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 Heather Coletti Marine Ecologist, National Park Service SW Alaska Inventory & Monitoring Network Heather's role in Gulf Watch Alaska: Nearshore Program Principal Investigator Important skills for her position: "Curiosity is a big one, I think.  And a willingness to work in uncomfortable conditions - and long hours." Challenges in her work: "Having just that one opportunity to collect the data, and what does that really mean in a whole year?"   Heather's advice to young people interested in science: "Volunteer. You know, school, of course, is important, but the sooner you can volunteer and get out in the field and start to get to know folks, the opportunities will present themselves.  We always have work, we always have questions, and if you are willing to get out there, opportunities will come."   Heather Coletti describes her favorite thing about working with sea otters and how she got interested in nearshore ecology. (0:54) Video Transcript My favorite daily duties… I would say one of my favorites is we do a lot of sea otter foraging work, data collection, so with high-powered telescopes we’re watching these animals eat because they bring everything up to the surface. It’s always a surprise, it’s challenging and really interesting. I’ve always been drawn to the ocean. Some circumstances just sort of present themselves professionally of who you meet, and it really does matter who your mentors are. And if you’re a good mentor I think whatever you’re interested in… and I had a great mentor, and his interest was in the nearshore, particularly in sea otters but just the ecology in general, and it stayed with me.     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()         Meet John Moran Research Fisheries Biologist, NOAA/NMFS Auke Bay Laboratories John's role in Gulf Watch Alaska: Pelagic Ecosystems Humpback Whale Program Co-Principal Investigator Important skills for his position: "You definitely need patience, you need to be very tolerant of weather, and just being able to endure things and not really give up." Challenges in his work: "Being on a small boat when it’s really rough, battling the weather, wind and rain, having your expensive camera getting salt spray on it... and then the whales just not cooperating." John's advice to young people interested in science: "I would take math and English. Those are two things that I didn’t really think I needed very much that are very important. Work hard, do things that people don’t want to do. You’re not going to go out and tag whales on your first day, but if you're entering data or doing some of the more tedious things, then you make yourself very useful. And it’s a good way to meet people, a good way to get your foot in the door."   John Moran describes some of the fun and frustrations of tracking humpback whales in the Gulf of Alaska. (0:50) Video Transcript When things change, like this last winter we thought we knew where all the whales were going to be in Port Gravina, and we got out there and they weren’t there. And we were just so sure of ourselves, we’ll just get out there and get a bunch of IDs, it’ll be nice & protected, and we were completely wrong. So when things jump out as being unusual that’s when it gets interesting. You think you have things figured out and you really don’t know what you’re talking about. I really like driving the boat for some reason, I don’t know why maybe it’s the control issue, but for doing photo Id or biopsies especially or tagging, and I do disentanglement work in Southeast and just being the one that maneuvers the boat, gets the boat close to the whales while somebody else maybe does the other things, you feel like you’re the one literally in the driver’s seat.   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()         Meet Sonia Batten Biological Oceanographer, Sir Alister Hardy Foundation for Ocean Science Sonia's role in Gulf Watch Alaska: Environmental Drivers Principal Investigator Important skills for her position: Basic science training, interest in small things, interest in seeing both "big pictures" and patterns Challenges in her work: "Anything to do with studying the ocean is challenging because you can’t sample enough of it to really understand what is going on. So trying to understand what’s going on across the horizontal region, down through the water column, and through time is really hard because they all change, all of the time." Sonia's advice to young people interested in science: "If you have a questioning mind and you like looking at the way the world works, then you are a scientist.  How you use that in a career could be anything from teaching, to talking with politicians to try and get policies that will help a community - there are so many different things. I would just say that it may not be the dry and dusty thing that you think it is. You can be a scientist and have a huge range of careers. If you are interested in things like that, keep your mind open for opportunities where you can use science." Sonia Batten discusses one of the coolest things about the ocean. (0:31) Video Transcript I think the coolest thing is that you can take a bucket of seawater, you can filter out the stuff and put it under a microscope and show people and they go, “Oh my god, I didn’t know I was swimming with that!” You can look at a crab larvae, a little tiny crab before it settles out under the microscope, and it’s got, some of them have spines that are three times the length of their body sticking out, and they look like alien things, and you have no idea that you’re swimming with that kind of thing, and yeah – I think that’s cool.   