The Alaska SeaLife Center (ASLC) has admitted a male harbor seal pup into the Wildlife Response Program. The harbor seal pup was found far from the water’s edge near a beach in Port Moller on the Alaska Peninsula. The animal was monitored for several days by the Alaska Department of Fish and Game until it became evident that intervention was necessary when no seals returned to the pup. The animal was transported to the Center after receiving National Oceanic and Atmospheric Administration approval on June 15. Lake Clark Air graciously donated the flight for the seal to Anchorage.  Upon the initial admit exam, the main concerns of the veterinary team include severely low body weight,  dehydration, and gastrointestinal issues. The team is currently providing initial stabilizing treatments and examining the patient further to understand the severity of the animal’s condition. A full press release will be provided with updates on this animal after further monitoring and examination.   The Alaska SeaLife Center’s Wildlife Response Program can provide care for animals like this harbor seal because of donations from corporate sponsors and individual donors. People are encouraged to contribute to the care of this patient here: www.alaskasealife.org/donate. The Center acknowledges the ongoing generous support of the Wildlife Response Program from companies like ConocoPhillips, Marathon Petroleum Corporation, SeaWorld Busch Gardens Conservation Fund, PetZoo, Borman Family Foundation, GCI, Partners4Wildlife, Sea Otter Foundation & Trust, and Grizzly Pet Products.  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.   

The Alaska SeaLife Center admitted a northern fur seal pup to the Wildlife Response Program on January 31, 2023. Fur seals are relatively uncommon wildlife response patients, and have not been cared for at the ASLC since 2017.   The female pup, estimated to be around six months old, was seen swimming erratically near the shore in Sitka, Alaska. Her abnormal behavior worried local residents, who reported the pup to the ASLC 24-hour stranding hotline (1-888-774-7325). Sitka is an unusual location to see northern fur seals this time of year, which raised concerns for her survival by ASLC staff. After receiving approval from the National Oceanic and Atmospheric Administration (NOAA), the animal was transported to the Center for treatment.   The main concerns found by the ASLC veterinary team upon the initial admit exam were dehydration, malnourishment, and signs of an unknown infection found in her bloodwork. Despite these concerns, she was observed to be active and alert when handled. The team found no evidence of severe physical trauma; however, noted that the pup seems smaller than average for her age. Staff are currently providing initial treatments and examining the patient further to understand more details about her condition.    The Alaska SeaLife Center’s Wildlife Response Program can only provide care for stranded and injured marine animals with help from federal grants, corporate sponsors, and individual donors. Those interested are encouraged to contribute to the care of rehabilitating marine animals here: www.alaskasealife.org/donate. The Center acknowledges the ongoing generous support of its Wildlife Response Program from companies like ConocoPhillips, Marathon Petroleum Corporation, Matson, PetZoo, GCI, and a number of individual donors, funds, and foundations such as The Stanley J. Williams Fund, Mesara Family Foundation, and The NC Giving Fund.         

The Alaska SeaLife Center (ASLC) Wildlife Response Program now has six harbor seal pups under its care after the admission of two new patients — a male from Naknek admitted on June 17, and a female from Wrangell admitted on June 22.    The first pup was spotted by locals at a site in Naknek and reported to the U.S. Fish and Wildlife Service (USFWS) National Wildlife Refuge in King Salmon, AK, who contacted ASLC. Photos showed the pup was in poor condition, prompting the National Oceanic and Atmospheric Administration (NOAA) to authorize pickup. However, rescue efforts were complicated when the pup returned to the water and became entangled in a net before responders arrived. Fortunately, locals were able to free the pup, and it was transferred to a USFWS biologist and driven to a local airport for a flight to Anchorage. Here, staff from NOAA were able to coordinate the final leg of its journey to the ASLC for care.   The second pup was spotted in Wrangell, AK, hauled out on a rocky beach where seals are not typically seen. This raised concerns for two local beach walkers who reached out to NOAA. The seal’s skinny condition suggested prolonged separation from its mother, leading NOAA to approve rescue efforts. When a flight that night could not be coordinated, the observers mobilized help from fellow rescue members and were able to give it medical treatments overnight. Transportation to Anchorage was arranged the following day thanks to Alaska Airlines cargo staff in Wrangell. The seal arrived safely and was transported to the ASLC.   In addition to low weight, dehydration, and malnourishment, additional complications required quick action from veterinary staff. For the Naknek pup, a dangerously high body temperature was the most immediate concern. Meanwhile, the Wrangell pup arrived with persistent tremors due to a lack of nourishment. The team is currently providing initial stabilizing treatments to both patients and keeping a close watch to ensure the best possible chance of survival. Updates will be shared on the ASLC’s Facebook and Instagram pages as they become available.   The ASLC Wildlife Response Program can only succeed with help from corporate sponsors and individual donors. The Center acknowledges ongoing support from ConocoPhillips Alaska, Marathon Petroleum Corporation, PetZoo, Partners 4 Wildlife, Matson, GCI, and a number of individual donors, funds, and foundations such as the Stanley J Williams Fund and the Theresa Bannister Legacy Fund. Those interested in contributing to the care of these patients can visit the ASLC’s website: 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 1-888-774-SEAL(7325).     

