animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         In order to design a meaningful research project, scientists must first have a solid understanding of the subject they wish to study.  Dr. Mellish and her team are fortunate because the Weddell seal population on McMurdo Sound has been studied extensively since 1968. Data collected as part of this Montana State University project has resulted in one of the most complete life histories of any wild mammal population in the world! VIDEO: WEDDELL SEAL SCIENCE Learn about the life history of Weddell seals. (3:50) Video Transcript Dr. Jay Rotella, Montana State University: “Weddell seals are found only in Antarctica, they’re a true seal ‘phocidae’, so you see they don’t have the external ears like some of the sea lions that people see at zoos and aquariums. “They’re one of several truly Antarctic seals, they’re only found in this part of the world. They’re one of the better diving marine mammals in the world, they can hold their breath for over forty minutes and dive to about 2,000 feet (600 meters). “We know them to be a seal that swims back in under the frozen sea ice, and they come up through the tide cracks. Around here against these islands we have places where the ice is attached to the shoreline and then out here the tide goes up and down a few feet (one meter). The seals use that diving ability to get back in here and come out through these tide cracks and use this area. One of their tricks in life is to get in here and have the pups away from predators, so that may be part of why they let us work in and around them. They don’t have predators up here about the ice, so they’re not worried about having anything happen to them. I don’t know that for sure, but it’s kind of an idea that people talk about. “For the first few weeks of life the babies are wearing this lanugo coat, this fleecy looking coat. They’re not very fat yet when they’re brand new and they’re not waterproof. For a while they’re really, really visible to us up on the surface, and then as they get a little fat from mom’s milk they’ll start to swim and learn some skills in the water. Then they’ll be a little less available to us for our work. “The next part of their life they sort of disappear from here. The first couple years of life they’re not around very much in the breeding colonies. They’re some evidence that they go out into the pack ice and probably exploiting fish out in those areas, although that’s not that well understood yet. “Then at some point around three, four, five years old they’ll come back into these colonies and start to give birth and maybe have a pup every two out of three years. Start giving birth between age five and seven, and then have one pup a year maximum. “Most of these animals live to be about five years old. Most animals that are born don’t make it to adulthood. The first couple years of life they’ve got about a fifty-fifty chance of survival. If they can make it to age three, the survival rates get very high; they’re getting bigger, they’re getting stronger, and probably know their way around and have places they know to find food and shelter. If they make it age three than they can make it to about 15 years old. The oldest seal we’ve ever had was thirty, but probably not very many make it that long, that’s rare. When we see a 20 year old, or a 25 year old, those are pretty old seals. “ While much is known about the life history of Weddell seals, less is understood about the species' physiological needs, including how they thermoregulate. In fact, due to the challenges that come with studying animals that split their time between land and sea, very little is known about the energetic costs of thermoregulation in any marine mammal species. VIDEO: WHAT IS ENERGETICS? Physiologist Dr. Allyson Hindle explains the concept of energetics and describes what makes up the 'energy budget' of a Weddell seal. (1:13) Video Transcript Dr Allyson Hindle: "One way that I really like to think about animal physiology is considering it in terms of energetics. Think about energetics, energy, as a currency that an animal can gain and spend. You would gain energy by eating fish, but in order to get those fish, in order to earn the energy, they have to spend it. They have to swim, they have to digest the food that they eat, they have to breathe, and they have to stay warm. All of those things cost energy. "So when we’re talking about energetics, we’re talking about the balance between spending and gaining. An animal that has a positive balance is taking in more energy than its using, and it’s going to grow if they’re a young animal, or its going to have excess energy to reproduce. On the otherhand, an animal that is spending more than its gaining, is going to start losing its body fat and losing its body mass. These animals become skinnier and skinnier, and ultimately bad things happen to them. "We’re interested in how animals live at this balance, and what happens when conditions change to change that balance". Thanks to recent advances in technology, tools now exist that allow scientists to study energetics in marine environments. Dr. Jo-Ann Mellish and her team hope to use these tools to establish a baseline for the energetic costs of thermoregulation in Weddell seals. They will use this information to predict polar seals' ability to adapt to changing habitat conditions.       WHO IS STUDYING SEALS?   DATA (n) - values for something measured   LIFE HISTORY (v) - the series of changes a living thing goes through during its lifetime   THERMOREGULATION (n) - the ability to maintain a constant body temperature under changing conditions   ENERGETICS (n) - the study of how energy is gained, used and lost (or transformed)   ADAPT (v) - to change behaviors or physical traits to survive in an specific environment   POLAR (n) -describing the area of the Earth’s surface around the north and south poles   PHYSIOLOGIST (n) - a biologist who studies the processes that help living things function    

animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('C', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         Pelagic animals live in the open seas, away from the coast or seafloor. The Pelagic Ecosystem team has the task of studying these predator and prey species in Prince William Sound. Despite the challenge, scientists have already managed to collect decades of data that focus on the interactions between whales, seabirds and their prey. This information is useful in answering questions such as: • What are the population trends of key open-ocean predators, such as orcas, tufted puffins, and humpback whales? • Are the numbers of forage fish, like herring, sand lance, and capelin, going up or down? • Is it possible to monitor forage fish population trends? • If it is possible to monitor them, what is the best way to do so? Forage fish have a big impact on marine ecosystems. They convert a huge amount of energy from lower trophic levels and this energy is transferred into food for larger fish, marine mammals, and seabirds. Forage fish have great numbers of offspring and short lifespans. These traits can cause major changes in their abundance from year to year. If the abundance of forage fish increases or decreases significantly, the predators that eat them will also experience shifts in their population numbers. Humpback whales are predators of herring. Many humpback whales migrate from Prince William Sound to Hawaii for the winter. Some humpback whales, however, stay in or near the Sound. During the winter, there is not much plankton for humpbacks to feed on, and fish like herring become a good alternative source of food for these whales. Watch the video below to see how the predators of the pelagic hunt their herring prey. VIDEO: Bait Ball Feast - BBC One In late summer, the plankton bloom is at its height and vast shoals of herring gather to feed on it. Diving birds round the fish up into a bait ball and then a humpback whale roars in to scoop up the entire ball of herring in one huge mouthful. From "Nature's Great Events: The Great Feast" by BBC. (1:14) Video Transcript The murres only attack from beneath, trapping the fish against the surface. But they push the herring within range of the gulls. It’s a feeding frenzy. The table is set for the mightiest predator of them all: the humpbacks have reached their feeding grounds. Scientists want to know the best way to estimate the numbers of specific fish species, such as herring. They get the data they need using a combination of aerial surveys, hydroacoustics, and various fish-capture techniques. Check out the video below to hear Mayumi Arimitsu explain some of these techniques. VIDEO: Forage Fish Studies Mayumi Arimitsu describes the methods scientists use to monitor forage fish populations. (0:55) Video Transcript We have observers in a plane that are looking at schools of fish in the ocean very close to the shoreline. We do a couple of things. One is use hydroacoustics from the boat, and with basically a scientific fish finder we’re able to quantify the biomass and density and depth distribution of these different forage fish. We also are trying to validate the aerial survey observations so we have a team in a skiff that are communicating with the pilot in the plane, and they are trying to catch what the observers in the plane are seeing. Scientists working on the humpback whale monitoring project are trying to understand if the whales are having an impact on the recovery of herring populations in Prince William Sound. An important part of this project is maintaining an up-to-date humpback “fluke identification catalog,” a kind of “Who’s Who?” in the Gulf of Alaska whale world. Watch the video below to learn about how scientists observe and photograph whales included in the fluke identification catalog. VIDEO: Tracking Humpback Whales John Moran describes how scientists are studying the importance of humpback whales in the Gulf of Alaska ecosystem. (2:08) Video Transcript (Narrator) These small silver fish are Pacific herring, one of the many species being monitored by Gulf Watch Alaska. Scientists are monitoring their population for signs of recovery after the Exxon Valdez oil spill. They are also interested in other potential factors that could be affecting their recovery. One of these potential factors may be humpback whales. (John Moran) We want to know if humpback whales are having an impact on the recovering herring population in Prince William Sound. Basically we want to know how many herring are whales eating, and is that important. So the first thing we need to do is figure out how many whales are there, so we use Photo ID. All the whales have unique patterns on their flukes. When the whale dives it shows the underside of its fluke, and we’ll take a picture of that and that can identify the individual whale. So basically we get on the boat and we go look for whales. That the base of our research is getting the fluke IDs. And from that you can get a lot more information out of it. We need to figure out what they’re eating, so we use the echo sounder on the boat, we’ll use nets and jigs, so we’ll see whatever prey is around the whale and try to catch that. Or if there’s any scales that slip out of their mouth, or any kind of sign of things on the surface, or fish jumping out of the whale’s mouth, we’ll try to document that. And we also use biopsies. We have a cross bow or a rifle that takes a little blubber plug out of the whale. So we approach the whale and get a little sample, and from that we can use stable isotopes or fatty acids to get at what the diet’s been from that whale. Humpbacks are kind of new players on the scene, they’re population was really low. In the late sixties & early seventies, there may have been 1,500-2,000 humpbacks in the North Pacific. And then there was this survey called the SPLASH survey that took place in 2006 that put the population at over 20,000. So that’s a huge increase. It impacts managers. If you’re managing a herring fishery and you have these humpbacks population weren’t really there 20, 30, 40 years ago, you’ve got to account for these new predators, how many herring are they taking, it’s all important to know if you’re trying to manage a fishery. We haven’t had them there, so how they impact the ecosystem is going to be new to us.       Who is watching the Gulf?   Biomass (n): the amount of living matter in a given habitat (i.e. the weight of organisms per unit area, or the volume of organisms per unit of habitat)   Forage fish (n): small schooling fishes that feed on plankton and are eaten by larger predators   Hydroacoustics (n): the study of sound in water   Pelagic (adj): the open sea, away from the coast or seafloor   Trophic level (n): the position of an organism or species in a food web or food chain    

animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         At the Alaska SeaLife Center, Dr. Hollmen's team provides all the necessary care for the Steller's eiders in their virtual habitat. The eider team monitors the birds’ behaviors and health on a daily basis and makes sure the birds have the proper space and food. The enclosures for the birds aren’t exactly like the habitats they typically live in, so it is up to the husbandry team to figure out what the Steller’s eiders need to succeed. Dr. Tuula Hollmen and her crew work hard to create a habitat that suits the eiders. Remember, Steller’s eiders are migratory birds, so the habitat at the Alaska SeaLife Center has to change season to season, especially during breeding season! VIDEO: Creating a Virtual Habitat Tasha DiMarzio explains how the Steller's eider enclosures at the Alaska SeaLife Center can be altered to create a virtual tundra habitat. (2:19) Video Transcript The area we are sitting in now we call our breeding units. There’s ten individual units or one large unit, and we can create smaller flocks or individual breeding units or one big pen for if we want to winter everybody in this unit, we can do that. Starting in January through March, we’ll really start watching the birds and seeing who is courting with who and who’s pairing off, and then we’ll move them from what we call the non-breeding or wintering unit and they migrate over to our breeding units (which is just across the walkway). In the winter time we switch them all to salt water because that is where they would be in the wild, out in the ocean, and in the summertime they come to these freshwater tundra ponds. When we were in full breeding season we had covers over one of the pools and it was tundra and then pond on the other side. But now since we are in duck rearing mode we have two ponds and they’re both fresh water. Getting birds to breed in captivity is always a big challenge. Luckily we are in a state where these birds are actually from, and so we can go out and see what they are using as nest materials and what sites they prefer, if its grass or lichen, and then we try and replicate that the best we can. We don’t have these big vast tundra fields, so we try and create areas that they can feel secluded and have privacy, but then have it look a little bit like what maybe they would see in the wild. We go to the beach and we collect a lot of driftwood to create visual barriers and blinds and areas that they can be private. Because each female is picky about where she likes, we try and provide each pair with at least three different nesting options. So a nesting option can be a manmade wooden structure that looks like nothing that you would see in the wild, and then another open tundra-like moss nest, and then a combination of the two: maybe driftwood around a plexiglass-covered structure. And then the biggest key is just keeping it dry so that the down in the nests stay dry. Because the areas that they are nesting, even though it is Arctic tundra, it’s actually a desert and so there is very little water and rainfall but here we’re in a very rainy climate and so that’s a big challenge we have, is keeping their nests dry while they’re going through the egg laying process, so we come up with different things to try and tackle that challenge. By altering the virtual habitat, the husbandry staff can try to match the eiders’ needs for the breeding season. Each year, the husbandry team continues to offer the eiders a variety of space and nesting configurations in the habitat, in an attempt to promote successful breeding. If something doesn’t work, they try something different the next year! After years of trial and error, favorable conditions have been created, allowing some of the eiders to feel comfortable enough to nest! As a result, the team is faced with hundreds of eggs. Some of the Steller’s eider hens incubate their own eggs, but many eggs end up in the care of the husbandry staff when hens don't prepare an appropriate nest. See how scientists can try to play the role of a hen incubating her eggs. VIDEO: ARTIFICIAL INCUBATION Nathan Bawtinhimer describes the process involved when humans incubate eider eggs. (1:32) Video Transcript It's a fun challenge trying to get the artificial incubators to accurately mimic the hen incubating which is very tricky. So we’ve been messing around with a lot of different humidity settings and different methods of turning to more accurately imitate the hen and promote better development within the egg during the incubation process and successful hatching. It’s important that we candle the eggs regularly so we can keep track of the development inside the egg. By candling them with a bright LED flashlight we can actually see inside the egg and just by looking we can tell how long it’s been incubating for, if it’s on the right track developmentally, and what the estimated hatch should be. When we are candling the eggs it is actually an important cool down time for the eggs, because we’ll have the top off the incubator which simulates the hen getting off the nest and foraging. And we also weigh the eggs everyday because during the course of incubation there is a certain range that the egg is supposed to lose to hatch successfully, usually between 12 and 16% of its weight. So we watch their weight loss and we adjust the humidity accordingly. The amount of weight they lose is critical for successful hatching. We’ll record and enter all the data in the spreadsheet so we can track the weight loss and the development of the eggs. And we keep very detailed records of everything we see every day when we candle. While scientists are learning about the Steller's eiders at the Alaska SeaLife Center, they also need to learn more about the natural habitat of these birds. If researchers are hoping to increase the nesting population of Steller's eiders in Alaska, there has to be suitable nesting habitat available in the wild. To determine what is available for these birds in the wild, the scientists head out into the field...       CLICK BELOW TO LEARN ABOUT SEADUCK SCIENTISTS!   COURTSHIP (n)- the behavior of male birds and other animals aimed at attracting a mate.   HABITAT (n)- the natural home or environment of an animal, plant, or other organism.   HUSBANDRY (n)- the care, cultivation, and breeding of crops or animals.   INCUBATE (v)- to keep an egg or organism at an appropriate temperature for it to develop.   MIMIC (v)- to imitate something.   MONITOR (v)- to keep surveillance over something.    

  animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() As Yosty mentioned, during the years of 2014 and 2015 scientists with Gulf Watch Alaska began to notice multiple strange occurrences happening in the Gulf, and they wondered how these could be connected. The area of water monitored by the team of scientists at Gulf Watch Alaska is crucial for the survival of animals in and surrounding the Gulf, as well as the populations of people situated on the coast. Using the power and capabilities of the Gulf Watch Alaska team, scientists have begun to piece together the mystery of these strange events. But before figuring out how these events are connected, the scientists needed to fully understand the scope of what was happening in 2014 and 2015. Starting in the winter of 2014, residents of communities surrounding the Gulf of Alaska were witness to a very concerning phenomenon happening to one of the area’s most familiar seabirds, the common murre. Striking numbers of common murres were washing up dead along the coast, and thousands were traveling unusually far inland and away from their feeding grounds in the Gulf of Alaska. It is considered normal for common murre populations to intermittently experience large-scale die-offs, known as wrecks, but the series of die-offs beginning in the winter of 2014 and extending through 2016 were unparalleled in the historic record, both in terms of geographic area and length of time. As the initial reports of these unusual common murre deaths and migratory patterns began making their way to the scientists of Gulf Watch Alaska, there was a lot of speculation about what could be causing this event. Travel with Yosty to meet Gulf Watch Alaska Scientist Kathy Kuletz to hear her account of the common murre die-off event and how her research seeks to understand what was causing the die-off. Click the video below to hear Kathy’s experience with the common murres. VIDEO: Kathy Kuletz and the Common Murres Kathy Kuletz talks about common murre die-offs and their potential causes, and some of the challenges scientists face when trying to study these events. (3:45) Video Transcript Narrator:The first person Yosty sat down with was Kathy Kuletz, a scientist who studies birds for Gulf Watch. Yosty: Hi Kathy, you’ve been a wildlife biologist with U.S. Fish and Wildlife service since 1978? Kathy: Yes. Yosty: Can you tell me about what went on in 2014-2015 that was so unusual in the Gulf of Alaska? Kathy: Everyone knows, it’s been really warm, that was the main thing. And associated with that we started having reproductive failure by seabirds and large die-off events - mainly with common murres but some other species were involved as well. But the main event, which has been really noteworthy, has been the die-off of common murres. It has been unprecedented in its geographic scope, extending from southeast Alaska all the way up into the Aleutian Islands and Bering Sea but mainly in the Gulf, the northern Gulf of Alaska. And it’s been unprecedented in the length of time that this has continued, we started having hints of it in 2014, it really hit heavy in the winter of 2015 and 2016 and just continued in episodes, die-offs happening throughout 2016. Yosty: So what do you think is killing the birds? Kathy: When we find them, we have looked at some carcasses on the beach and taken some back to the labs. USGS has been working with us and many other groups - COASST and Fish & Game - and they have, the birds have been empty, their stomachs have been empty and they have lost muscle mass, they have all the evidence of sort of consuming from the inside because they are starved. I know there is a lot of concern about domoic acid and saxatoxin, which is found with paralytic shellfish poisoning, and that certainly could be there, but so far we’ve only found some of the birds have trace amounts of saxatoxin. So the problem with determining if that has played a part is that they don’t keep food in their gut for very long, and because they are empty we haven’t been able to test the food that they have eaten. We do know that those kinds of toxins can change behavior of seabirds, and so it might have affected their ability to forage and find food, but it is also just as likely that there is not enough food or the food is of low quality in the areas where they normally feed. Now when it is really warm, some of these fish will go very deep in the water column, so birds like black legged kittiwakes who just feed on the surface, they can’t access the fish. Murres can dive quite deep, 100 meters, so they should be able to access fish if they go deep but the fish might also have moved far offshore if it is very warm, they are looking for colder water sometimes or more food. So it is quite likely that their food wasn’t available, or it wasn’t nutritious. Often when it is very warm the zooplankton tend to be smaller and less energy dense and up the food chain the fish will be smaller and have less energy for weight, so that affects seabirds and marine mammals that feed on them. We are continuing to collect carcasses when we find them, or people will ship them in and we’ll help get them sent to the lab. USGS now is putting together their own lab so we can do testing here in Anchorage, so that will expedite things a lot and maybe that’ll help us get better access to fresh samples that we can more accurately test for saxatoxin and other toxins. Yosty: Thank you.       Who is watching the Blob?   Carcass (n): the full skeletal and organ remains of a dead organism   Crucial (adj): very important to the success or failure of something   Data (n): values of something measured   Domoic acid (n): an acid produced by algae that accumulates in the shellfish that consume the algae, affecting the brain and nervous system of the animals that eat the shellfish   Food chain (n): the organization of organisms in an ecosystem, describing which organisms eat which   Intermittently (adv): happening in an irregular pattern   Phenomenon (n): a situation that is observed for which the cause is unknown or questioned   Saxatoxin (n): a toxin produced by algae that accumulates in the shellfish that consume the algae, causing illness in the animals that eat the shellfish   Speculation (n): a theory or idea without evidence to support it   Unparalleled (adj): having no equal or match, something that is unique   Unprecedented (adj): never seen or experienced before   Wrecks (n): large die-offs of common murres that have happened periodically throughout history    

  animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() Talking with Kathy, Yosty learned that the common murres in the Gulf of Alaska were starving during this period of uncharacteristically warm water. This common murre die-off event was very puzzling for scientists because there was not a clear reason as to why the birds were behaving abnormally. If the birds were not getting enough food, there must be something in the Gulf of Alaska impacting the food chain. Scientists study all levels of marine food webs, beginning with the organisms at the base — the plankton. Plankton are a diverse group of living organisms that spend at least part of their life floating through the water column, unable to swim against the current. Plankton consist of both plants and animals and help to form the base of the marine food chain. Every organism that relies on the ocean for food depends on an adequate supply of plankton to keep the ecosystem properly fed. Even animals that don’t eat plankton themselves, like the common murres, require enough healthy plankton to feed the fish and invertebrates that they prey upon. So, if the common murres were starving, causing them to move close to shore and inland to search for food, and dying in large numbers, there might be some evidence that maybe something was different about the amount or types of plankton in the Gulf of Alaska those years. Following this lead, Yosty moves forward in the investigation by questioning Gulf Watch scientist Sonia Batten, who specializes in monitoring plankton populations to understand what had been happening at the base of the Gulf’s food chain that might have been related to the murre die-off. Watch the video below to hear what Sonia has observed with the plankton in the Gulf of Alaska. VIDEO: Sonia Batten and Plankton Sonia Batten describes her observations of plankton in the Gulf of Alaska. (4:17) Video Transcript Narrator: Hmm… It all seemed to go back to the murres’ food chain. Why did these seabirds starve to death? Was something wrong with their food source? Yosty needed to start at the bottom of the food chain. She needed to talk to Sonia Batten, A Gulf Watch scientist monitoring plankton in the Gulf of Alaska. Yosty: Hi Sonia, what evidence do you have that 2014-2015 were unusual times for plankton in the Gulf of Alaska? Sonia: We’ve been looking at plankton in the northern Gulf of Alaska since 2000, so we have quite a long time series now. We look at the plankton from spring through fall of each year. We noticed in 2014 and then again in 2015 that there was something unusual happening, and we were kind of expecting it because we knew that the waters offshore were really warm from the end of 2013 through the next two years (really unusually warm, and it’s been called “the blob” by some people). So we were expecting to see something unusual. What we typically see in the plankton… There are two types of plankton. There’s the plant plankton and those are little tiny single-celled plants that float around and take the sun’s energy to grow – and they typically get blooms of those in the spring because there’s lots more sunlight in the spring, there’s lots of nutrients from the winter storms that have been mixed up, and it starts warming up. All those things are really good for them to grow, so we typically see those take off in the spring. And then as they grow they get eaten by the animal plankton and their numbers die back a little and they run out of nutrients and so on, so there’s lower levels of them through the summer. And then sometimes in the autumn we get another bloom because we get a few storms come in and mix things up again and give them more nutrients. That’s the typical pattern. What we saw in 2014 was we didn’t see anywhere near as many of those plant plankton as normal, and we saw big numbers of very small animal plankton that were around. It was quite unusual – we hadn’t seen anything quite like that in the whole 50 years of sampling that we’ve done. Yosty: What impacts could this have on the rest of the Gulf? Sonia: It’s still a question we’re working on. Plankton support everything in the ocean. All of the fish and mammals either feed on plankton themselves, or they feed on something that’s been eating plankton already. If there’s not so many of one type of plankton that might be bad, but there were quite a lot of animal plankton around so there obviously eating something. They may be eating something that we don’t see… One of the things we saw was that the types of plant plankton were slightly different: there were more of the smaller type of cell that are longer and thinner. Those cells typically do better in years when there’s not so many nutrients around, because they find it’s easier to take the nutrients up. It’s possible that those are not such a good food source for some of the animal plankton, or maybe the animal plankton weren’t finding as much of what they wanted and in turn that could mean that there’s not enough animal plankton for the fish and seabirds and mammals. But we still don’t really know – those kinds of patterns take a long time to be revealed. Yosty: Kathy mentioned something called domoic acid and its potential to impact seabirds. How is this related to the plankton that you’ve been studying? Sonia: Some phytoplankton – that’s the plant plankton – can produce a toxin called domoic acid. They don’t necessarily produce it over time, sometimes they produce it as a response to a stress in their environment. One of those stresses could be being eaten, so they produce it to put off zooplankton from eating them. There were reported instances of domoic acid in Alaska, and actually through a wide area of the North Pacific a lot of places were reporting it. Although the plankton have evolved to deal with the domoic acid that’s produced by the phytoplankton when other animals eat the zooplankton they concentrate the toxin, and as you go up the food chain the poison gets concentrated and it can potentially cause problems in larger animals that never ate plankton themselves but have eaten other organisms that have concentrated it. So it’s one explanation for why some of the seabirds may have been struggling in that year.   Plankton are considered one of the environmental drivers, so they’re the link between what happens in the ocean – in terms of water chemistry, temperature, the water conditions – and the fish, because plankton respond to their environment really quickly, and fish feed on plankton and larger organisms feed on fish, so the plankton are the link between the oceanography and the fish. We know that plankton respond really quickly because they have life cycles that are really short, sometimes even days, but all of them less than a year or at least a year is the longest life cycle. So if changes happen in their environment they respond quite quickly, and you can see that in changes in their numbers, and the types of plankton and where they’re at. So by monitoring them it gives you a really rapid response to a change in the environment. In the early part of the twentieth century in the UK, it was kind of hard to know where to send the fishing boats, you know, where they were going to find the herring, and Alister Hardy invented this instrument that could be towed behind ships, measuring the plankton, and it’s called the continuous plankton recorder. Continuous because, rather than taking a sample as a snapshot across, it continuously samples the plankton as it goes. His idea was that if you could understand the food of the herring, the food of the fish, maybe you could predict where they were going to be and then send the fishing boats there. You would build a map, a bit like a weather map, of where plankton were and when they were, and then you could send the fishers. So that was his idea, back in the early part of the early part of the twentieth century. And it took a few years to get routine, but from the 1930s onwards they were using this instrument to do that – to build up a picture of plankton meteorology, basically.         Who is watching the Blob?   Abnormally (adv): different from what is normal   Diverse (adj): a lot of variety   Invertebrate (n): an organism lacking a backbone   Organism (n): an individual life form   Phytoplankton (n): freely floating, often minute plants that drift with water currents   Productive (adj): producing enough energy to sustain life   Zooplankton (n): freely floating animals that drift with water currents  