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() 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()           Nearshore and benthic (bottom-dwelling) organisms are good gauges of change in the environment. Many are sedentary, sensitive to change, and easy to access for study. Scientists are usually more able to discover the source of change in this kind of habitat. Once those sources are found, they can identify and compare changes that are natural from those that are man-made. Click the image below to discover the different zones of the nearshore ecosystem. The Nearshore Ecosystems team collects data in the tidal areas. Researchers are focused on learning about the variety and abundance of the species living at sites in Prince William Sound, the outer Kenai Peninsula, and Lower Cook Inlet. This data will help scientists find answers for questions like: • Is the nearshore environment changing significantly from year to year? • Have resources in this environment recovered from the 1989 oil spill? If not, are there reasons other than the oil spill? • Are changes in offshore conditions also causing changes in the nearshore habitats? This project focuses on organisms that are considered crucial to the nearshore ecosystem’s health. One such key species is the black oystercatcher. These shorebirds are good candidates for monitoring projects because they have a long lifespan. Over that lifetime, the oystercatcher lives in and depends upon intertidal habitats. This is where they mate, nest, and raise their young. Even though black oystercatchers aren’t benthic animals, they eat a diet of creatures that are. Their menu of mussels, limpets, and chitons are easily effected by changes in the environment. If oystercatchers aren’t healthy, it probably means that something significant has happened to the shellfish that they eat. Click on the image below to learn more about the black oystercatcher, a critical species of the Nearshore Benthic Systems in the Gulf of Alaska project. Click the audio icon to hear the call of the black oystercatcher. Scientists, like the National Park Service’s Heather Coletti, are trying to address the following questions: • Are the numbers of black oystercatcher nests changing from year to year? • Is the number of eggs or chicks in each nest changing? • Are chicks supplied with the same variety and amount of food each year? • Does this data change from one location to another? Heather and her team monitor the habitat of black oystercatchers using a variety of methods, including the use of shoreline transects to survey nest sites and sample prey remains at oystercatcher nesting sites. VIDEO: Monitoring Nearshore Systems Heather Coletti describes her work studying black oystercatchers for the nearshore systems component of Gulf Watch Alaska. (1:50) Video Transcript The nearshore is that interface between the terrestrial system – land – and the oceans. And there are several influences from the ocean that meet at the nearshore and then we have anthropogenic and natural influences from the terrestrial, and in some heavily populated areas that’s pollution and runoff, and how the nearshore really is affected by all those influences. And it’s essentially where the densest human populations live, along the coasts. Our program is essentially monitoring the nearshore food web. So we start out at the sea grasses and algae, which are the primary producers of that system. And then we look at invertebrates – benthic invertebrates – whether it’s mussels, clams, limpets… And then we have surveys for higher trophic level predators, like your sea ducks, sea otters, sea stars. We monitor oystercatchers, which are a pretty charismatic shorebird that is essentially confined to the nearshore and the intertidal. They feed exclusively in the intertidal on benthic invertebrates. So that’s your mussels, your limpets, that’s their two primary food sources, but they’ll eat some barnacles and some worms. So we have several aspects of their biology that we are monitoring. The goal of any monitoring program is to look at change over time and understand change over time, what’s driving it and if there’s any way to predict what those outcomes may be. That’s ultimately the goal and we are in our first few years of monitoring, and right now looking at what the natural variation in these systems is like. That hasn’t been fully documented yet.       Who is watching the Gulf?   Abundance (n): the quantity or amount of something   Benthic (adj): pertaining to the seafloor and the organisms that live there   Data (n): values for something measured   Density (n): the number of inhabitants per unit of area   Distribution (n): the way in which something is spread over an area   Intertidal (n): the benthic shore area between the extreme reaches of high and low tides   Nearshore (n): the marine zone that extends from the high tide line to depths of about 20 meters   Organism (n): an individual life form   Prey (n): an animal taken by predators as food   Riparian zone (n): the area of land next to a lake, river, stream, or wetland   Subtidal (n): the benthic area below low tide that is covered by water most of the time and exposed briefly during extreme low tides   Tide (n): the alternate rising and falling of the sea at a particular place, due to the gravitional attraction of the moon and sun   Transect (n): a path along which scientists count animal populations and plant distributions    