This event is FREE and open to the public. Join State Veterinarian Dr. Bob Gerlach and Assistant State Veterinarian Dr. Sarah Coburn for a presentation on avian influenza, and biosecurity measures backyard flock owners can take to prevent the introduction of avian influenza and other more common poultry diseases. Webinar information if you can't join us on site. Sorry, we had technical difficulties, we should be able to post the entire video soon. Thank you. Please click the link below to join the webinar: https://us02web.zoom.us/j/83263840635?pwd=eXFwYmlBeEF4WDhFakVOQ1ZqRE5LUT09 Passcode: 137021

There's something fishy going on at the ASLC! Members of our education and aquarium teams will share an up-close look at some of the fish and invertebrates living here at the Center. Learn about the ASLC from the comfort of your own home - Virtually       For more info and to register: http://www.alaskasealife.org/virtualvisits Tuesday, December 1 - 3:00pm Episode 2: The Awesome Octopus Wednesday, December 2 - 11:00am Episode 2: The Awesome Octopus Tuesday, December 29 - 3:00pm Episode 3: Who is lurking in our Kelp Forest? Wednesday, December 30 - 11:00am Episode 3: Who is lurking in our Kelp Forest? Tuesday, January 26 - 3:00pm Episode 4: All Hail King Crabs! Wednesday, January 27 - 11:00am Episode 4: All Hail King Crabs! Tuesday, February 23 - 3:00pm Episode 5: Incredible Invertebrates! Wednesday, February 24 - 11:00am Episode 5: Incredible Invertebrates!

Make your way around Seward and visit local businesses hosting featured artists during the Seward First Friday Art Walk! Visit the ASLC lobby from 6 - 8 PM on July 1, 2022 to see this month's TWO featured artists: Dreaming Bear Studio & Rabbit Creek Studio Dreaming Bear Studios will have items displayed in the ASLC Lobby for the month of July. See more of the artist's work on their websites -   Rabbit Creek Studio: https://rabbit-creek-studio.square.site/ https://www.facebook.com/kimnielsenak/ Dreaming Bear Studio: https://www.dreamingbearstudio.com/   Seward First Friday Art Walks are hosted by the Seward Chamber of Commerce and Seward Art Council.

Join us for a special community watch party at the Alaska SeaLife Center as we livestream "An Evening with Bill Nye live from Anchorage's Alaska Center for the Performing Arts – part of the University of Alaska Anchorage’s CAS Community Lecture Series. This is a unique opportunity to gather with fellow community members and science enthusiasts for an evening of thought-provoking conversation! Those attending the LiveStream event will have the chance to ask Bill Nye questions via a custom QR code. The stream will take place in the Bear Mountain Conference Room and be displayed on a large screen for group viewing. Seating is limited, and registration is recommended. RSVP here: https://24092.blackbaudhosting.com/24092/tickets?tab=2... The Alaska SeaLife Center’s doors will open at 6:20 pm, August 21, 2025, for registered guests. All tickets not claimed by 6:35 pm will be released for general admission. The program will start at 6:45 pm. This event is cohosted by the Alaska SeaLife Center, Seward Education Advocates, Seward Prevention Council, Seward Arts Council, and Chugach Regional Resource Commission, in partnership with the Seward Community Library and Museum.  

  Enjoy delicious soup served by Seward students in handcrafted ceramic bowls glazed by students and local artists.Take home a one-of-a-kind bowl and help send every 5th grader to KMTA Outdoor School Sleepover. A Zero-Waste Event honoring sustainability and our local marine habitats (Recommended donation for purchase of bowl with soup - $25 Recommended donation of soup with your own container - $5-15).   Join us for a special community watch party at the Alaska SeaLife Center as we livestream Cruisin’ Deep Time with Ray Troll & Kirk Johnson: The Travels of a Scientist and an Artist in search of Paleo America from Anchorage's Alaska Center for the Performing Arts – part of the University of Alaska Anchorage’s CAS Community Lecture Series. The stream will take place in the Bear Mountain Conference Room and will be displayed on a large screen for group viewing.  *Seating is limited for the Livestream portion of this event. Click here to register and secure your spot.    