Seward, Alaska (January 22, 2016) – The Alaska SeaLife Center (ASLC) is proud to announce the recipients of the 2016 Alaska Ocean Leadership Awards. These awards are given annually to individuals and organizations that have made significant contributions to the awareness and sustainability of the state’s marine resources. The Alaska SeaLife Center appreciates the support provided by the award sponsors and thanks the Awards Committee members: Denby Lloyd, Molly McCammon, Lisa Busch, Ian Dutton, Jason Brune, Michael Castellini and Phyllis Shoemaker for assistance in selecting the awardees. Two of the awards will be presented at the Alaska Marine Science Symposium on January 25, 2016 at the Hotel Captain Cook in Anchorage, Alaska. The remaining awards will be presented at the Alaska Marine Gala on February 13, 2016 at the Dena’ina Center in Anchorage, Alaska. Tickets and sponsorship opportunities are still available.  For additional information, visit www.alaskasealife.org or contact Nancy Anderson, nancya@alaskasealife.org or 907-224-6396. Following are the 2016 Alaska Ocean Leadership Award winners: Captain Ed Page will receive the prestigious Walter J. and Ermalee Hickel Lifetime Achievement Award. The late Governor Walter J. Hickel and his wife Ermalee endowed this award for 10 years to recognize an individual who has made exceptional contributions to the management of Alaska’s coastal and ocean resources over a period of 20 years or more. Through his tireless efforts to promote safety, stewardship, and environmental protection of the marine environment, Captain Ed Page has been an exemplary leader and public servant on behalf of Alaska's oceans. Even after 29 years of service with the United States Coast Guard, Captain Page chose not to retire. Instead, he put his extensive maritime experience, knowledge of marine law, contacts with the shipping industry, talent for communication, and passion for the ocean to good use by creating the Marine Exchange of Alaska in 2000. Under his leadership, the Marine Exchange of Alaska tracks and monitors over 2,000 vessels in the 1.2 million square miles of ocean bordering Alaska. The Marine Exchange makes it more likely that potential vessel-related problems at sea will be detected, thereby preventing unseen marine accidents. Award to be presented at the Alaska Marine Gala.  The nonprofit organizationSeaShare will receive the Stewardship & Sustainability Award. This award is sponsored by Jason Brune, and honors an industry leader that demonstrates the highest commitment to sustainability of ocean resources. SeaShare leads our seafood industry in a collective effort to improve nutrition for the people served by our nation’s food bank network. SeaShare combines the generosity of fishermen with processors, service providers, and financial donors to generate high volumes of donated seafood. SeaShare started in 1994 with an Experimental Fishing Permit to retain Prohibited Species Bycatch in Dutch Harbor and use those valuable fish resources for hunger relief. Over 20 years later, SeaShare remains the only organization authorized by NMFS to coordinate donations from over 120 boats and shore plants in Alaska. To date, this has resulted in 4 million pounds of fish distributed in communities such as Anchorage, Kodiak, Juneau, Cordova, Fairbanks, St. Paul, Kotzebue, Galena, Nome, Diomede, Savoonga and Wales. It’s a great story of fishermen and processors who respect the resource and who want to see that fewer fish are wasted. Award to be presented at the Alaska Marine Gala. Sofia Astaburuaga will receive the Hoffman-Greene Ocean Youth Award, which is sponsored by Dale Hoffman.The award honors an individual or team of Alaskan youth ages 12-19 who have displayed a dedication to promoting the understanding and stewardship of Alaska’s oceans. Sofia is an active member of Alaska Youth for Environmental Action, and is passionate about working with teens on issues related to climate change and the environment. She has worked on habitat restoration and resource monitoring efforts in Prince William Sound and the Chugach National Forest, as well as salmon habitat restoration through the Student Conservation Association. This past year, Sofia has been working with researchers at the University of Alaska to investigate the effects of plastics on seabirds in the Aleutians. Award to be presented at the Alaska Marine Gala. Arliss Sturgulewski will be recognized with the Ocean Ambassador Award. The Ocean Ambassador Award was created to recognize an individual or organization that has made outstanding contributions in promoting public awareness and appreciation of Alaska’s oceans, coasts, and marine ecosystems. Arliss is well-known throughout the state of Alaska for her service in political office and on many key advisory committees related to marine research and outreach. She is an active champion for the wise use of Alaska’s resources. While serving in the Alaska State Senate from 1979 to 1993, Arliss was an advisor to the International North Pacific Fisheries Commission. She fought against foreign fishing in US waters and championed the Community Development Quota program that supports local Alaska communities and fisheries. She has also been a member of the University of Alaska Fairbanks School of Fisheries and Ocean Sciences Advisory Council since 1992 and has served on the Alaska Sea Grant Program Statewide Advisory Committee since 2003. In these roles, she has been actively supportive of expanded marine research capacities in the state, as well as providing scholarship opportunities to students. Award to be presented at the Alaska Marine Gala. Susan Saupe will receive the Marine Science Outreach Award. This award is given to a person, team or organization that has made an outstanding contribution to ocean literacy via formal or informal education, media or other communications. It is co-sponsored by the University of Alaska, School of Fisheries and Ocean Sciences and the Alaska Ocean Observing System. Susan grew up on Kodiak Island, earned a Master’s degree in Chemical Oceanography, and has conducted research at sea throughout Alaska. She has been with the Cook Inlet Regional Citizens Advisory Council since 1996, and drew on her previous experiences to build their science program. Her role as Director of Science and Research provides unique opportunities to bridge the gap between marine researchers and coastal communities. Susan includes outreach in each program component – whether talking about oceanography, contaminants monitoring, coastal habitat mapping and assessments, or oil fate and effects research – to build meaningful partnerships. By seeking commonalities, Susan leverages funding, logistics, and expertise to collect and deliver user-friendly information about Alaska’s marine environment to a wider range of research, educational, agency, industry, and community users. Award to be presented at the Alaska Marine Science Symposium. Dr. Gunnar Knapp was selected toreceive the Marine Research Award, sponsored by Drs. Clarence Pautzke and Maureen McCrea. This honor is given to a scientist, team of scientists, or an institution that is acknowledged by peers to have made an original breakthrough contribution to any field of scientific knowledge about Alaska’s oceans. Dr. Gunnar Knapp has been studying fisheries management, fisheries markets, and the world seafood industry for more than twenty-five years, focusing particularly on the Alaska salmon industry. Gunnar’s willingness and ability to build close links with all sectors of the industry make him an inspiration to researchers in his field.  During the 1990’s, he began the Salmon Market Information Service for the Alaska Seafood Marketing Institute. He co-authored the major 1997 report “The Great Salmon Run: Competition between Wild and Farmed Salmon.” He has written numerous articles and reports on salmon markets, trends in limited entry permit ownership, the effects of halibut and crab IFQs, the Chignik salmon co-op, implications of climate change, and the economic impacts of Alaska fisheries. Dr. Knapp is closely engaged with the seafood industry and policy makers in Alaska. Currently, he is writing a book, The Economics of Fish, which is intended as an introduction to the insights provided by economics about fisheries, aquaculture and the seafood industry. Award to be presented at the Alaska Marine Science Symposium. About the ASLC Opened in 1998, the Alaska SeaLife Center operates as a private, non-profit research institution and public aquarium, with wildlife response and education programs. It generates and shares scientific knowledge to promote 

  animatedcollapse.addDiv('1', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('2', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         Three years of spring sampling trips resulted in thousands upon thousands of data samples. Back at the University of Alaska Fairbanks, the scientists resettle into their lab. Now with all their samples in front of them, they work to draw meaning from these snippets of information. It's like putting together a puzzle, but this one will take years to finish! Dr. Rolf Gradinger quickly discovered that there was a huge amount of ice algae production happening in the Bering Sea, even more than the team had hypothesized! Dr. Gradinger found that as much as 50% of all the algae growing in the Bering Sea in spring was growing with the sea ice. Armed with this knowledge, Dr. Bluhm and Dr. Iken set to work decoding the food web. First, they wanted to figure out which animals in the Bering Sea feed directly on ice algae. The two scientists are especially interested in animals that feed directly on the sea ice, because changes in the food available for these species will impact animals all the way up the food chain. To study the diet of these primary consumers they used a process called stable isotope analysis. VIDEO: BUILDING A FOODWEB USING STABLE ISOTOPES Learn about how researchers can piece together the marine food web by looking at muscle tissue (1:35) Video Transcript You might have heard the saying before, "you are what you eat". It turns out it's true! Certain chemicals from the foods we eat stay inside our body's tissue long after the food has been digested. Because different foods have different chemicals in them, each type of food has its own chemical signature, it's kind of like a fingerprint. Scientists can look at these signatures inside an animals tissues to see what kinds of food the animal has been eating. The chemicals that scientists look for are called stable isotopes.   In marine ecosystems like the Bering Sea, scientists use this technique to figure out which animals are eating certain types of algae. Imagine you're a clam. You live in the silty sediments at the bottom of the Bering Sea. In the springtime you eat 10 units of food in a day. Of these ten units, eight are of sea ice algae and two are from phytoplankton from the pelagic zone. You go along like this, every day eating eight units of sea ice algae and two units of phytoplankton, until one day.... SCOOP... you end up in our researchers sediment grab sampler. You're hauled up to the surface and taken to the laboratory where a sample of your muscle tissue is removed and tested for stable isotope signatures. The scientists recognize the signature of the stable isotopes from the algae you ate, so they can tell that the ice algae was an important part of your diet. This same techique can be used on animals higher up the food chain. Even the walrus who ate the clam who ate the sea ice algae will have muscle tissue with the sea ice algae's special signature. With the help of stable isotope analysis, the pieces begin falling into place. Dr. Bluhm and Dr. Iken are able to connect primary consumers to the ice algae they ate using their muscle tissue. The food chain doesn't stop there! These primary consumers can be connected to secondary consumers, who can be connected to one of the ecosystem's top predators: the polar bear. Suddenly, scientists are able to show that sea ice isn't just important to a few species; it connects animals throughout the food web! Navigate through the food web below to see what scientists have learned about how arctic organisms are interconnected: The evidence collected as part of this project clearly supports the team's hypothesis that sea ice is an important food source for pelagic and benthic Bering Sea communities during the springtime. The question now is: What will it mean for marine life as sea ice conditions in the Bering Sea continue to change? Scientists aren't sure yet, but they know that research projects like this one are important because they will provide baseline information which will help the science community quantify ecosystem changes over time.       WHO IS STUDYING SEA ICE?   ISOTOPES (n)- different forms of the same chemical   INTERCONNECTED (adj)- connected with each other   CLIMATE (n)- the general weather conditions in an area over a long period of time   BASELINE (n)- a starting value that is used for comparison to future values   QUANTIFY (v)- to assign a quantity to something              

          WELCOME, TEACHERS! The Alaska SeaLife Center and Gulf Watch Alaska are excited to present this virtual field trip (VFT). Join the Gulf Watch Alaska team of scientists as they investigate the long term effects of the Exxon Valdez oil spill on the ecosystems of the Gulf of Alaska. Learn about the work of a collaborative team of scientists from many different ocean science disciplines, who represent over 15 different government agencies, non-profit research institutions, and universities. GRADE LEVEL: 6-8th TIME NEEDED: Between one and four 1-hour class periods (teachers may choose to use all or only some of the supplementary lessons). NUTSHELL: Students will learn about the long-term monitoring projects that have been studying the effects of the 1989 Exxon Valdez oil spill in Prince William Sound and the northern Gulf of Alaska. They will explore the various projects and how, collectively, they can inform us about the overall ecosystem. LEARNING OBJECTIVES: After completing this virtual field trip, students will be able to: • Explain how the long-term monitoring project called Gulf Watch Alaska was founded and what its overall goals are. • Understand the collaborative nature of science and how researchers from various disciplines working together can provide a ‘big picture’ view of a massive project. • Explain the various levels of a biome and how all components of an ecosystem depend upon each other for a healthy environment. BACKGROUND: In this virtual field trip, students will meet various scientists and researchers working for the Gulf Watch Alaska long-term ecosystem monitoring program, a project of the Exxon Valdez Oil Spill Trustee Council, encompassing the marine ecosystems affected by the 1989 oil spill. This program is organized into four related ecosystem monitoring components, with data management, modeling, and synthesis components providing overall integration across the program. This VFT can be used in a number of ways. Individuals may navigate through the pages on their own and meet the scientists through the links provided on the right-hand bar. Self-guided exploration can be completed in a couple of hours. Alternatively, teachers may facilitate a structured experience, working through each page of the VFT together in a class. Lesson plans (links included on the right-hand column of this page) are available to supplement online content. TO USE THIS VIRTUAL FIELD TRIP YOU WILL NEED: • Internet access, video-streaming capabilities • Projection system (with audio) to display content or a computer lab (with headphones) • Corresponding lesson plans (linked as PDFs in the right hand column of this page) UNABLE TO RUN THE STREAMING VERSION? REQUEST A FREE COPY OF ALL MATERIALS ON CD BY EMAILING education@alaskasealife.org. ADDITIONAL RESOURCES: • Gulf Watch Alaska • Alaska Ocean Observing System • Nearshore Ecosystem Projects • Ecological Trends in Kachemak Bay • Nearshore Benthic Systems in the Gulf of Alaska • National Park Service SWAN Nearshore Monitoring • Environmental Drivers Projects • Continuous Plankton Recorder • Gulf of Alaska Mooring (GAK1) Monitoring • Oceanographic Conditions in Lower Cook Inlet and Kachemak Bay • Oceanographic Conditions in Prince William Sound • The Seward Line: Marine Ecosystem Monitoring in the Northern Gulf of Alaska • Lingering Oil Projects • Weathering and Tracking • Harlequin ducks and sea otters • EVOS Status of Injured Resources and Services • Pelagic Ecosystem • Detection of Seabird Populations • Fall and Winter Seabird Abundance • Forage Fish • Humpback Whales • Killer Whales • Prince William Sound Marine Bird Population Trends   Contact Us: If you have any questions about this virtual field trip, please contact the Alaska SeaLife Center Education Department at education@alaskasealife.org or 907-224-6306. For more information on classes we offer, including our inquiry-based 50-minute Distance Learning programs, visit our website at www.alaskasealife.org.         CURRICULUM SUPPLEMENTS Use the .pdf links below to access classroom activities for each section of the Gulf Watch Alaska virtual field trip experience. Lesson 1 Nearshore.pdf Lesson 2 Drivers.pdf Lesson 3 Lingering_Oil.pdf Lesson 4 Pelagic.pdf Gulf Watch Whale Fluke ID.pdf Who's that Whale? slideshow          

  animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         Eiders are sea ducks, which means that they live in coastal areas where they dabble for small invertebrates or dive for crustaceans and molluscs. Steller's eiders nest on the arctic and subarctic tundra. These birds are sexually dimorphic, so males generally look very different from females. Click on the images below to discover the advantages of different colors on the tundra: Steller's eiders are migratory and winter comes early on the Alaskan tundra. Before ice covers the ponds and coastal waters near the Steller's beeding grounds, the birds must travel south to areas where the coast doesn't freeze over, allowing them to access food resources in the ocean. Watch the video to learn where the Steller's eiders of Alaska travel throughout the year. VIDEO: Annual Cycle of Steller's Eiders in Alaska Discover the life history of Steller's eiders in Alaska. (2:44) Video Transcript In Alaska, Steller’s eiders spend the winter on the coast along the Aleutian Islands, the Alaska Peninsula, and the Kodiak Archipelago. As spring arrives, the birds wait for the sea ice to melt along their migratory paths. Before they migrate, the males begin to dance. All efforts are geared toward finding a mate. Then, the Steller’s eiders that winter in Alaska diverge into two separate breeding populations. Most of them fly northwest to breed and nest in Russia. Others fly north to breed and nest near Barrow, Alaska. These birds comprise the Alaskan breeding population. Historically, Steller’s eiders also nested on the Yukon-Kuskokwim, or Y-K Delta. Now Steller’s eiders are a rare sight on the Y-K Delta, and very few Steller’s nests have been discovered there in the past several decades. In late May or early June the Steller’s Eiders reach their breeding grounds on the arctic tundra. By late June the hens are ready to make a nest on the tundra in close proximity to tundra ponds. The males stay around to guard while the females construct elaborate grass nests lined with cozy down feathers. The end result is so well camouflaged that it virtually disappears into the tundra. By early July the Steller’s hens will lay up to 9 olive-brown eggs. While the females tend to their eggs, the males leave to travel south and return to their molting grounds. Adult eiders molt their flight feathers once each year, leaving them unable to fly for about a month as they grow new feathers. Males travel to protected bays and lagoons to molt before continuing on to their wintering sites. Meanwhile, on the tundra the hens incubate their eggs up to 26 days before the ducklings hatch. Within 24 hours of hatching the ducklings leave the nest to follow their mother around the coastal tundra. In 5 to 7 weeks the young birds are able to fly. Fall will soon give way to winter, so the mothers and their young must fly south to the molting and wintering grounds. The females reunite with the males and with the breeding population that spent its summer in Russia. And the annual cycle of the Steller’s eiders begins again. Every species of bird has different requirements for successful nesting but, with so few of these birds in the wild and so little known about them, how will researchers know what Steller's eiders need? In captivity, these birds won’t have to worry about predators or the challenges of migration. But will the scientists be able to provide them with requirements they need to nest and raise ducklings hundreds of miles away from the tundra?       CLICK BELOW TO LEARN ABOUT SEADUCK SCIENTISTS!   CAMOUFLAGE (n) - concealment that alters or obscures the appearance; helps an organism to hide from its predators.   FORAGE (v) - to search for and collect food.   INCUBATE (v) - to keep an egg or organism at an appropriate temperature for it to develop.   IRIDESCENT (adj) - shining with many different colors when seen from different angles.   LIFE HISTORY (n) - the series of changes a living thing goes through during its lifetime.   MIGRATION (n) - seasonal movement from one area to another.   MOLT (v) - to lose a covering of hair, feathers, etc., and replace it with new growth.   PLUMAGE (n) - the feathers that cover the body of a bird.   SEXUAL DIMORPHISM (n) - when the male and female of the same species look distinctly different from one another.  

animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         A typical day doesn’t exist on the Arctic tundra. Even in the summertime, you could wake to a day of hail, snow, fog, rain, or 70-degree sunshine. Luckily, on good weather days there is a lot of daylight when scientists can get their work completed. With a flat landscape, light from the sun lasts almost 24 hours. Researchers sometimes work until one o'clock in the morning! In the 2014 season, Alaska SeaLife Center scientists traveled to the Y-K Delta twice; once in June to investigate habitat for nesting pairs and once in July to study conditions during brood rearing. This fieldwork helped determine if there is suitable habitat on the Delta for the potential rearing of Steller’s eider ducklings in the upcoming years. If the team can hatch and raise Steller's eiders on the Y-K Delta, this may be a way to reintroduce Steller's eiders to that area. The prospective Steller's rearing location needs to have quality habitat for the eiders, but it also needs easy access for the scientists to come and go with supplies. VIDEO: STUDYING SITES FOR REINTRODUCTION Sadie Ulman explains what information the field team gathered in 2014 and why. (1:48) Video Transcript One of the primary goals of my work right now is to help with the reintroduction of Steller’s eiders on the Yukon-Kuskokwim Delta, and our focus is on this particular central Yukon-Kuskokwim Delta: Kigigak Island down on the further south, and then all the way up here on the Kashunuk River system were three different locations. We were looking for freshwater ponds, which happen to be mainly on top of these pingos which are essentially upraised tundra, kind of new tundra areas upraised with these deep, clear freshwater ponds on them with different vegetation than the lower, more grassland. This past season we were sampling a suite of habitat types, but a list of factors kept pointing toward these pingo ponds being the highest level of quality for habitat. We’re looking at salinity specifically because it’s been shown to affect the growth and mass of ducklings at an early age. Sea ducks in particular have salt glands that they don’t fully develop until anywhere from 3 to 6 days of age. After the salt glands have developed they can process salt water readily and it does not affect them. With the changing climate and weather there’s been a higher frequency of coastal storm surges coming in. So the seawater essentially is coming up and flooding a lot of the tundra area and therefore increasing the salinity in a lot of those ponds. That is very helpful to know for the reintroduction purposes, as we need to find a location where there’s plenty of freshwater available for these broods and these ducklings to be reintroduced. Click on the tools and equipment in the image below to learn more about what the research team does in the field. Can you find all six items to click on?         CLICK BELOW TO LEARN ABOUT SEADUCK SCIENTISTS!   CONDUCTIVITY (n) - the degree to which a specified material conducts electricity.   DATA (n) - values of something measured.   DELTA (n) - the area of land where a river splits into smaller rivers before it flows into an ocean.   HABITAT (n) - the natural home or environment of an animal, plant, or other organism.   INVERTEBRATE (n) - an organism that doesn’t have a spine or spinal column; insects are one example of invertebrates.   pH (n) - a number between 0 and 14 that indicates if a substance is an acid or a base.   PINGO (n) - a hill of soil-covered ice pushed up in an area of permafrost.   QUADRAT (n) - a square or rectangular plot of land marked off for the study of plants and animals.   REAR (v) - caring for and raising (offspring) until they are fully grown, especially in a particular manner or place.   SALINITY (n) - the saltiness or dissolved salt content of a body of water.   SEDIMENT (n) - matter that settles to the bottom of a liquid.   SLOUGH (n) - an inlet on a river or a creek in a marsh or tidal flat.    

Invitation to Bid (2): Fiberglass Cabin Cruiser and Platform Barge Invitation to Bid (ITB) for 21’ Fiberglass Cabin Cruiser and Trailer ITB Number: ASLC-ITB-2025-001 Start Date 06/04/2025 Close Date 06/18/2025, 3:00 PM Organization: Alaska SeaLife Center                                                                   PO Box 1329 / 301 Railway Avenue                                       Seward, AK 99664                                                                                Contact: Johanna Kinney Phone: 907-224-6349.    Email: Johannak@alaskasealife.org Date: June 4, 2025 1. Introduction The Alaska SeaLife Center invites qualified bidders to submit sealed bids for the sale of a used 21’ Parker fiberglass cabin cruiser vessel and 1,400 lb. capacity EZ Loader trailer. This procurement aims to update our fleet to support our research and outreach activities. 2. Viewing Opportunities Interested bidders are invited to view the vessel and trailer in person at Storm Chasers Marine Services, located at 13552 Lowell Point Rd, Seward, AK 99664. Viewing opportunities are available during normal business hours, which are Monday through Friday, 8 am to 5 pm. Climbing on and/or entering the vessel is not permitted. 3. Bid Submission Bids should be delivered or mailed in a sealed envelope and addressed as follows: Alaska SeaLife Center Attn: Johanna Kinney, RE: ASLC-ITB-2025-01 PO Box 1329 Seward, AK 99664 Envelopes must be clearly marked “ITB – Cabin Cruiser and Trailer: ASLC-ITB-2025-01”. Bids can be delivered in person to the front ticket counter at the Alaska SeaLife Center, located at 301 Railway Avenue, Seward, AK 99664, during normal business hours. To be considered, bids must be received by 3:00 p.m. on June 18, 2025. Bid contents should include the bidder's name, mailing address, phone number, bid number (ASLC-ITB-2025-01), bid item (Cabin Cruiser and Trailer), and bid amount. No money should be included in the bid envelope. 4. Evaluation and Award Bids will be evaluated based on complete bid information and price. The Alaska SeaLife Center reserves the right to accept or reject any bid and waive any minor irregularities. 5. Additional Terms The successful bidder must remit payment in cash or a cashier’s check and sign a bill of sale by June 25, 2025. Upon successful payment, execution of the bill of sale, and transfer of the trailer title, the successful bidder is responsible for either removing the items from the Storm Chasers' property by June 30, 2025, or providing documentation of a new storage services agreement to remain at the current location. The vessel and all associated equipment, parts, and materials are being offered and will be sold “AS IS, WHERE IS,” with no warranties or guarantees, express or implied, including but not limited to any warranty of merchantability or fitness for a particular purpose. The buyer assumes all responsibility for inspection and evaluation of the items prior to purchase and agrees to accept the items in their present condition. Vessel and Trailer Specifications Vessel Details: Vessel Name: Sea Searcher Type: Cabin Cruiser Year: 2003 Length: 21 feet Vessel Make: Parker Marine Enterprises Hull Material: Fiberglass/plastic Engines: 2 Yamaha Outboard engines, 200 HP / 10 HP each Fuel Capacity: 80 gallons (gasoline) Trailer Details: Type: EZ Loader – EZZY Class: 31 Year: 2003 Body: BT Weight: 1,400 lbs Most recent boat surveys and additional photos are available upon request to Johanna Kinney: johannak@alaskasealife.org, 907-224-6349. Invitation to Bid (ITB) for Platform Barge ITB Number: ASLC-ITB-2025-002 Start Date 06/04/2025 Close Date 06/18/2025, 3:00 PM Organization: Alaska SeaLife Center                                                                      PO Box 1329 / 301 Railway Avenue                                   Seward, AK 99664                          Contact: Johanna Kinney Phone: 907-224-6349.    Email: Johannak@alaskasealife.org           Date: June 4, 2025 1. Introduction The Alaska SeaLife Center invites qualified bidders to submit sealed bids for the sale of a used aluminum-pontoon platform barge with hydraulic steering console. This procurement aims to update our fleet to support our research and outreach activities. 2. Viewing Opportunities Interested bidders are invited to view the vessel in person at Storm Chasers Marine Services, located at 13552 Lowell Point Rd, Seward, AK 99664. Viewing opportunities are available during normal business hours, which are Monday through Friday, 8 am to 5 pm. Climbing on and/or entering the vessel is not permitted. 3. Bid Submission Bids should be delivered or mailed in a sealed envelope and addressed as follows: Alaska SeaLife Center Attn: Johanna Kinney, RE: ASLC-ITB-2025-02 PO Box 1329 Seward, AK 99664 Envelopes must be clearly marked “Platform Barge: ASLC-ITB-2025-02”. Bids can be delivered in person to the front ticket counter at the Alaska SeaLife Center, located at 301 Railway Avenue, Seward, AK 99664, during normal business hours. To be considered, bids must be received by 3:00 p.m. on June 18, 2025. Bid contents should include the bidder's name, mailing address, phone number, bid number (ASLC-ITB-2025-02), bid item (Platform Barge), and bid amount. No money should be included in the bid envelope. 4. Evaluation and Award Bids will be evaluated based on complete bid information and price. The Alaska SeaLife Center reserves the right to accept or reject any bid and waive any minor irregularities. 5. Additional Terms The successful bidder must remit payment in cash or a cashier’s check and sign a bill of sale by June 25, 2025. Upon successful payment and execution of the bill of sale, the successful bidder is responsible for either removing the vessel from the Storm Chasers' property by June 30, 2025, or providing documentation of a new storage services agreement to remain at the current location. No trailer is included with the vessel. The vessel and all associated equipment, parts, and materials are being offered and will be sold “AS IS, WHERE IS,” with no warranties or guarantees, express or implied, including but not limited to any warranty of merchantability or fitness for a particular purpose. The buyer assumes all responsibility for inspection and evaluation of the items prior to purchase and agrees to accept the items in their present condition. Vessel Specifications Vessel Details: Vessel Name: SSL Barge Year: 2003 Overall length: 32 feet Overall width/beam: 10 feet Deck load capacity: 10,000 pounds Weight: 3820 Vessel Make: Alcan Products Ltd Hull Material: double aluminum pontoon structure Pressure-treated lumber deck Propulsion: outboard compatible (no motors are for sale) Additional photos and information are available upon request to Johanna Kinney: johannak@alaskasealife.org, 907-224-6349. ***Motors and equipment shown in photographs are not for sale.  