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    

          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()         Check back here for updates about the ongoing work from the team at Gulf Watch Alaska! This page is your source for news, announcements and data pertaining to each of the long term monitoring projects. GOOD NEWS! From the Lingering Oil team: • 25 years after EVOS, harlequin ducks and sea otters are no longer being exposed to lingering oil in Prince William Sound! Click the image below to see how other species have fared since 1989. Gulf of Alaska Data Portal Click the image below to visit the Gulf Watch Alaska webpage that allows you access to an interactive data page where you can browse data sets, access project descriptions, and project data onto a map allowing you to graphically explore individual or multiple layers of data! Text goes here!         Who is watching the Gulf?      

Here are some things you can do today to help continue our mission work: Membership is the best way to support the Alaska SeaLife Center. No donation is too small - everything helps. If half of Alaskans donate $10 each, the Center will be saved. We'd love to "sea" you! Online reservations for tickets are strongly encouraged. See how the business community is helping to save the Alaska SeaLife Center. Thank you to all guests and members, past, present, and future, for helping to ensure the Center's mission work continues.            

History Concept The concept of the Alaska SeaLife Center began over 25 years ago, with the initial vision by Seward community leaders to enhance the existing University of Alaska's Seward Marine Center research facilities. Members of both the local and scientific communities identified a need and expressed their support for an expanded research and public education facility in Seward. The concept remained a dream for years with periodic efforts to lobby the University and the Alaska Legislature for funding. Exxon Valdez Oil Spill (EVOS) On March 24, 1989, the supertanker Exxon Valdez spilled 11 million gallons of oil into Prince William Sound, damaging nearly 1,500 miles of Alaska's pristine shoreline and causing widespread harm to the region's wildlife, economy, and ecosystems. Thousands of marine birds, mammals, and fish were destroyed in the days and weeks following the spill. The Exxon Valdez disaster drew dramatic attention to the need for improved facilities to treat injured wildlife, as well as to enhance Alaska's collective research infrastructure. In particular, the disaster brought to light the lack of reliable baseline information on the affected animals and their habitat before the spill. This greatly hindered the capability of scientists to understand the extent of damages and the recovery process. In light of the potential long-term effects of the Exxon Valdez oil spill, scientists identified a need to establish the capability to conduct research and monitoring on a long-term basis. Formation of SAAMS In February 1990, responding to the needs brought to light by EVOS, a group of concerned citizens and researchers formed the Seward Association for the Advancement of Marine Science (SAAMS), a 501(c)(3) non-profit corporation for "educational, social, and cultural purposes including marine research, public education, and providing education and scientific programs." The goal of SAAMS is to create a world-class marine research, wildlife rehabilitation, and public education institution adjacent to the existing University of Alaska Seward Marine Center on Resurrection Bay in Seward, Alaska. That goal advanced by the completion of the Alaska SeaLife Center in 1998. Capital Funding In 1993, the Alaska Legislature appropriated $12.5 million from the EVOS criminal settlement funds as a state grant to the City of Seward to develop the Alaska SeaLife Center as a "marine mammal rehabilitation center and as a center for education and research related to the natural resources injured by EVOS." The City of Seward entered into an agreement under which SAAMS agreed to assume all obligations and responsibilities of the City with respect to administering the State Grant. Following receipt of the first installment of the State Grant funds, SAAMS requested additional funding from the EVOS Trustee Council, the governing body for the EVOS Civil Settlement funds. In November 1994, the Trustee Council authorized $24.956 million to support the development of research facilities at the Center. The Trustee Council subsequently appropriated an additional $1.247 million for a fish pass and research equipment enhancements at the Center. In May 1996, the City of Seward issued $1.75 million in Revenue Bonds to finance $13 million of the cost of constructing the Alaska SeaLife Center. These bonds were retired in March 2001, utilizing a $14 million appropriation to the Center authorized by U.S. Senator Ted Stevens. Finally, a private fundraising campaign raised approximately $6 million for the start-up of the Center. Over $1 million of the campaign was raised within Seward, a town with 3,000 residents. Construction Ground breaking for the Center took place in May 1995. This was followed by Phase I construction which consisted of site preparations, utility relocations, sheet pile cofferdam and breakwater installation, and construction of the seawater intake and outfall reservoirs and lines. The Phase I contract was completed on time in December 1995. Phase II construction commenced in June 1996, and consisted of the main building, life support systems, laboratories, animal habitats, exhibits, and landscaping. Grand Opening occurred on May 2, 1998. Business Model With a mission of bringing visitors in close contact with cutting-edge marine research, the Center’s design includes a public aquarium with exhibit tanks for displaying research animals as well as other North Pacific mammals, birds, fish, and invertebrates. The facility also features a full veterinary suite with quarantine pools for orphaned, diseased, or injured wild animals brought to the Center for rehabilitation, and for resident animals that need medical treatment. Looking to the Future The Alaska SeaLife Center will continue its focus on marine research. As our world, and more specifically the North Pacific, faces dramatic changes caused by environmental factors and human components, the Alaska SeaLife Center will continue to be instrumental in understanding and developing ways to maintain marine ecosystems.