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()         Individual scientists usually specialize in one particular area. They get very good at knowing a lot about a few things. This is a natural and very normal thing to do, especially when the amount of detail a researcher has to consider in their study is huge! There is no way for any one person to know the ins-and-outs of each and every project. One of the most important lessons we can learn from a disaster the size of the Exxon Valdez oil spill is the importance of "thinking big" with science -- really big! We need to ask big questions, such as: “How is this one particular thing connected to that?” or “What influence does something that seems so different and very far away have on my local work?” or “How is this one thing connected to everything?” Scientists might not have the luxury of working on a whole bunch of different projects at once but, through cooperation in large projects like Gulf Watch, they can see the links, or connections, between what they have been focusing on and what others have been doing. In science, we call this "systems thinking." Systems thinking looks at the web of relationships where individual pieces respond both in their own individual ways 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 things around them. Gulf Watch Alaska scientists combine data from all of their projects to help them better answer their own specific research questions. This gives each of them a better understanding of complicated ecosystem connections. You can think of each project like different pieces to a jigsaw puzzle. As more and more pieces are combined, a clearer and more complete picture emerges. Click the picture below to solve the jigsaw puzzle! Systems thinking allows the modern scientist to step outside of their lab. They connect with fellow researchers and see the importance of their work on a much larger scale. It requires teamwork and communication as they build a network with different specialties, interests, and research subjects. Watch the video below and listen to the Gulf Watch team as they talk about working together and putting the pieces of this complicated puzzle into place. VIDEO: Monitoring Connections Sonia Batten, Heather Coletti, and Dan Esler discuss connections between the four individual monitoring components of Gulf Watch Alaska. (1:55) Video Transcript (Sonia Batten) The Gulf of Alaska is a really complicated system. You’ve got places like Cook Inlet, Prince William Sound, which are these kind of inlets, and they’ve got local things happening there which are really important. And there are people studying the plankton and the ocean in those places, and they do really good detailed local studies, but we’re looking at a bigger area. We go from way off shore across the shelf, and it kind of smoothes out the little small-scale local effects and we’re looking at bigger climate effects and things that affect the whole region. So my data provides a link to what the local studies are doing and gives a broader context. (Heather Coletti) I think our work will really inform and strengthen our understanding of the connections between these systems. They talk about some of the zooplankton in the oceans out in the middle of the Gulf. How does that affect our coast and where we all recreate and live? And I guess I’d say the same thing for some of the environmental drivers, these big oceanographic systems that move through and the changes in the climate. How does that affect where we spend our time and where our resources are? (Dan Esler) I think a really important contribution of the work is to be able to take that long-term view of how things operate in marine ecosystems and how contaminant events are, what the timeline is for recovery from those sorts of things. And that fits in perfectly with the philosophy of Gulf Watch generally, taking this long-term, broad-scale view to understand these bigger patterns in marine ecosystems. I think that’s a really an important contribution for what we’re trying to do. You too can help with long-term ecosystem monitoring right in your own ecosystem -- through Citizen Science! Citizen science is the collection and analysis of data through partnerships between the general public and professional scientists. This collaborative way of doing science allows anyone with an interest in the natural world to engage in the scientific process. Many citizen scientist projects benefit from people gathering local monitoring data and contributing to a larger database. The data provided by participating citizen scientists helps professional researchers build a more complete understanding of ecosystems that they only visit once or twice a year. Recently, the scientific journal "Frontiers in Ecology and the Environment" published an entire issue focused on citizen science! Click the link on the right to access the journal. Explore some of the links below to find a citizen science opportunity to join! • Citizen Scientists • The Cornell Lab of Ornithology Citizen Science Central Projects • National Science Foundation • SciStarter • Scientific American Citizen Science Project List • Zooniverse • Journey North       Who is watching the Gulf?      

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()         With their hypotheses developed and their study subjects chosen, Dr. Mellish and the team began the detailed process of planning their fieldwork. The team's field season in Antarctica needed to coincide with the seal's reproductive season, which runs from late October to December. It would be important to arrive by early October to maximize their time before the late spring ice melt made it unsafe to work on the sea ice. The team chose research sites on Erebus Bay, a pupping and breeding area just a short snowmobile ride from the U.S. base at McMurdo Station. From the Erebus Bay location, they'd select forty healthy seals to participate in the study. It was decided that only healthy animals should be studied and that, of the adults studied, all should be females. This would help prevent outside variables from complicating the data. Navigate through the pictures below to learn about the tools the researchers used to select healthy animals for their project: The team was able to work directly with each seal to complete its initial health assessment. However, to collect research data from the healthy animals, the researchers would need to monitor the seals as they went about their daily lives. Since a lot of a seal's time is spent beneath the sea ice - where it's difficult for researchers to observe them directly - this data would have to be collected remotely. To do this, the team outfitted each seal with specially engineered instruments, called data loggers, that would record and store the team's data. VIDEO: STUDYING SEALS USING DATA LOGGERS Dr. Markus Horning explains how the research team used data loggers to collect data for the Weddell seal project. (2:19) Video Transcript My name is Markus Horning, and I am an Associate Professor of Wildlife with Oregon State University’s Marine Mammal Institute. I’ve worked with Weddell seals in the Antarctic ever since my first trip to the Antarctic in 1981. My expertise that I bring to the table is related to my ability to bridge engineering and biology. I’m a biologist by training, I have a Ph.D. in biology, but I’ve always dabbled in electronics. We really can accomplish much more in our attempts to study and understand these animals if we use what we call “telemetry devices.” Basically, we use fancy electronics that can go with the animal where they go and where we can’t. Often times where I come in is figuring out, ‘Okay, this is the question, this is the data we need in order to be able to answer this question we have about the biology of this animal.’ Then I ask, ‘How can we get that data?’ and I find specialty sensors that give us exactly that data that we need. In this project we actually have several separate devices that we glue to the back of an animal. These are multi-channel devices - they have many different sensors. The information that we’re really most interested in is the information we get from the heat flux sensors. We glue these onto the surface of the skin of the seal and they measure exactly how much heat the animal is transferring to the cold water or cold air. To be able to understand this data and the patterns we see in terms of heat dissipation, we also need to record the behavior of the animal. That’s why we’re recording dive depth, swim speed, because that really determines the physiological state of an animal. If everything works well we find our animal after about five days, I’d say, and everything is still attached. We immobilize the animal a second time and we just peel everything off, or we shave a little bit of fur off. We get everything back home and we download the data. We want to recover the equipment so we can use it again on another animal, but also because the devices that we use actually record the most important information in memory. So, unless we recover the device we don’t have access to the data that we really want.       WHO IS STUDYING SEALS?   HYPOTHESIS (n) - a proposed explanation to a question that must be tested   PUPPING SEASON (n) - the time during the year when seal pups are born   OUTSIDE VARIABLE (n) - something not being tested in a study that could impact the data   DATA (n) - values for something measured   MONITOR (v) - to keep surveillance over something   REMOTELY (adv) - from a distance, without direct contact   DATA LOGGER (n) - a device that measures and stores data on the activity or condition of an animal.    