The rare rescued Pacific walrus calf admitted to the ASLC wildlife response program in July of 2024 has foudn her longterm home and is now under the expert care of SeaWorld Orlando’s renowned animal care specialists. The calf, which was found orphaned and abandoned on the beaches of Utqiagvik, Alaska, has been named Ukiaq, which translates to “autumn” in the language of the Iñupiaq people who live in the area of northern Alaska where she was first found. Ukiaq – or Uki (pronounced “oo-kee”) as she is affectionately being called – brings the Alaskan spirit with her to Orlando, honoring the rich culture and traditions of the Alaskan Native peoples. After receiving life-saving rehabilitative care from the ASLC and being deemed non-releasable by the United States Fish & Wildlife Service (USFWS), Uki arrived at her long-term home SeaWorld Orlando on September 18, weighing approximately 220 pounds and ready to continue her care. SeaWorld Orlando was chosen as Uki’s new home because of the staff’s experience with walrus care, and the overall walrus herd at SeaWorld Orlando allows for the best nurturing environment for her overall care and development, including a female walrus that is capable of acting as a surrogate to Uki. The specialized care Uki is receiving at SeaWorld is part of the park’s long-standing commitment to wildlife rescue and rehabilitation. SeaWorld’s animal care specialists are working closely with veterinarians to ensure Uki’s needs continue to be met, including a carefully crafted feeding plan and ongoing medical evaluations. While Uki’s arrival is a heartwarming milestone, she will not be introduced to SeaWorld Orlando’s guest-facing habitats immediately. The young walrus will spend time acclimating to her new surroundings and receiving the round-the-clock care necessary to support her growth and well-being. “Uki’s journey to SeaWorld Orlando is only the beginning of her new chapter. Our team is providing dedicated, 24/7 care to ensure her transition is as smooth as possible,” said Dr. Joseph Gaspard, Vice President of Zoological Operations at SeaWorld Orlando. “We want to give her time to settle into her new home, and once she’s ready, guests will have the unique opportunity to meet this extraordinary calf and learn more about our conservation efforts in the Arctic region.” Ukiwas first discovered by Utqiagvik community members in July 2024, after a walrus herd had left the area. Alone and vulnerable, the young calf, estimated to be only a few weeks old, was transported to the Alaska SeaLife Center (ASLC) in a rescue operation in coordination with the United States Fish and Wildlife Service (USFWS). She received immediate medical care for dehydration and malnourishment from the Alaska SeaLife Center’s expert team, and additional professionals familiar with walrus care, including SeaWorld, mobilized to provide additional support for her round-the-clock care. “We are proud to have been able to quickly respond to the call for help, getting a zoological team with expertise in walrus care to the Alaska SeaLife Center within 24 hours of the calf’s rescue,” said Dr. Claire Erlacher-Reid, Senior Veterinarian at SeaWorld Orlando. “Uki’s story of survival is a testament to the importance of partnerships and rapid response in wildlife rescue, and we are committed to providing her with the highest level of care as she continues her journey here at SeaWorld Orlando.” "We are thrilled by the progress this walrus calf has made since her admission to the Alaska SeaLife Center Wildlife Response Program. As just the eleventh orphaned Pacific walrus calf to come through our doors since our opening 25 years ago, we recognize how incredibly special she is. Success stories like Ukiaq is what inspires us, the only organization authorized to rehabilitate live-stranded marine mammals in the state of Alaska," said Dr. Wei Ying Wong, ASLC President and CEO. Uki’s story of survival continues to highlight the importance of global collaboration in marine mammal rescue. “From the Utqiagvik community members who first found her, to the tireless efforts of the ASLC team, and now to our family here at SeaWorld Orlando, Uki has been surrounded by people committed to giving her a second chance,” said Dr. Gaspard. As she grows stronger in her new home, Uki will play an essential role as an ambassador for her species, educating the public on the challenges Pacific walruses face in the wild. Her story, like many other animals rescued by SeaWorld Orlando, emphasizes the park’s ongoing mission to inspire action toward the protection and preservation of marine life. The Alaska SeaLife Center’s Wildlife Response Program can only provide care for stranded and injured marine animals with help from corporate sponsors and individual donors. The Center acknowledges the ongoing generous support of the Wildlife Response Program from supporters like ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI,  and a number of individual donors, funds, and foundations such as Stanley J Williams Fund, Mesara Family Foundation, and the NC Giving Fund. Those interested in contributing to the care of these patients can visit www.alaskasealife.org/donate.      Call first! Before approaching an injured or stranded marine animal in Alaska, call the 24-hour Stranded Marine Animal Hotline at 1-907-362-2232  

Orphaned Otter Pup and Two Seal Pups Join Growing Patient List at Alaska’s Only Permanent Marine Mammal Rehab Facility The Alaska SeaLife Center (ASLC) has admitted three new patients in just four days, including an orphaned male sea otter pup from Homer on June 23. In addition, two orphaned harbor seal pups were admitted — a harbor seal pup from Nikiski on June 20, followed by another harbor seal pup from Juneau on June 23. The pup from Nikiski is currently receiving veterinary treatment, and the pup from Juneau, the smallest and most underweight patient admitted so far this season, did not make it despite intensive care efforts. Including the most recent admits, there are now 12 animals in rehabilitative care at the ASLC, with many still in critical condition and receiving life-saving veterinary care.  “We’ve had busy seasons before, but this is a notable number of admits early on in the season,” said Jane Belovarac, ASLC Wildlife Response Curator and Licensed Veterinary Technician. “With harbor seal pupping season continuing through mid-July, we’re staying prepared. We don’t yet know what the coming weeks will bring.” As Alaska’s only permanent marine mammal rehabilitation facility, the ASLC plays a vital role in responding to orphaned and injured marine animals from across the state’s vast and remote coastlines. Every case requires coordination, expertise, and long-term commitment from the ASLC’s small but dedicated team. One of the most recent examples of that commitment came just days ago, when a young sea otter pup was found stranded near Homer, Alaska. A community member spotted the pup alone on a beach in Homer and called ASLC’s 24-hour Stranded Marine Animal Hotline. The pup was found unusually far from the water during low tide, and his mother was nowhere in sight. After hours alone, birds began to approach the vulnerable pup, and the team knew they needed to act. With authorization from the U.S. Fish and Wildlife Service, the ASLC Wildlife Response Team coordinated the pup’s safe transport to Seward for immediate care. In their earliest weeks of life, sea otter pups are entirely dependent on their mothers for survival. Mothers provide near-constant care, including feeding, grooming, and maintaining the pup’s coat to ensure it stays clean and waterproof, which is critical for staying warm and buoyant. When a pup is orphaned, these responsibilities fall to the ASLC’s Wildlife Response Team, which is currently providing round-the-clock care to give the recently admitted pup the strongest chance at survival. “We believe this pup is about two weeks old, and is now under 24/7 care and showing encouraging signs,” said Jane Belovarac, Wildlife Response Curator at ASLC. “He’s alert, taking the bottle well, and has already started practicing holding his breath while in the water, which is a great early milestone. His temperature and glucose levels are stable.  As his body adjusts to drinking formula, we are watching him closely for signs of constipation, which is always a challenge for pups transitioning to new food.” This pup joins another female sea otter pup rescued from Homer earlier this month, who continues to make steady progress. The female pup has now been given the name Un’a, which means “that out in the open water” in the language of the Alutiiq/Sugpiaq people. It’s a fitting name, they say, for a special pup who has shown strong resilience in her recovery.    Un’a remains under close observation for a front limb injury that is slow to heal. While obvious on radiographs, it does not appear to bother her, and she is using the limb normally. Her energy levels are improving, and she frequently engages with enrichment toys, dives deep in her pool, and eats solid foods — all positive signs that she’s meeting milestones in her development. For updates on all 12 of the patients currently admitted, follow the Alaska SeaLife Center on Instagram and Facebook at @AlaskaSeaLifeCenter. Our team is busy providing top-notch care to patients, but we’ll share updates as often as we can.  Call First! If you encounter a stranded or injured marine animal in Alaska, contact ASLC’s 24-hour Stranded Marine Animal Hotline at 1-888-774-SEAL(7325). Do not approach or attempt to move the animal. The Alaska SeaLife Center’s Wildlife Response Program can only provide care for stranded and injured marine animals with help from corporate sponsors and individual donors. Supporters can help provide vital care for marine animals in need by donating at www.alaskasealife.org/donate.      The Center acknowledges the ongoing generous support of the Wildlife Response Program from supporters like ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI,  and a number of individual donors, funds, and foundations such as Stanley J Williams Fund, Mesara Family Foundation, M. E. Webber Foundation, The Theresa Bannister Fund, and the NC Giving Fund.       

  animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() The Gulf of Alaska is part of the North Pacific and reaches from the Alaska Peninsula in the west to the Alaska archipelago in the southeast.  The coastline includes mountains, glaciers, temperate forests, towns, and cities. Powerful currents in the Gulf of Alaska have helped shape the surrounding land and communities, and circulate necessary nutrients and marine life from the deep waters to the surface. These circulation patterns allow the Gulf of Alaska to thrive with life and sustain some of the largest United States’ fisheries, as well as provide essential habitats for seabirds, marine mammals, and fish to feed and reproduce. As described in Gulf Watch Alaska: Long-term Monitoring, the Gulf of Alaska was impacted by a major oil spill on March 24, 1989. The Exxon Valdez oil tanker ran aground in Prince William Sound, Alaska, and spilled nearly 11 million gallons of oil. An estimated  250,000 seabirds, 2,800 sea otters, 300 harbor seals, 250 bald eagles, up to 22 orcas, and billions of salmon and herring eggs were lost to the spill. Since the spill, scientists have been conducting a long-term ecosystem monitoring study to gain a better understanding of both natural and human-caused impacts to the Gulf of Alaska ecosystem. The Gulf Watch Alaska long-term monitoring program consists of a team of scientists who work together to measure and watch different parts of the ecosystem spill area. Through cooperation in this project, scientists can see the links, or connections, between all of their areas of study. In science, we call this “systems thinking.” Systems thinking looks at the web of relationships where individual pieces respond on their own and together as a whole. An ecosystem like the Gulf of Alaska is not just a collection of individual animals and plants. It is all living things interacting with each other and with the non-living components around them that drive physical and chemical processes and affect the conditions for survival. The process of systems thinking allows the Gulf Watch Alaska team to harness the power of a network of scientists that all specialize in different research subjects. This power makes the team of scientists well-equipped to solve any mysteries unfolding in the Gulf of Alaska. One such mystery arose in 2014 when people across the Pacific West coast began to notice large quantities of dead or dying birds washing up all along the shore from California to Alaska. As this event expanded, scientists began investigating the intricate network of natural processes in the Gulf to try and uncover the mystery of these dying birds. Yosty Storms is a former colleague at Gulf Watch Alaska. She is now working for the Alaska Native Science and Engineering Program in Anchorage. Recently, Yosty has heard a lot of talk regarding the birds washing ashore, as well as other very unusual events happening throughout the Gulf and surrounding land areas. Let’s follow along as Yosty visits with the Gulf Watch Alaska team and investigates these odd occurrences. Watch the video below and meet Yosty! VIDEO: Meet Yosty Storms Meet Yosty Storms and learn about a mystery occurring in the Gulf of Alaska. (1:42) Video Transcript Narrator: Meet Yosty Storms. Yosty works at the Alaska Native Science and Engineering Program in Anchorage. But when she was a student she worked with Gulf Watch Alaska. That's a long-term monitoring program looking at a large range of the North Pacific Ocean, especially the area impacted by a massive oil spill back in 1989. This area has taken a very long time to recover, because some of that oil is lingering on the beaches and offshore. That oil continues to affect the health of fish and other wildlife. Gulf Watch Alaska is a team of amazing scientists who are "on watch" for this ecosystem, keeping tabs on its recovery from the oil spill, and to see if they can detect other sorts of changes – the kinds that might be the result of global climate change. The majority of Alaskans live in communities along the coastline of the Gulf of Alaska, or within the watersheds that drain into it. Some of these communities, like here in Cordova, are dependent on the Gulf of Alaska for their local economy and jobs. Others, like the Native Village of Eyak, have over 10,000 years of history in this region. Everyone at Gulf Watch Alaska agreed that 2014, 2015, and 2016 were very, very unusual years for the ecosystem. So let’s go along with Yosty to see if we can put the mystery together. The first question Yosty wanted to ask some of the scientists was: just how unusual were these years?         Who is watching the Blob?   Archipelago (n): a section of water containing many islands   Cooperation (n): working together to accomplish a goal   Ecosystem (n): a community of living things and nonliving surroundings linked together by energy and nutrient exchange   Essential (adj): something that is necessary or very important   Habitat (n): a place that provides an animal or plant with adequate food, water, shelter, and living space to feed, breed, seek shelter, and raise young   Intricate (adj): very detailed, complex   Lingering (adj): sticking around, lasting for a long time   Sustain (v): strengthen or support physically or mentally   Thrive (v): to be healthy and successful   Watershed (n): an area of land that contains a common set of streams or rivers that all drain into a single larger body of water, such as the ocean    