How You Can Help Donate Our Wildlife Response program is mostly funded through private donations. Please consider making an online donation today to support this critical program. Wishlist The patients and their caregivers in the Wildlife Response Program can also be supported by purchasing an item on our Amazon Wishlist. Items in need range from formula for orphaned animals to footwear for the caregivers.  Volunteer Volunteers are key to the success of our Wildlife Response team. The Alaska SeaLife Center has volunteer opportunities to fit a variety of schedules.  

Donate Directly The Alaska SeaLife Center relies on the generous support of people like you as we strive to understand and maintain the integrity of Alaska's marine ecosystems. The Center is the only facility of its kind in Alaska, and we need your help to stay on the cutting edge of marine research, wildlife response, and education. Please consider a donation to the Alaska SeaLife Center as we work together to sustain Alaska's oceans. You can donate directly here or join a Giving Circle for higher level gifts. For more information on supporting Alaska SeaLife Center programs, contact the Development Office at (907) 224-6355 or development@alaskasealife.org. See our Individual Donors from January 1 - December 31, 2022 on the Donors page. Pick.Click.Give. Make a Difference using your Alaska PFD  Pick.Click.Give. allows Alaskans to share their Permanent Fund Dividend with causes they care about.  When you go online to apply for your dividend, you will see the Pick.Click.Give. option. Click and follow the instructions to make your donation. The Alaska SeaLife Center encourages and thanks the many Alaskan donors that have supported us in this way.     Investment Accounts We accept donations from several types of investment accounts, including qualified charitable distributions from IRAs and gifts of publicly traded securities such as stocks, bonds, and mutual funds. Please click here for more details and contact information if you would like to explore this opportunity.   Matching Gifts Your donation or volunteer time may be matched by your employer or you may designate a donation to the Alaska SeaLife Center!   Many employers will match your financial gift one-for-one or even two-for-one, providing additional support for the Alaska SeaLife Center. Click here to see if your company sponsors matching gift programs. Sometime these programs even extend to retirees. For additional information on matching gifts, contact the employee benefits office at your place of employment and request a matching gift form from your personnel office. Follow the directions to complete the form and mail the form for processing to:   Alaska SeaLife Center Attn: Development Office – Matching Gifts P.O. Box 1329 Seward, AK 99664-1329   Contact the Development Office at (907) 224-6355 or development@alaskasealife.org with any questions.

#Wrapper { width:695px; margin-top:10px; } #Content { float:left; width:385px; } #Sidebar { width:260px; margin-left:390px; } #Bottom { width:640px; clear:both; }               ASLC Internship Program Are you looking for an exciting internship opportunity? The Alaska SeaLife Center (ASLC) is sponsoring internship programs for college students or graduates who are interested in gaining a one of a kind experience in a world-class marine facility. ASLC internships offer a well-rounded experience in a variety of areas within the Center. Depending on the type of internship, duties may include assisting aquarium, avian, or marine mammal staff with animal husbandry tasks; helping with marine-related research projects or as support in our education department. Interns will be required to participate in a variety of areas and all are required to participate to some extent in the interpretive aspects of our operation. Interns will not be permitted to participate in ASLC activities on vessels unless specified in the internship.       Click here to apply for an Internship and to view other employment opportunities   Our Internship Program includes: "SUMMER" Internships: May through early August "FALL" Internships: October through December "WINTER" Internships: January through April   Most of your questions are answered on this page. If you find that you may have questions or would like more information on becoming an intern at the Alaska SeaLife Center,  please email the volunteer coordinator.                            Instructions for Applicants  Complete the application for no more than 2 positions. Be sure to provide us with the best e-mail and phone number for contacting you. If you are applying for 2 internships you must complete an application for each one. Upload the required additional information to your application Cover Letter(s) Resume 1 Letter of Recommendation Incomplete applications will not be considered.   Program Requirements Applicants must be college graduates or currently enrolled in an accredited college or university with a background or coursework in a related field. Applicants must have the ability to understand and follow written and oral instruction, have excellent communication skills, and good organizational skills with attention to detail. Applicants must possess the ability to adapt to an ever-changing work environment, and be available weekends, evenings and holidays. Public speaking skills, a familiarity with video equipment and software, and experience with education programs are highly encouraged. For many internships, applicants should be agile with a good sense of balance in order to maneuver around exhibits and holding areas. Program Information  The internships are unpaid. Participation in program requires 40 hours per week. A background check will be conducted on all potential interns. Interns will be required to sign a contract agreeing to a start and end date. College credit can be earned but must be arranged by you and your college. Interns are responsible for their own meals and travel expenses. Foreign students must obtain a J-1 visa to participate.                                                   What people say about us: “I felt like an important part of working toward making a difference for marine life” “I had a great experience; it was everything I could have hoped for. I think that the SeaLife Center has the best overall work environment of anywhere that I’ve worked.” “This is the position to have if you want to be a top candidate for jobs” “It’s a great place to kick off your career, get experience and learn what you like”