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() Who is watching walrus? IMPACT (v) - to affect or change something else FORAGE (v) - to search for and collect food MIGRATE (of animal) (v)- to move seasonally from one area to another           Background Scientists know that when summer sea ice in the Arctic melts away from their shallow feeding grounds, Pacific walrus will haul out on land to stay near their food. The Icy Cape stampede showed scientists that land haulouts in the Chukchi Sea can be dangerous for young walrus. Scientists wonder how walrus populations will be impacted when the walrus have to use land haul outs more and more often. To understand how walrus populations might be affected by changes in their Arctic habitat, scientists first had to understand "normal" Pacific walrus behavior. Take a look at the videos and fact sheet below to explore what researchers already know about the mysterious Pacific walrus. VIDEO: The Pacific Walrus Understanding walruses' relationship with sea ice is important to understanding their behavior. (1 minute) Video Transcript Pacific walrus feed in relatively shallow water, hunting for small invertebrates on the ocean floor. In the Bering and Chukchi Seas, the continental shelf provides a vast area of shallow, rich feeding grounds for the walrus. Walrus haul out on sea ice or on land to rest between feeding trips. Although they are good swimmers, they don’t typically swim long distances, so they prefer to rest near where they eat. In the winter, arctic sea ice extends south into the Bering Sea, where large herds of male and female walrus spend the winter together. Then in the springtime, females and calves follow the melting sea ice north into the Chukchi Sea, while adult males separate from the rest of the population and migrate south to spend the summer in Bristol Bay. The male walruses in Bristol Bay typically haul out on land and feed near shore. In the Chukchi Sea, the females and calves spend their summer floating on the sea ice, drifting over the shallow continental shelf. In recent years, summer sea ice in the Arctic has melted beyond the edge of the continental shelf, leaving the females and calves without their traditional feeding and resting platforms.   WALRUS FACT SHEET (click to download .pdf) Female walrus and their calves use sea ice all year. They migrate to the Chukchi sea in summer because there is so much food available for them there. Watch the video below to hear Dr. Lori Polasek talk more about how females and calves may be affected if they can't haul out on sea ice and must move to areas on land, instead. VIDEO: Females and Calves Dr. Lori Polasek describes how females and calves might be impacted by hauling out on land instead of sea ice. (1.5 minutes) Video Transcript What are some of the possible impacts of females and calves hauling out on land instead of sea ice? There are several important facts about walrus that we had to understand before starting this project, and one of those is that land haulouts are primarily used by male walruses, of all ages, and ice is primarily used by females and calves. And the importance of ice, you can think of it as a mom and calf are floating around on a piece of ice and that keeps them moving across the water so it allows them to utilize different resources so they don’t impact a resource and completely deplenish [deplete] it. Also, by allowing them to float around, they’re not congregated together, where they’re more susceptible to predators, where then you allow the whole herd’s offspring to potentially be wiped out by a predator. It also takes your young, your offspring which are more susceptible to disease, and separates them from the population so that disease can’t spread as fast. So these new emerging haulouts with moms & calves packed together, then wipe out all of those protections of those calves by exposing them to disease as a group, by allowing them higher exposure to predators, and then by also having them together totally deplete resources in a localized area. Arctic sea ice extent is impacted by changes in seasonal and global climate. Walrus respond to changes in sea ice by migrating and adapting their behavior. Understanding how sea ice forms and why it melts can help scientists understand more specifically how walrus will be influenced. Check out the sea ice fact sheet below! SEA ICE FACT SHEET (click to download .pdf) This important background knowledge helped scientists from the Alaska SeaLife Center develop a research project studying walrus.      

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() Who is watching walrus? DEPLOY (v)- to set something up so that it is ready for action BLIND SPOT (n) - an area that cannot be seen because something is blocking your view DATA SET (n)- all of the information collected UPGRADE (v) - to improve the quality of something; to buy the next version of a product             Results   Cameras at the five sites captured data during the season of May-September 2011. For each of the sites, the timeline below shows (1) when the cameras were deployed, (2) when the first walrus was spotted at that location, (3) the date when the largest number of animals were counted on that site, and (4) the date of the last image taken by the cameras. The team collected census data by examining the photos at the end of the season and counting the walruses. Below are images captured from the haulout site on Cape Seniavin on August 4th, 2011. On this day, over 1,400 male walruses were counted hauled out in this single spot. Click on the thumbnail images below to see the larger versions: Researchers decided to add more cameras at this site in 2012 to avoid blind spots like the one created by the rock in the pictures above. On Hagemeister Island, cameras recorded the disturbance event seen below. Click on the thumbnail images below to see the larger versions: In the fourth photo you can see that these walrus quickly returned to the beach. The scientists couldn't see what caused the disturbance, but they think it was likely a bear or other land-based predator nearby. With clear images like the ones above, Dr. Polasek and her team agreed that camera monitoring at these remote sites is both possible and useful for understanding Pacific walrus behavior. Unfortunately, the type of camera the Alaska SeaLife Center team installed for the 2011 season tended to fail often. Many of the cameras stopped taking pictures before the last walrus left the site at the end of the season. So the 2011 data set isn't as complete as the team had hoped. They knew camera monitoring worked, but they needed to find a better type of camera. In 2011, the scientists were able to begin establishing their baseline. In 2012, they purchased new, more reliable cameras and added more haulout sites to their study. They're continuing to work on their baseline using male walrus in Bristol Bay, but with the help of the residents of Point Lay they've also set up their first cameras along the Chukchi Sea. Check the updates section for images captured in the second season!        