A statewide rescue effort led by the Alaska SeaLife Center’s Wildlife Response Program brings in five more harbor seal pups from across Alaska The Alaska SeaLife Center (ASLC) has admitted five more harbor seal pups to the Wildlife Response Program in the span of twelve days from across the state of Alaska. Of the new patients, two pups remain in poor health, two are in critical condition, and one sadly succumbed to an infection despite intensive care efforts. These cases follow the recent admissions of an orphaned northern sea otter pup and four previously admitted harbor seal patients, all of whom required intensive rehabilitation and veterinary care.    On June 6, a female harbor seal pup was found alone on a beach near Nikiski, Alaska. Photos sent to the ASLC Wildlife Stranding Hotline confirmed that the pup was malnourished and dehydrated, likely from maternal separation. After receiving National Oceanic and Atmospheric Administration (NOAA) approval, the female pup was transported by ASLC volunteers in Kenai all the way to Seward for care. Now identified as patient PV2507, the pup is under the care of ASLC’s veterinary and wildlife response teams. While she remains in a guarded state, she has been stable for the past few days and continues to show slow signs of improvement. On June 10, a male harbor seal pup was admitted from the remote community of Pilot Point, Alaska.  Following a two-flight journey to Anchorage, the pup arrived in increasingly fragile condition. In a critical window where every minute mattered, the owner of Kenai Aviation graciously volunteered to fly the pup directly to Seward on a third and final flight, ensuring he could receive immediate veterinary care. Bloodwork confirmed the pup was battling a severe internal infection, and when his fever spiked above 105 degrees Fahrenheit the morning after his admit, the ASLC veterinary and wildlife response teams moved into critical care mode. Despite hours of intensive treatment, the pup unfortunately succumbed to his condition. The Alaska SeaLife Center extends its sincere gratitude to the Kenai Aviation pilot whose rapid response gave this vulnerable pup the best possible chance. Their support was vital in delivering urgent care when it mattered most, and it didn’t stop there.  The very next morning, on June 11, the Kenai Aviation team once again stepped in to help, transporting another harbor seal pup from Anchorage to Seward. This patient had traveled all the way from Sitka, Alaska, highlighting the statewide reach and rapid coordination of the ASLC Wildlife Response Program. Now identified as PV2509, the female harbor seal pup was found extremely malnourished and dehydrated. She remains in critical condition under close observation and intensive care.  The stream of patients being admitted wasn’t over yet. While the team worked to stabilize patient PV2509, the ASLC was monitoring a pup in a popular fishing area in Homer. At the beginning, an adult seal was observed briefly returning to the pup, but as the pup remained in a high-traffic area, more interactions between the pup and people were documented. Her condition deteriorated, and concerns grew. With no further sign of the mother and the pup’s health declining, authorization was granted. She was transported to the ASLC late on the night of June 12. She is now known as patient PV2511.  A few days later, on June 17, a seal pup near Egegik was reported alone. Photos sent showed a pup in lanugo with an umbilicus, indicating this was a premature seal. The next day, he was still in the area and there had been reports of people interacting with him.  Due to his condition and location, this animal was also authorized for recovery and rehabilitation. Thanks to the generous help of Coastal Air LLC, he was flown to King Salmon on short notice so he could make his flight to Anchorage. Harbor seal PV2512 is currently under critical care due to his delicate condition. Unfortunately, these most recent patient admits highlight the serious impacts human presence can have on harbor seal pups during pupping season. One of the most significant threats to these pups is disturbance from people and pets. If a mother seal is interrupted or feels unsafe, especially in high-traffic areas, she may abandon her pup. Once abandoned, a pup’s chances of survival drop sharply, particularly during the early days when it relies entirely on its mother’s milk for nutrition, immune support, and growth. It is critical to give seals space and share coastal areas responsibly. Never approach, touch, or attempt to move a seal pup. Keep children and pets well away from haul-out sites and known pupping areas. Approaching or disturbing a marine mammal can cause lasting harm, pose safety risks to people, and may violate the Marine Mammal Protection Act. Responsible viewing helps ensure that young animals have the best possible chance to grow and survive in the wild. If you do see a seal pup in distress, the Alaska SeaLife Center remains ready to respond to reports of stranded and injured marine mammals statewide. Call the 24-hour Stranded Marine Animal Hotline at 1-888-774-SEAL (7325). We encourage all Alaskans and visitors to save this number in their phone contacts—and remember, always call first before approaching any stranded or injured wildlife.             The Alaska SeaLife Center’s Wildlife Response Program can only provide care for stranded and injured marine animals with help from corporate sponsors and individual donors. People are encouraged to contribute to the care of rehabilitating marine animals here: www.alaskasealife.org/donate.   The Center acknowledges the ongoing generous support of the Wildlife Response Program from supporters like ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI, and a number of individual donors, funds, and foundations such as Stanley J Williams Fund, Mesara Family Foundation, M.E. Webber Foundation, and the NC Giving Fund.        

Directions & Accessibility The Alaska SeaLife Center is located at Mile 0 of the Seward Highway in Seward, Alaska, 125 miles south of Anchorage. You can reach Seward by road year-round, or via the Alaska Railroad or cruise ship during the summer season. Getting Here Car or RV: The highway to Seward is one of the most scenic byways in Alaska. We are located approximately 125 miles south of Anchorage at Mile 0 of the Seward Highway. For the most up-to-date safety, traffic, and travel information on Alaska's highways, visit Alaska 511 online.           Cruise Ship: Some cruise lines provide transfer service from the dock to the Alaska SeaLife Center as part of your tour. If you wish to visit us independently, we recommend using the shuttle or taxi services detailed below. Transportation from Anchorage: Transportation between Anchorage and Seward is available daily during the summer season through the Park Connection. Year-round transportation is available through Seward Bus Line. Local Shuttles & Taxis: There is a free shuttle offered by the Seward Chamber of Commerce during the summer season that has stops at the rail and cruise terminals. There are also several taxi services in Seward. Glacier Taxi: 907- 224-5678 Mike’s Taxi: 907- 224-2244 PJ’s Taxi: 907- 224-5555 Seward Taxi & Tours: 907- 362-8000 Parking Parking is available at no charge year-round.  Our parking lot is located adjacent to the Center. Accessibility The Alaska SeaLife Center welcomes guests of all abilities. Please contact our visitor services team if you have any questions about available accommodations and accessibility at visit@alaskasealife.org.  The Alaska SeaLife Center is wheelchair & stroller accessible. We do have a small number of wheelchairs and strollers available for use during your visit. Service Animals In compliance with the American Disabilities Act, and Association of Zoos and Aquariums accreditation standards, the Alaska SeaLife Center accommodates service animals (dogs and miniature horses) in all public areas with the exception of areas where there is concern that the service animal could affect the safety and health of collection animals, specifically the open-air aviary; and with the following understandings: • Service animals must be trained to perform specific or task directly related to a person’s disability. • Companion animals, therapy animals and comfort animals are not service animals. • Service animals must be under control and harnessed, leashed, tethered, under voice, signal or other effective control. Staff at the ASLC may ask you two questions: 1. Is the animal required because of a disability? 2. What work or task has the animal been trained to perform? The ASLC retains the right to request that service animals be removed from the premises if 1) the animal is out of control and the handler does not take control, 2) the animal is not housebroken, or 3) the animal’s behavior poses a direct threat to the safety of others. Some ASLC tours include areas that are not open to service animals. ASLC security is available to briefly assist tour guests with service animals for that portion of the tour by staying with the animal in an adjacent unrestricted area. ADA Guidelines You can find information about ADA guidelines for service animals on the ADA website at https://www.ada.gov/regs2010/service_animal_qa.html#exc. From the ADA “Frequently Asked Questions” site the following applies: “Exclusion of Service Animal” Q25. When can service animals be excluded? A. The ADA does not require covered entities to modify policies, practices, or procedures if it would “fundamentally alter” the nature of the goods, services, programs, or activities provided to the public. Nor does it overrule legitimate safety requirements. If admitting service animals would fundamentally alter the nature of a service or program, service animals may be prohibited. In addition, if a particular service animal is out of control and the handler does not take effective action to control it, or if it is not housebroken, that animal may be excluded. Q.26. When might a service dog’s presence fundamentally alter the nature of a service or program provided to the public? A. In most settings, the presence of a service animal will not result in a fundamental alteration. However, there are some exceptions. For example, at a boarding school, service animals could be restricted from a specific area of a dormitory reserved specifically for students with allergies to dog dander. At a zoo, service animals can be restricted from areas where the animals on display are the natural prey or natural predators of dogs, where the presence of a dog would be disruptive, causing the displayed animals to behave aggressively or become agitated. They cannot be restricted from other areas of the zoo.   Certified Sensory Inclusive by KultureCity The Alaska SeaLife Center was the first organization in the state of Alaska to be certified Sensory Inclusive by KultureCity. Our front-line staff have been trained and equipped with the knowledge to help people with sensory disabilities if needed during their visit. Signage can be found throughout the aquarium designating where the quiet area and headphone zones are located.        Resources: View the ASLC social story to prepare for your visit and have the best experience possible. View the Headphone Zone Map to prepare for potentially loud areas Sensory Bags, provided by KultureCity, can be checked out from the admissions counter free of charge and include headphones, the ASLC headphone zone map, fidgets, verbal cue cards, and a VIP lanyard. We also have a weighted lap pad that is available on request.      Audio Tour The ASLC Audio Tour offers rich descriptions to support visitors who are blind or have low vision, providing access to information that may not be available through visual exhibits and signage. It features some unique stories and perspectives not presented in written displays. Some stories by Sugpiaq Native Elders are presented with permission through an ongoing partnership with Chugachmiut Heritage Preservation, a program of Chugachmiut, the tribal consortium dedicated to promoting the self-determination of the seven Alaska Native communities in the Chugach Region of South-Central Alaska. For the enjoyment of all guests, we ask that you use headphones or earbuds when accessing the audio tour.  This audio program and accompanying booklet were made possible through generous grants from the U.S. Department of Education’s Governor’s Emergency Education Relief Funds through the office of Alaska Governor Mike Dunleavy with additional support from the Seward Community Foundation, recorded in partnership with Chugachmiut Heritage Preservation, a program of Chugachmiut, the Tribal consortium created to promote self-determination to the seven Native communities of the Chugach Region,  and CRIS Radio, a nonprofit 501(c)3 radio-reading service, serving people who are blind or print-challenged.     

The Alaska SeaLife Center (ASLC) and multiple partners responded to a male ringed seal that was found out of his habitat on an oilfield in Alaska’s Beaufort Sea on Dec. 17, 2025. This is the Center’s first ringed seal response in over four years and one of only 30 ringed seals admitted in the Center’s more than 25-year history, making the case exceptional for the ASLC Wildlife Response Program.  The seal, part of the Arctic subspecies listed as threatened under the Endangered Species Act, was first observed by oilfield operators. Staff contacted NOAA Fisheries, the federal agency that manages the Marine Mammal Health and Stranding Response Program, for guidance. With coordination from NOAA Fisheries, the ASLC, the local operators, and Alaska Clean Seas, the young ringed seal was brought back to the ice, but repeatedly returned to the oilfield.  The ice extending along the coast of Alaska’s Beaufort Sea is a remote Arctic region where winter sea ice extends miles from shore and is often stacked by high winds, making it unlikely that humans could safely escort the seal to open water. Crews at the oilfield used an auger to drill breathing holes in the ice to encourage the seal to access the sea. Although the seal placed his head in the open holes, he did not swim away. When the seal was found moving into areas with heavy machinery, and taking into account the seasonal low light conditions, he was placed into a crate to prevent accidental injury from vehicles. With continued risk to the animal, NOAA Fisheries authorized transport to the ASLC for rehabilitation (MMPA/ESA Permit #24359).  Any response involving ice seals in Alaska requires careful consideration of regulatory policy and respect for the Indigenous communities that rely on these animals for subsistence. In rehabilitation situations involving Alaska’s four ice seal species (ringed, spotted, bearded, and ribbon), the ASLC follows a precautionary non-release policy developed by NOAA Fisheries, an Alaska Native organization, and the Ice Seal Committee: ice seals transported outside of their natural range for treatment and care are not eligible for release. This policy eliminates the risk of disease transmission between marine ecosystems from these individuals, particularly for animals originating from remote and culturally significant regions. In this case, the collaborative decision to admit this ringed seal was not made lightly, as it shapes this seal’s future.  “This response reflects the complexity of wildlife response in Alaska,” said Jane Belovarac, ASLC Wildlife Response Curator. “Our priority with live animals is always to rehabilitate, release, and see animals thrive in the wild. When relocation efforts in situations like this are unsuccessful, and the animal remaining in place is not safe, we are prepared to provide the specialized care needed to ensure their well-being.” ?Currently, only the ASLC and two other facilities in the United States care for ringed seals. As one of the very few ringed seals in human care and a member of the Arctic subspecies listed as threatened under the Endangered Species Act, this seal will serve as an important ambassador for his species and teach us more about the challenges that his species faces as Arctic conditions continue to change.  The ASLC remains committed to working alongside federal agencies, Indigenous partners, and industry collaborators to protect the health of ice seal populations and the ecosystems they depend on. This response reflects the complexity of conservation work in Alaska’s rapidly changing Arctic and the importance of thoughtful, collaborative decision-making when human activity and wildlife intersect. We thank the partners and crews involved in the response, including Alaska Clean Seas, the Ice Seal Committee, members of the Marine Mammal Health and Stranding Response Program, and NOAA Fisheries.    The Center acknowledges the ongoing generous support of the Wildlife Response Program from supporters like ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI,  and a number of individual donors, funds, and foundations such as Stanley J Williams Fund, Mesara Family Foundation, The Theresa Bannister Fund, and the NC Giving Fund.   Call first! Before approaching an injured or stranded marine animal in Alaska, call the  24-hour Stranded Marine Animal Hotline at 1-888-774-SEAL(7325).             