  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 research vessel is a busy place! On a ship the size of the U.S. Coast Guard Cutter Healy, several groups of scientists will be working on the boat at once, each with their own research project. Watch the video below to learn about what daily life was like as the research team collected samples for their sea ice project. VIDEO: A DAY IN THE LIFE Martin Schuster describes daily life working as a research technician on the sea ice project. (2:45) Video Transcript "My name is Martin. I've been a grad students at UAF (University of Alaska Fairbanks) in the Masters program in Marine Biology for about four years now. "In the sea ice project working with Rolf my role was as technician, so I was basically organizing our gear before we would go out, and making sure all our sleds were loaded up with all the various paraphernalia that you need to go out and dirll holes in the sea ice and sample water. Our project was to get off the ice breaker on either a little ladder that they would lower down to the ice, or with a helicopter, which was the preferred way to do it. My job was basically to pack all the gear before we got out. To double, triple check and make sure that we had everything, because once you're twenty miles away from the ice breaker, if you forget something it's not a good thing. And then once we got onto the ice we would unpack everything. We would take some ice cores and then we would section the ice cores so that we could look at each individual strata in the sea ice later on and determine what kind of biota is living inside there. We'd also cut a larger hole in the sea ice so we could lower a device called a ctd. This thing would basically give us various water temperature and clorofil readings as it goes down into the water and then we'd pull it back up by hand. Most of the work was definitely getting things together and then cleaning up afterword. You have a pretty limited time on the ice and you want to get as much work done as you can. And then as soon as you're done it's time to go back to the ship because of polar bears." Text on screen "Wait a second.... POLAR BEARS" Martin: "It was a worry, I mean whenever we were on the ice directly from the ship we had what's called a bear guard. It was a Coast Guard person, fully dressed up in their survival suit with a rifle. And they would stand and watch us the whole time, just to make sure there were no bears around. So it was expected that we would see some bears, but sadly we did not. "We were just out during the day which was really neat because we got to see every sunrise and sunset, which on the sea ice is just spectacular. It was really, really cool. Just go, go go all the time. Whenever there's a chance to work, we were working. You get into sort of a motion after the first couple days, and time just starts to fly by. You really lose all sense of what day it is in the week, because it doesn't really matter. You have your work cut out for you that day, you know what you're going to do. You set all your stuff out, and you just do it. One day just begins to blend into the next. And it's actually better to be busy on a ship like that than it is to be idle, because you can get bored pretty easily. At the end of the busy day there's still work to be done. Back on the ship, the scientists have to download data to their computers and store samples for later analysis. Finally, they repack the gear for another day on the ice. On the USCGC Healy, every day is a work day. The team will continue this routine each day for several weeks! The team is excited to begin piecing together the food web, but analysis will have to wait until later, back in the lab in Fairbanks.       WHO IS STUDYING SEA ICE?   BIOTA (n)- the animal or plant life in an area   CHLOROPHYLL (n)- a green pigment found in plants and algae    

  Spring/Summer 2026 Availability March 5 - September 30: 2:30 pm Daily   Duration: Approximately 30-minute tour Maximum of 4 people per tour - Minimum age 10* Go behind the scenes in our aviary to meet our puffins and other resident bird species and participate in a feeding session with these remarkable birds. This tour includes walking and kneeling on uneven surfaces. ***Due to cold and windy conditions, our Puffin Encounter will be slightly modified. Guests will still go behind the scenes and get an up-close look at one of our resident birds.     One Group Per Tour Group Size of 1-2 Guests: $289.95 Group Size of 3 Guests: $339.95 Group Size of 4 Guests: $389.95 Members get an additional 20% discount, buy your membership today and use the benefits immediately. (does not include admission)   Tickets only valid for date selected. Online tickets must be purchased at least one day in advance.    *Guests aged 10-16 must be accompanied by a paying adult

  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()         At the northern fringe of the Pacific Ocean, along the United States’ most remote boundary, lies the Bering Sea.  Covering an area more than three times the size of Texas (nearly 900,000 sq. mi.), and supporting some of the most valuable fisheries in the world, the Bering Sea’s remote waters have attracted explorers for thousands of years.  This cold maritime environment is home to a huge diversity of life. From migrating whales to clams, seabirds, seals and fish, organisms in the Bering Sea have evolved to make up one of the world’s most unique ecosystems.  The Bering Sea’s high northern latitude means nearly continuous daylight throughout the summer months.  In contrast, the winters are long and dark. Winter conditions are so harsh that the surface of the ocean, over much of the Bering Sea, freezes.  Organisms living in this region have had to adapt to these challenging, extreme, and changeable polar conditions. VIDEO: INTRODUCTION TO THE BERING SEA Discover why the Bering Sea is important to people in Alaska and around the world (1:50) Video Transcript Despite its remoteness, the coastline of the Bering Sea is home to many Alaskans. There are no roads connecting these remote communities to Alaska’s larger cities, so people living along the coast rely on the ocean to sustain their way of life. Subsistence hunting and fishing of marine animals has traditionally been an important source of food, material for clothing, fuel and culture for many people living in these villages. Successful harvest of these marine resources requires an understanding of the Bering Sea ecosystem including the ability to predict how weather and species distribution vary throughout the year. However, it isn’t only people who live beside the Bering Sea who are affected by it. Even if you’ve never heard of the Bering Sea, chances are it’s had an impact on your life. If you’ve ever eaten fish sticks or tried ‘artificial’ crab meat, you were probably eating Pollock. Pollock is a species of cod that live in the Bering Sea. These fish make up the largest single species fishery in the United States. On average two billion pounds of Pollock are harvested in Alaska every year (that’s equal to about 100 times the weight of the Eiffel Tower in Paris). The Pollock fishery in Alaska is worth about three hundred million dollars a year, making it an important part of our state and national economy. So whether you live beside Alaska’s coast, or thousands of miles from it, the Bering Sea is worth caring about. It’s home to unique animals and dynamic people. It provides American jobs and is a source of food, insight and inspiration. Recently, people living in coastal areas, companies exploring and building along the coast, and researchers with an eye on the Bering Sea have observed significant and measureable changes. Sea ice has been arriving later in the winter.  Animals are migrating farther north and the distribution of species is changing.  Some animal populations are growing quickly, while others seem to be in decline. These changes directly impact everyone who relies on the Bering Sea.  They make it harder for local communities to support their food and infrastructure needs, and harder for companies to plan on the expected ice or weather conditions two years down the road.   VIDEO: ARCTIC MELT IN ACTION This NOAA visualization illustrates how sea ice cover in the Arctic changes annually across the seasons. Compare 2012's record melt season to the historic (1979-2000) median. (0:34) Changes in the Bering Sea won’t just affect people and their activities; they may also impact the balance of the marine ecosystem. This has scientists concerned. They realize that before we can make predictions about what these changes may mean for this important marine ecosystem, we need to learn more about the area as it is now. Dr. Rolf Gradinger and his colleagues at the University of Alaska Fairbanks are one group of researchers working to better understand the Bering Sea. Observations they've made have sparked scientific questions and inspired futher research about the Bering Sea food web.  VIDEO: INTRODUCTION TO THE RESEARCH PROJECT Dr. Rolf Gradinger explains why the team is interested in studying the Bering Sea ecosystem. (1:30) Video Transcript "My name is Rolf Gradinger. I'm a faculty member at the School of Fisheries and Oceans Sciences (at UAF). I have a research interest in Arctic Ecology and I've been doing this now for quite a while. "Since 2008 I worked in the Bering Sea in spring. The Bering Sea is very unique, it's a unique ocean because it's part of the Arctic system. The Bering Ecosystem is very rich in a lot of marine resources, there are lots of fish living in the Bering Sea like Pollock, and most of the US fisheries are actually happening in the Bering Sea. In addition to that you will find lots of marine mammals and seabirds in the Bering Sea. And a lot of people living in that region, like native populations on Saint Lawrence Island or on the Alaskan coastline rely on marine resources. "Now the big question is, which you might have heard, that ice conditions in the Arctic are changing. Summer sea ice is disappearing, ice melts happen much sooner, so there is a tremendous change in the Arctic. "The question is, what does it all mean to the ecosystem if ice conditions change? For really addressing that question you need to know what lives with the ice. You know about the Polar bears and the seals living on the ice, but there's actually little critters that live within the ice, and they grow within the ice, and they only exist within the ice. Our part was to learn as much as possible about the spring biology, in association with ice in the Bering Sea." Dr. Rolf Gradinger and his team know that among the many species of plant and animal life living with the sea ice are marine plants called algae. The team wants to better understand the role that this sea ice algae plays in the entire Bering Sea food web during the spring. Dr. Gradinger knows that to accurately hypothesize the importance of this algae bloom, the researchers will need to study the science of sea ice as well as discover what types of living things make their homes throughout the sea ice ecosystem.        WHO IS STUDYING SEA ICE?   FISHERY (n)- an area where fish are caught   MIGRATE (v)- to move seasonally from one area to another   ORGANISM (n)- an individual life form   ECOSYSTEM (n)- a community of interacting living organisms and their physical environment   LATITUDE (n)- a measure of the distance north or south of the equator, expressed in degrees   SUBSISTENCE (n)- a style of living where a person relies on the local environment for survival   DISTRIBUTION (n)- the way something is spread over an area   ALGAE (n)- any aquatic plant or plant-like organism (seaweed)    

  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()         Many factors needed to be considered as Dr. Gradinger and his team planned their research. In addition to having the necessary sampling equipment, it was important that they time the research trips so they would be collecting samples during the spring sea ice melt season.  If they traveled too early, their measurements might underestimate the importance of ice algae. If they traveled too late, the ice would all have melted and there would be no ice algae for them to measure.  The team chose research sites in the eastern Bering Sea because it is a very productive region of water. Picking the research area was only the beginning. Next, they had to select the right tools to help them answer their research questions. Navigate through the images below to learn how each tool helped the team answer their research questions: With many samples to collect at every study site, a researcher's job is never dull. Can you imagine what daily life would be like on a 400-foot long ship floating in the middle of the Bering Sea?       WHO IS STUDYING SEA ICE?   MELT SEASON (n)- the time of the year when melting occurs   PRODUCTIVE (adj)- being rich in resources; in this case, with valuable resources like fish   PROPEL (v)- to push or move in a particular direction   WATER COLUMN (n)- the area of water between the surface and the sea floor   ALGAL GROWTH (n)- the process of algae growing   ROV (n)- a remotely-operated vehicle  

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.    