      Starting August 21 through Saturday, August 27, 2022 (ending at 8 PM)   Every donation of $25 or more for ASLC pinniped research will receive a limited edition sticker decal that shows you are a supporter of this critical research! This exclusive sticker was created specifically for this event by local Alaskan artist Sea Spray AK. (Donations must be made through this link to receive a sticker!)     Scientific Research was the founding reason that the Alaska SeaLife Center was created in 1991, and it remains a staple in our mission to this day. Two of the amazing scientific research projects at the ASLC that both focus on pinnipeds (seals and sea lions) are in need of your help!   Federal grant funds that support scientific research have diminished over the years, making the financial support for important scientific research more and more competitive. Less support has been coming to the ASLC science teams for research that is unique to the Alaska SeaLife Center and our partner scientists.   The important research our scientists have been working on for the endangered populations of Steller sea lions and ice seals have both been heavily impacted by funding reductions. With changing oceans and climates, the pinniped research at the ASLC has never been more important.   The Chiswell Island Steller Sea Lion Remote Video Monitoring Project has been collecting data for over 20 years at the ASLC, and years of hard work has just now started to give us a big picture look at the changes happening in our oceans.    The Alaska SeaLife Center is also home to the PHOCAS project, a special partnership between ASLC and the University of California Santa Cruz. PHOCAS stands for the Physiology and Health of Cooperating Arctic Seals. This program involves trained Alaskan ice seals that are studied at ASLC and Long Marine Laboratory. Scientists and veterinarians with expertise in seal science are working together to gather needed information about the behavior, development, health, and physiology of spotted, ringed, and bearded seals. The project will provide insight into how these seals may respond to changing ice and climate conditions in Alaskan Arctic and subArctic waters.    Every year the climate and our oceans are changing, and the science team working with arctic species of ice seals at the ASLC is collecting critical data on how these elusive arctic species will be impacted. If this project does not have enough funding to continue, all who care for the survival of these irreplaceable arctic species will be impacted.       From August 21 - 27, 2022 ASLC social media pages will be filled with stories and updates from the Center's pinniped scientific research teams.   Follow us on Facebook  Follow us on Instagram  Follow us on YouTube   Every donation of $25 or more for ASLC pinniped research will receive a limited edition sticker decal that shows you are a supporter of this critical research! This exclusive sticker was created specifically for this event by local Alaskan artist Sea Spray AK. (Donations must be made through this link to receive a sticker!)   Please join us this week on social media to learn more about this important research and help sustain this incredible scientific work that will inform policymakers for years to come.       

animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         WELCOME, TEACHERS! The Alaska SeaLife Center and COSEE-Alaska are excited to present their latest virtual field trip (VFT), Eyes on Eiders. Join Dr. Tuula Hollmen and her team as they investigate the lives of Steller's eiders in Alaska and what it takes for eiders to breed successfully. Learn from field researchers, animal care staff, lab researchers, and the principal investigator (Dr. Hollmen) herself. GRADE LEVEL: 5th-8th TIME NEEDED: Between one and four 1-hour class periods (teachers may choose to use all or some of the supplementary lessons). NUTSHELL: Students will learn about natural history of Stellers' eiders and their recent decline in Alaska. They will also explore the type of research that goes into planning the recovery of a species, as well as encounter several genres of scientific careers. LEARNING OBJECTIVES: After completing this virtual field trip, students will be able to: - Explain the life cycle of Steller’s eiders and how husbandry staff need to understand the life cycle and annual migration of these birds in order to care for the birds in captivity. - Describe this eider research project in terms of the scientific method. - Understand the scope of work, creativity, and inquisitiveness that goes into recovery efforts for a threatened species. BACKGROUND: In this virtual field trip, students will meet Dr. Tuula Hollmen (Principle Investigator), Tasha DiMarzio (Avian Curator), Nathan Bawtinhimer (Aviculturist), Sadie Ulman (Research Coordinator) and Dr. Katrina Counihan (Scientist). They compose the team at the Alaska SeaLife Center working with Steller’s eiders. Your students will follow the eider team into the field, a unique outdoor lab, and a traditional indoor lab as these scientists work to answer questions about Steller’s eiders. This VFT can be used in a number of ways. Individuals may navigate through the pages on their own and meet all the scientists through the links on the right-hand bar. Self-guided exploration can be completed in about an hour. Alternately, teachers may facilitate a structured experience, working through each page of the VFT together as a class. Lesson plans (included in the right-hand column of this page) are available to supplement online content. Lesson plans include activities that help explain taxonomy, explore community ecology, and engage students with hands-on field techniques and an egg dissection. TO USE THIS VIRTUAL FIELD TRIP YOU WILL NEED: - Internet access, video-streaming capabilities - Access to Eyes on Eiders the virtual field trip - Projection system (with audio) to display content or a computer lab (with headphones) - Corresponding lesson plans (arranged as PDFs in the right hand column of this page) UNABLE TO RUN THE STREAMING VERSION? REQUEST A FREE COPY OF ALL MATERIALS ON CD BY EMAILING: education@alaskasealife.org ADDITIONAL RESOURCES: General information on Steller's Eiders: US Fish & Wildlife Service: Steller's Eider Factsheet US Fish & Wildlife Service: Steller's Eider Recovery Plan US Fish & Wildlife Service: Species Profile for Steller's Eiders General information about the Y-K Delta: Video: Alaska's Yukon Delta National Wildlife Refuge Education Resources Related to Climate Change: NOAA Education Resources: Climate Change Impacts Contact Us: If you have any questions about this virtual field trip, please contact the Alaska SeaLife Center Education Department at education@alaskasealife.org or 907-224-6306. For more information on classes we offer, including our inquiry-based 50-minute Distance Learning programs, visit our website at www.alaskasealife.org.         CURRICULUM SUPPLEMENTS Use the .pdf links below to access classroom activities for each section of the MELTDOWN virtual field trip. Background_Activities.pdf Questions_Activities.pdf Center_Activities.pdf Field_Activities.pdf Results_Activities.pdf Glossary.pdf          

Seward, Alaska (December 9, 2021) – The Alaska SeaLife Center (ASLC) announces the publication of “Stranded beluga (Delphinapterus leucas) calf response and care: reports of two cases with different outcomes” in the journal Polar Research primarily authored by ASLC’s Director of Animal Health, Dr. Carrie Goertz.  This publication was two years in the making and highlights the response and care of two beluga calves at the Center: Naknek rescued in 2012 and Tyonek in 2017. Both cases detailed in the piece provide invaluable information about the beluga populations the calves originated from and new information on wild beluga neonates.    Collecting the data for this publication while rehabilitating beluga calves required a collaborative effort from many prestigious contributors like SeaWorld, Mystic Aquarium, Shedd Aquarium, Vancouver Aquarium, Georgia Aquarium, Woods Hole Oceanographic Institute, and the National Oceanic and Atmospheric Association. “I am so proud of how the professional zoological community came together to care for and learn from both calves. Looking back, I know that it was exhausting and emotionally draining at times, but what I really remember is the joy of seeing the beluga calves respond to treatment, watching their personalities develop, and feeling the support and camaraderie of the care team. The group brought decades of experience caring for stranded cetaceans as well as neonatal belugas and dolphins in aquaria in order to support both Naknek and Tyonek,” explains Goertz.  The rehabilitation success rate of beluga whales is extremely low. While Naknek succumbed to his ailments in 2012, he survived the longest out of any rehabilitated beluga calf at that time.    The team beat the odds in Tyonek’s case, however, making him the first beluga calf to be successfully rehabilitated in the world. After spending about six months in rehabilitation at the Center, Tyonek became a resident at SeaWorld San Antonio in 2018 where he remains integrated into their pod. Steve Aibel was one of the cetacean experts from Shedd Aquarium that contributed to Tyonek’s care in Alaska and now continues to work with him at SeaWorld. “Working with Tyonek, from day one to date, made visible the strength, powerful contribution and impact that comes from collaboration within the zoological community. This was one of many instances where animal care experts, veterinarians, and research scientists from multiple organizations came together with a singular goal of helping a little whale in need. I distinctly remember a room filled with hundreds of years of beluga whale experience working together to solve the many challenges Tyonek faced,” states Aibel, Vice President Zoological Operations at SeaWorld San Antonio.    These cases demonstrate the ability to care for and rehabilitate stranded beluga calves, once thought to be impossible. The findings in this paper offer tools to assist in the conservation of endangered populations as well as aid in wildlife rescue in the future. “The greatest part is this important story is still being told today with the help of a healthy and thriving whale. I am not unique in saying that this experience changed the people who cared for him 24 hours a day for several months. In truth, every rescue does that! Every rescue matters as does every animal that we care for. They all add to the collective knowledge that helped Tyonek and will continue to help even more animals in need,” continues Aibel.  Support for the care of these beluga calves came from the Alaska SeaLife Center, Georgia Aquarium, Mystic Aquarium, SeaWorld, Shedd Aquarium, the Texas Marine Mammal Stranding Network, and Vancouver Aquarium. Additional funding was provided by the Prescott Grant Program, Prescott Emergency Grant Program, SeaWorld Busch Gardens Conservation Fund, and individual and corporate donations to the Center’s Wildlife Response Program.   The scientific article can be found on the Polar Research website here.   About ASLC  Opened in 1998, the Alaska SeaLife Center operates as a 501(c)(3), non-profit research institution and public aquarium in Seward, Alaska. The Center generates and shares scientific knowledge to promote understanding and stewardship of Alaska’s marine ecosystems. The ASLC is an accredited member of the Association of Zoos and Aquariums. To learn more, visit www.alaskasealife.org.  

Back-to-Back Rescues Bring Two Orphaned Sea Otter Pups to ASLC for Rehabilitation and Veterinary Treatment   Seward, Alaska (November 17, 2025): The Alaska SeaLife Center (ASLC) recently admitted two orphaned northern sea otter pups rescued from the Homer area within a two-week span. A female, estimated to be less than two months old, was found alone and extremely malnourished on the beach. Ten days later, a male otter pup was reported in the same region after a fall storm moved through the area. The male pup is estimated to be between 4 and 6 months old and was found in a less severe emaciated state, but lethargic, alone, and in poor condition.    Reports of both otters came through ASLC’s 24-hour Stranded Marine Animal Hotline (1-888-774-7325), prompting swift responses from ASLC’s wildlife response team. Staff and volunteers observed each pup closely to ensure no adult otters were caring for the pups. When no adults were spotted, the animals were transported to Seward for urgent veterinary care at the ASLC with prior authorization from U.S. Fish and Wildlife Service (USFWS).    The female pup is currently in critical condition and receiving intensive care after arriving at the Center on October 20, 2025, extremely malnourished, dehydrated, severely anemic, and weak.   “Usually, when an otter pup is first admitted and receiving its first veterinary exam, it will vocalize often and move around a lot. This pup was so lethargic and weak that she barely made any noise, which was immediately concerning,” said ASLC Veterinarian Dr. Emmanuelle Furst.    Since the female pup’s arrival, she has slowly started to gain weight and strength with 24-hour care and veterinary treatment. She continues to have gastrointestinal issues, which the ASLC animal care and veterinary teams are watching closely. Ten days later, an older male pup, estimated to be around 4 to 6 months old, was admitted after being found alone and resting unusually high up on the beach in Homer. He appeared weak and lethargic, and birds had begun to gather near and peck at him. The male pup is currently undergoing additional medical tests to better understand his condition and prepare targeted veterinary treatments, as he fights to overcome his health challenges.  With these two newest sea otter patients, the Alaska SeaLife Center is now caring for four orphaned sea otter pups, all of whom will be deemed non-releasable due to their young age (under six months old) and their dependence on intensive human care. The wildlife response program has seen an uptick in orphaned, injured, and deceased sea otter reports across the state this year, and the ASLC continues to run tests to better understand what is impacting the wild populations.  These young otters’ stories serve as a powerful reminder of Alaska’s unique wildlife and the ecosystems they rely on, and our shared responsibility to protect them. As the state’s only permanent marine wildlife response and rehabilitation facility, the Alaska SeaLife Center remains committed to giving every animal the best possible chance at survival while deepening understanding of the ocean we all depend on.  The ASLC Wildlife Response Program operates year-round to respond to and care for stranded and orphaned marine animals across the state. You can help make rescues like these possible by donating to support their care and by reporting animals in need. Before approaching an injured or stranded marine animal, call the 24-hour Stranded Marine Animal Hotline at 1-888-774-SEAL (7325). Your Support Matters  The Alaska SeaLife Center’s Wildlife Response Program can only provide care for stranded and injured marine animals with help from corporate sponsors and individual donors. Supporters can help provide vital care for marine animals in need by donating at www.alaskasealife.org/donate.  The ASLC acknowledges the ongoing generous support of the Wildlife Response Program from supporters like ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI,  and a number of individual donors, funds, and foundations such as Stanley J Williams Fund, Mesara Family Foundation, M. E. Webber Foundation, The Theresa Bannister Fund, and the NC Giving Fund.              