Giving Circle Levels and Benefits The Alaska SeaLife Center relies on a combination of grants, donations, and admission sales to operate at a world-class level. Donors like you support Alaska's marine wildlife by helping to fund research, education, and wildlife response programs. We invite you to join a Giving Circle at a level best suited to you. The SeaLife Circle begins at the $300 donation level and the Steller Circle begins at the $1,000 donation level. SeaLife Circle Level SeaLife Associate SeaLife Advocate Cost $300-$499 $500-$999 Family membership including 2 named adults and named dependent children/grandchildren ages 17 and under* Discounts for guests, tours, and gift shop Recognition on the Alaska SeaLife Center website and on the donor board at the Center Invitation to an annual virtual CEO update   Guest Passes 4 8 *Adults and dependent children/grandchildren must be in the same household. Steller Circle Level Steller Partner Steller Guardian Steller Patron Steller Champion Cost $1,000-$2,499 $2,500-$4,999 $5,000-$9,999 $10,000+ Family membership including 2 named adults and named dependent children/grandchildren ages 17 and under* Discounts for guests, tours, café, and gift shop Recognition on the Alaska SeaLife Center website and on the donor board at the Center Invitation to an annual virtual CEO update Guest Passes 8 8 8 8 VIP Tour  For 4 For 4 For 8 For 8 Invitation to quarterly VIP virtual programs   Breakfast or lunch with the CEO     Keeper for a Day, a 5-hour program for one or two people with minimum age of 16       *Adults and dependent children/grandchildren must be in the same household. Please contact the Development Office at development@alaskasealife.org or call Laura Swihart, Development Associate, 907-224-6337, if you have any questions about joining a Giving Circle.

  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() Meet Dr. Kathy Kuletz Wildlife Biologist, U.S. Fish and Wildlife Service Kathy's role in Gulf Watch Alaska: Pelagic Ecosystems Co-Principal Investigator, Prince William Sound Marine Bird Population Trends Important skills for her position: "Biometric and GIS skills are of course important for working in science, but writing and communication skills are more important for me now, at this stage in my career. And of course, getting outdoors when possible, to recharge interest and enthusiasm, even get new ideas." Challenges in her work: "Obtaining the support needed for a scientific project, especially something long-term, takes an enormous amount of time and effort - and is usually not why one goes into science. But it has to be done... these aren't the fun aspects of science, but they also help you to refine your goals, objectives, and approach." Kathy's advice to young people interested in science: "Get some field experience, and even work on several types of studies to see what really stokes your interest in learning more. Often, biologists start out as volunteers (I did) and move to seasonal field work, or help with data and reports. When you're on a project, do some background searching and reading on the subject or your specific project (so easy to do these days), and find out what questions the project leader is focused on. If you do a good job, work well in difficult conditions, and stay in contact, chances are you'll be called back." Dr. Kathy Kuletz describes her career as a seabird biologist. (3:14) Video Transcript I’ve always been interested in the working with wildlife. I grew up in the desert, so the ocean was exotic to me. Anything that had to do with the ocean was very exotic, and that’s probably what attracted me to that aspect. I wanted to see Alaska, so I came up for a summer job like most people here. I worked in fisheries to begin with because that’s where a lot of the jobs were – there’s not a lot of funding to study birds. I was doing fisheries work, but then I wound up getting a summer job on Naked Island in Prince William Sound, and that was my first job with seabirds. My one year there turned into four, which turned into my Master’s degree studying pigeon guillemots there. Of course that was before the oil spill – I started back there in 1978. After the oil spill, it turned out that was one of the few places where we had some baseline data on seabirds – how they raised their chicks, what they fed on, and how many birds there actually were in these colonies. I went back after the oil spill, again as a seasonal employee of Fish & Wildlife Service, and eventually it became a term appointment. I stayed on in prince William Sound studying marbled murrelets. I became interested in what was going on at sea. Back in the 70s and 80s there was a large ecosystem study going on because they were looking at oil lease sales in the Bering Sea and the Gulf. They had what they called the OCSEAP program – the Outer Continental Shelf Environmental Assessment program. Then there was a huge gap where not much was done out at sea, and of course seabirds spend most of their lives out at sea, but mostly people study what goes on at a colony. I was interested in that other aspect of their lives and what happened the other three quarters of their lives out at sea. For the most part, this was before we had little tiny satellite tags and GPS dataloggers, but we didn’t know what they really did. We didn’t have a good idea of where birds went, and a large part of what we found out was by counting birds at sea – going out on big ships, research vessels that were doing fisheries work or oceanographic work, and doing surveys in conjunction with those. That’s what we’ve continued to do, of course we have more technology now and we can log location of every sighting very accurately and tie that data into what the oceanographers found on the same cruise, or the plankton people, the fish people, the marine mammal folks. So we’re trying to identify the hot spots, trying to found out where birds go in the non-breeding season as well as during the breeding season offshore. That’s what’s attracted me – the idea of being able to put together all this information and understand the big mystery of what seabirds do out at sea, that’s what draws me into it.   Who is watching the Blob?    

  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() 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 discover the mechanisms behind a mystery unfolding in the Gulf of Alaska. Learn about the work of a collaborative team of scientists from many different ocean science disciplines, and follow along with the narrator as she explores the scientists’ process of initially observing unusual phenomena in the Gulf of Alaska and seek to discover the causes and connections. You can use this VFT in conjunction with the “Gulf Watch Alaska: Long-term monitoring” VFT, or as a stand-alone piece. 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 mystery of the seabird die-off that occurred in the Gulf of Alaska, during the winter of 2015 – 2016. They will explore various aspects of the investigation and how, collectively, the scientists were able to begin uncovering the mechanisms behind the extreme die-off event.   LEARNING OBJECTIVES: After completing this virtual field trip, students will be able to: • Understand the process of scientific thinking and the use of the Scientific Method as a tool to develop questions and search for answers. • Understand the collaborative nature of science and how researchers from various disciplines working together can provide a ‘big picture’ view of a dynamic marine ecosystem. • Explain how an ecosystem is composed of many different components, including physical and chemical processes that drive the ecosystem and determine the conditions for survival of marine life. • Use evidence to make a claim about the cause or causes of a change in a population. 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, investigating the marine ecosystems since the 1989 oil spill. This program focusses on a recent mystery that has unfolded in the Gulf of Alaska, beginning with the observation of an extreme seabird die-off event. Organized into three main pages, this VFT follows researchers along on an investigation to uncover what caused this mortality event. 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 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. 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 all the classes and programs we offer, including our inquiry-based 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: Observation Observation Poster Template Lesson 2: Investigation Lesson 3: Discovery          

  Spring/Summer 2026 Availability March 5 - August 31: 3:00 pm Daily   Duration: Approximately 30-minute tour Maximum of 6 people per tour - Open to all ages All brain, no bones! Immerse yourself in a world of suckers and beaks. Go behind the scenes and join a member of our Aquarium Team to participate in an octopus feeding and learn more about these fascinating creatures. One Group Per Tour Group Size of 1-2 Guests: $289.95 Group Size of 3 Guests: $339.95 Group Size of 4 Guests: $389.95 Group Size of 5 Guests: $439.95 Group Size of 6 Guests: $489.95 Members get a 20% discount, buy your membership today and use the benefits immediately.  (does not include admission) *Guests under 16 must be accompanied by a paying adult Tickets only valid for date selected. Online tickets must be purchased at least one day in advance.    

Local Information Seward is located at Mile 0 of the Seward Highway, 125 miles south of Anchorage. Located at the head of Resurrection Bay, Seward is the gateway to Kenai Fjords National Park, with Chugach National Forest and Caines Head State Recreation Area nearby. The city offers many recreational activities, including day wildlife viewing cruises, kayaking, fishing, and hiking.    Seward is accessible year-round by road or by train and cruise ship during the summer season. Local Links Seward Chamber of Commerce   City of Seward    City Campgrounds & Parks    Visit Anchorage

Seward, Alaska (April 7, 2020) – Nat Geo WILD’s new series, “Alaska Animal Rescue,” is airing April 11 at 5 p.m. Alaska time. This new show highlights three renowned animal conservation centers, the Alaska SeaLife Center, the Alaska Wildlife Conservation Center, and the Alaska Raptor Center.   The series will give viewers a unique behind the scenes look at wildlife response in action as animal care teams experience both the rewards and challenges of rescuing wildlife in various regions of Alaska. From Nat Geo WILD: “Whether caring for a stranded sea lion, an orphaned lynx or an injured eagle, these are the people on the front lines, willing to do whatever it takes to rescue and preserve Alaska’s wildlife.”   The facilities featured in “Alaska Animal Rescue” anticipate this series will help inspire people to care about wildlife and conservation. “We hope viewers of the show see how valuable all three of our facilities are not just to wildlife in the state of Alaska, but in supporting conservation work on a global scale,” said Tara Riemer, Alaska SeaLife Center President and CEO.    “We are very excited for the premiere of Alaska Animal Rescue. We hope viewers will become stewards for Alaska’s wildlife and learn how everyone around the world can help participate in wildlife conservation efforts,”  said Di Whitney, Executive Director, Alaska Wildlife Conservation Center.   Jennifer Cross, Executive Director, Alaska Raptor Center states, “All of us at the Alaska Raptor Center are thrilled about the show’s premiere this Saturday! Although filming was challenging at times, we are thankful for this opportunity to showcase the important work non-profits do on behalf of Alaska’s wild animals.”     The show will air on Nat Geo WILD channel April 11, at 9/8c (5 p.m. Alaska time)  Learn more about the facilities highlighted in the series here: https://alaskaanimalrescue.org/    About the Alaska SeaLife Center (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.   About the Alaska Wildlife Conservation Center (AWCC) Founded in 1993, the Alaska Wildlife Conservation is a sanctuary dedicated to preserving Alaska’s wildlife through conservation, education, research, and quality animal care. AWCC takes in injured and orphaned animals and provides them with enclosures at a 200-acre facility in Portage, Alaska. Most of the animals that arrive at AWCC become permanent residents. To learn more, visit www.alaskawildlife.org.    About the Alaska Raptor Center (ARC) Established in 1980, the Alaska Raptor Center’s mission is to promote and enhance wild populations of raptors and other avian species through rehabilitation, education, and research. ARC provides medical treatment to about 200 injured birds each year, striving to rehabilitate and release its avian patients. Some birds who are too injured to survive in the wild find sanctuary at the facility in Sitka, Alaska, providing educational opportunities to visitors. To learn more, visit www.alaskaraptor.org.