After nearly two months of rehabilitation at the Alaska SeaLife Center, male sea otter pup "Qilak" finds home in Chicago at Shedd Aquarium.  Qilak (pronounced Kee-lak), a five-month-old rescued male northern sea otter (Enhydra lutris kenyoni), arrived to his new home at Shedd Aquairum on October 24, 2022.  Since his rescue, the pup received around-the-clock care at the Alaska SeaLife Center (ASLC) in Seward, AK, the only permitted stranding marine mammal response facility in the state. Members of Shedd’s animal care and response team worked alongside partners to rehabilitate Qilak before bringing him to Shedd on Oct. 25. For now, Qilak remains behind the scenes at Shedd as he continues to reach milestones and build bonds with the animal care team and other otters.  Qilak spent nearly two months being monitored day and night and receiving regular health exams by ASLC staff. He has feedings every four hours, which has slowly decreased as he continues to grow and progress. He has been doing well since his arrival in Chicago, receiving continual care behind the scenes at Shedd’s Abbott Oceanarium. At five months old, he is a bit older than past rescues, which means he has already met some developmental milestones and continues to show signs of independence. ASLC and Shedd staff worked together to care for Qilak during his last few weeks of rehabilitation. (photo: Shedd Aquarium) The animal care team at Shedd looks forward to watching him continue to grow and thrive. Qilak’s next few milestones will be learning his new habitats, bonding with other otters and more. “As an organization dedicated to care and conservation, Shedd Aquarium is equipped to step in to assist our partners, and in this case, we offered rehabilitation support and ultimately a home for this pup in need,” said Peggy Sloan, chief animal operations officer at Shedd Aquarium. “Our rescued population of sea otters are important ambassadors for their wild counterparts creating compassion for this keystone, endangered species.” For now, Qilak remains behind the scenes at Shedd as he continues to reach milestones and build bonds with the animal care team and other otters.  Qilak spent nearly two months being monitored day and night and receiving regular health exams by ASLC staff. He has feedings every four hours, which has slowly decreased as he continues to grow and progress. He has been doing well since his arrival in Chicago, receiving continual care behind the scenes at Shedd’s Abbott Oceanarium. At five months old, he is a bit older than past rescues, which means he has already met some developmental milestones and continues to show signs of independence. Shedd staff members observe Qilak  at the Alaska SeaLife Center before his transport to Chicago. (photo: Shedd Aquarium) The pup was examined at ASLC and found to be underweight, but otherwise, he was strong and alert. Veterinarians and animal care team members monitored him closely to ensure he remained in good condition. He was already eating solid foods, swimming, grooming and more. During his rehabilitation, Shedd’s animal care team sent a rotating group of support staff to work alongside ASLC for round-the-clock care. ASLC led the pup’s naming that resulted in Qilak, which means dome of the sky, the entire sky or heaven in Inuit.  “Otter pups need care and attention 24 hours a day, seven days a week, so it takes a village to rehabilitate a young animal,” said Jane Belovarac, Wildlife Response Curator at ASLC. “While the process is lengthy, there is nothing more rewarding than watching our patients grow and find their homes. We’ve been honored to be part of his second chance at life, and we’ll continue to follow his journey.” Qilak joins the rescued sea otter population at Shedd Aquarium, including the other new arrivals Otters 926 and 929 that can now occasionally be seen on exhibit in the Abbott Oceanarium. There are now a total of six sea otters that call the aquarium home. Find more information about sea otters at Shedd on the aquarium’s website: https://www.sheddaquarium.org/animals/sea-otter.   Shedd Aquarium staff report that Qilak is settling in well. This photo is from when he first arrived at Shedd (photo: Shedd Aquarium)   About Northern Sea Otters The northern sea otter subspecies (E. lutris kenyoni), is found in the Aleutian Islands, Southern Alaska, British Columbia, and Washington. Within Alaska, there are three stocks. The Southeast stock can be found in the coastal waters of Southeast Alaska. The Southcentral population spans from west of Glacier Bay to the eastern edge of Cook Inlet. The Southwest population stretches from the western edge of Cook Inlet out the Aleutian Islands. In Alaska, sea otter populations in Southcentral and Southeast Alaska have stabilized or are continuing to increase. However, in Southwest Alaska, sea otters have experienced a sharp population decline in the last 20 years. The sea otter species as a whole are listed as “Endangered” on the IUCN Red List, while the northern sea otter is listed as “Threatened.” Main threats in the wild include predation, overharvest, fishery interactions, disease, and oil spill. Their main prey species include sea urchins, crabs, clams, mussels, octopus, fish, and other marine invertebrates. Sea otter teeth are adapted for crushing hard-shelled invertebrates such as clams, urchins, and crabs.   About the Alaska SeaLife Center Opened in 1998, the Alaska SeaLife Center operates as a private, non-profit research institution and a public aquarium. It generates and shares scientific knowledge to promote understanding and stewardship of Alaska’s marine ecosystems. The ASLC is an accredited member of the Association of Zoos and Aquariums. To learn more, visit www.alaskasealife.org.   About Shedd Aquarium The John G. Shedd Aquarium in Chicago sparks compassion, curiosity and conservation for the aquatic animal world. Home to 32,000 aquatic animals representing 1,500 species of fishes, reptiles, amphibians, invertebrates, birds and mammals from waters around the globe, Shedd is a recognized leader in animal care, conservation education and research. An accredited member of the Association of Zoos & Aquariums (AZA), the organization is an affiliate of the Smithsonian Institution and supported by the people of Chicago, the State of Illinois and the Chicago Park District. www.sheddaquarium.org  

Distance Learning Visit Alaska…  virtually! Our live, interactive videoconference programs expand your students' scientific experience with engaging multi-media presentations. Using inquiry-based learning, these 55-minute conferences incorporate live animals (whenever possible) and current research programs happening right here at the Alaska SeaLife Center! The materials for each program include a teacher's guide with specific background information and activity ideas, as well as supplies for the session's hands-on activities. Video Sample:  Marine Mammal Adaptations Registration To register for a Distance Learning program, Download the Distance Learning registration form and return it via e-mail. To accommodate shipping materials, reservations must be made at least 30 days in advance. See below for prices and time zone recommendations. Please email distancelearning@alaskasealife.org or call (907) 224-7900 for more information. Program Descriptions PROGRAM NAME GRADES DESCRIPTION Who Lives Where? Pre-K Meet Alaska’s wettest residents! Find out where Alaska’s marine animals live, what they eat, and how they move. Beaks, Bubbles, & Burrows K-3 Observe the diving seabirds in our avian habitat as we discuss the behaviors and adaptations of these intriguing animals. Marine Mammal Adaptations K-5 Discover how these mammals are able to thrive in Alaska's frigid waters by observing our own resident seals and sea lions. Terrific Alaskan Tidepool Travels 1-5 Take a walk through the Alaskan intertidal zone and meet our tough and mysterious local invertebrates. Eat or Be Eaten in Alaska 4-6 Discuss the complexity of food webs by exploring some of Alaska's most interesting animals and ecosystems. Living in the Ring of Fire 5-8 Verify plate tectonic theories by investigating geologic activities around the Pacific plate, specifically here in Alaska. Cephalopods: Squid Dissection 5-9 Get your hands into a "head-footed" animal as we learn more about cephalopods through dissection and discussion! (Please contact us about squid availability. Observation-only sessions are also an option.) Sea Lion Monitoring 6-12 Learn how scientists at the center study a wild population of endangered Steller sea lions hauled out on the Chiswell Islands. Practice remote video monitoring yourself! The Scoop on Poop 6-12 Roll up your sleeves and analyze sea lion scat as we learn more about the hands-on way some of our scientists study these animals' diets.   Prices Program costs include teacher guides, materials* for up to 30 students (additional students are $1 each) and postage. An additional $20.00 may be added to reservations made less than 30 days in advance.   PROGRAM NAME COST Beaks, Bubbles, & Burrows Marine Mammal Adaptations Terrific Alaskan Tidepool Travels Eat or Be Eaten in Alaska Living in the Ring of Fire Sea Lion Monitoring $190.00 The Scoop on Poop $220.00 Cephalopods: Squid Dissection (including squid) $240.00 (squid shipping within U.S. only; if you provide your own squid the program is $190.00)  * International programs: Shipping to countries outside the United States will require an additional fee.  Also, customs procedures may prevent the shipping of physical materials to countries outside of the U.S. - in these cases, we will send materials electronically. Time Zone Recommendations Our distance learning sessions are taught from the exhibits, which rely on natural light. As Alaska's sunrise/sunset times vary dramatically from season to season, the following table lists optimal time recommendations for booking your reservations. There can still be large fluctuations within a calendar month, so these times are only a guide. Additional times may be available - please contact us for more information.   NORTH AMERICAN TIME ZONES (includes daylight savings time) ALASKA PACIFIC MOUNTAIN CENTRAL EASTERN September 7:30 AM - 5:00 PM 8:30 AM - 6:00 PM 9:30 AM - 7:00 PM 10:30 AM - 8:00 PM 11:30 AM - 9:00 PM October 8:30 AM - 5:00 PM 9:30 AM - 6:00 PM 10:30 AM - 7:00 PM 11:30 AM - 8:00 PM 12:30 PM - 9:00 PM November 9:00 AM - 4:30 PM 10:00 AM - 5:30 PM 11:00 AM - 6:30 PM 12:00 PM - 7:30 PM 1:00 PM - 8:30 PM December 10:00 AM - 4:00 PM 11:00 AM - 5:00 PM 12:00 PM - 6:00 PM 1:00 PM - 7:00 PM 2:00 PM - 8:00 PM January 10:00 AM - 4:00 PM 11:00 AM - 5:00 PM 12:00 PM - 6:00 PM 1:00 PM - 7:00 PM 2:00 PM - 8:00 PM February 8:30 AM - 5:00 PM 9:30 AM - 6:00 PM 10:30 AM - 7:00 PM 11:30 AM -8:00 PM 12:30 PM - 9:00 PM March 8:00 AM - 5:00 PM 9:00 AM - 6:00 PM 10:00 AM - 7:00 PM 11:00 AM - 8:00 PM 12:00 PM - 9:00 PM April 7:00 AM - 5:00 PM 8:00 AM - 6:00 PM 9:00 AM - 7:00 PM 10:00 AM - 8:00 PM 11:00 AM - 9:00 PM May 7:00 AM - 5:00 PM 8:00 AM - 6:00 PM 9:00 AM - 7:00 PM 10:00 AM - 8:00 PM 11:00 AM - 9:00 PM June 7:00 AM - 5:00 PM 8:00 AM - 6:00 PM 9:00 AM - 7:00 PM 10:00 AM - 8:00 PM 11:00 AM - 9:00 PM July 7:00 AM - 5:00 PM 8:00 AM - 6:00 PM 9:00 AM - 7:00 PM 10:00 AM - 8:00 PM 11:00 AM - 9:00 PM August 7:00 AM - 5:00 PM 8:00 AM - 6:00 PM 9:00 AM - 7:00 PM 10:00 AM - 8:00 PM 11:00 AM - 9:00 PM Technical Requirements We use Zoom to connect.  Please contact us if you have questions about using other platforms. Customized Programs Do your students show exceptional enthusiasm for a particular lesson plan or subject?  With advance notice we can modify existing programs or create specialized programs to accommodate specific lesson goals, ages, or comprehension levels. Sessions are designed to be 55 minutes in length but can be adapted to fit your class period.    

animatedcollapse.addDiv('A', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init() animatedcollapse.addDiv('B', 'fade=1') animatedcollapse.ontoggle=function($, divobj, state){ //fires each time a DIV is expanded/contracted //$: Access to jQuery //divobj: DOM reference to DIV being expanded/ collapsed. Use "divobj.id" to get its ID //state: "block" or "none", depending on state } animatedcollapse.init()         The Steller's eiders kept the team busy during the 2014 breeding season. The combination of nesting materials, nest placement, privacy, mate choice and staffing worked for the eiders! For the first time in the program’s history, two Steller’s eider hens, Scarlet and Eek, incubated their eggs for the full 26 days and hatched ducklings. Scarlet had three ducklings and Eek had one. Four other ducklings hatched after artificial incubation and were raised by people for a total of eight Steller’s ducklings. The hens fully incubating their eggs was a grand achievement for the eider team! In the early stages of the project, hens would only lay infertile eggs, or not build a nest, or not stay on their nest through the whole incubation. In captivity, Steller’s eider hens had never incubated their eggs completely on their own before now! In addition to the eight ducklings of 2014, the eider team had many eggs that were infertile or that were fertile but never hatched. All the eggs that do not hatch go to the lab where Dr. Katrina Counihan and her lab technicians get to work. Every egg provides further data for researchers to use to learn more about eiders. VIDEO: DATA FROM EGG DISSECTIONS Discover what Dr. Katrina is learning in her eider lab. (1:40) Video Transcript I do various projects with the eiders. The major one is I oversee the processing of the eggs every summer. We get eggs from the captive spectacled and Steller’s eiders. For this summer we got over 300 eggs from both species, so we have help usually in the summer from interns and also volunteers which are often college students. Without them we wouldn’t be able to get through all these samples, because it takes about 30-45 minutes per egg to process it. As you can see here we use a variety of tools: digital calipers to measure the width and length of all of our eggs, and then we have a scale that we [use to] weigh the eggs before we start the dissection. The first thing we do is we’ll use these little just basic knitting scissors and we cut around the center of the egg. And then we’ll dump out as much of the albumen as we can into a large dish and then the yolk into a second one of the large Petri dishes. And then we’ll use really simple things, like just plastic forks to mix up albumen and yolk before we take samples, and then spatulas to scrape up every last little bit to make sure we get the samples. And then just little plastic syringes to suck up the samples into the vials. And then we weigh out the yolk and the albumen. So we literally save every bit of every egg we get. Dr. Katrina Counihan uses parts of the eggs she dissects to study eider health. We know a lot about how people deal with being sick, but not much about what eiders do to stay healthy. One part of the egg she is interested in is the yolk because it contains immunoglobulin (or antibodies) which would help the duck fight off diseases. Dr. Counihan looks at the immunoglobulin in the eggs to understand how the eiders are able to fight diseases. Thanks to Dr. Counihan’s work, if the eiders are reintroduced, the scientists will understand how healthy the captive birds are and how the eiders will be able to handle any diseases that they might encounter in the wild. Dr. Hollmen believes that the collaboration and communication between the research and husbandry staff is the key to the team’s success. The husbandry staff works to make the eiders feel at home and healthy so they lay eggs. Some of those eggs hatch into ducklings that increase the captive reservoir population. Researchers in the lab use the other eggs to find information on the health of the birds. The field team tries to find a wild habitat where the eiders could survive. Each team member contributes a specialized set of skills and everyone is united by the goal of learning about and helping a unique arctic species.       CLICK BELOW TO LEARN ABOUT SEADUCK SCIENTISTS!   ALBUMEN (n) - the white of an egg.   CALIPER (n) - a tool with two moveable arms that is used to measure thickness, diameter, length or width.   COLLABORATION (n) - the action of working with someone to do or create something.   IMMUNOGLOBULIN (n) - also called antibody; a protein that helps the immune system find and get rid of foreign objects like bacteria and viruses.   PETRI DISH (n) - a shallow plastic or glass dish often used in labs to culture bacteria or collect samples.   YOLK (n) - the yellow center of an egg that supplies food to a growing bird before it hatches.