  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    

  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  

John first came to Alaska with the U.S. Coast Guard in 1985 and learned to operate a variety of vessels while servicing aids to navigation along the Gulf of Alaska coast.  After leaving the Coast Guard he earned a Bachelor of Science degree at the University of Alaska Southeast, then a Master of Science degree through the University of Alaska Fairbanks (UAF) while studying seabird ecology in Prince William Sound.  John has been working as a Research Associate at the Alaska SeaLife Center (ASLC) since the summer of 2000.  His research focus is on the behavior and population dynamics of Steller sea lions and nesting seabirds, primarily through the use of remote video monitoring techniques.  He earned a Ph.D. degree from UAF with a dissertation study related to his sea lion research at ASLC.  John also continues to work as a part-time captain and naturalist for the tourist industry based in Seward, Alaska.  Behavior and population dynamics of Alaskan pinnipeds and seabirds Google Scholar

ASLC in the news Seward, Alaska (January 14, 2016) - KTVA reporter, Heather Hintze, visited the Alaska SeaLife Center and spoke with our Avian Curator, Tasha Dimarzio, and Science Director, Tuula Hollmen to get the latest on efforts to understand what is currently impacting common murres. An unusual number of live murres have been sighted in the region for this time of year. Researchers and the public have also seen an exponentially higher murre die-off than what is typically associated with El Nino years, with thousands of birds washing up on Alaska’s shores.  For the past five years, Hollmen and ASLC staff, working in partnership with National Park Service, have conducted monthly surveys of murres contributing to the baseline knowledge of these highly specialized seabirds. In addition to working with murres and other birds in the ASLC aviary, Dimarzio volunteers for the Coastal Observation and Seabird Survey (COASST) helping partners enhance the regional understanding of seabirds.  Hintze’s video and story can be found at http://www.ktva.com/seward-volunteers-tracking-dead-murre-numbers-across-alaska-794/.

It is with a heavy heart that we announce the death of Richard C. Hocking, the Alaska SeaLife Center’s esteemed Aquarium Curator of 24 years. Richard passed away November 21 at his home in Seward at the age of 70. Richard was born in Seattle, Washington on April 16, 1951. His curiosity about the natural world was evident from a young age when he declared his intentions to become a forest ranger. He loved camping and exploring at a little forested lot near the Skykomish River as well as during many family trips throughout his home state of Washington and to various national parks. Richard enjoyed numerous hobbies including reading on a variety of subjects, backpacking, skiing, kayaking, photography, movies, traveling, and scuba diving. Diving in particular became a prominent interest in his life as evidenced by his PADI divemaster certification in 1983. While Richard’s job with the Washington Department of Fish and Game paralleled his childhood dreams of being a forest ranger, his passion for the ocean truly defined his life's work. For over four decades, Richard grew his career in the zoo and aquarium industry. He began his legacy in 1976 with the Seattle Aquarium as an Aquarium Biologist. He worked there up until 1989 when he became employed with the Point Defiance Zoo & Aquarium as an Animal Care Technician and additionally assisted with diving and collecting operations. His time at Point Defiance ended when he left for Alaska in 1997.  Richard began his career at the Alaska SeaLife Center as the Aquarium Supervisor in 1997, before the building was even finished. He quickly was promoted to Aquarium Curator in 1998, a role he upheld until his passing. While he significantly shaped the aquarium exhibits and led the division at the Center, his management role never stopped him from doing any task; from checking water quality to leading a tour, Richard took part. “Richard was truly an ASLC treasure. Both a teacher and a student, he had a gift for sharing his endless knowledge of marine species and a passion for marine conservation. His contributions to ASLC for the past 24 years can be seen and felt through all of the exhibits,” explains Husbandry Director, Lisa Hartman. Richard was known as one of the most hands-on curators in the building. While his main role was managing a group of aquarists to maintain and display the species in the Center, he immersed himself in many other aspects of ASLC. Richard managed and secured permits that allow the Center to collect and display fish and invertebrates. He was very involved in the long term monitoring of invasive species in Alaskan waters and would often set and check green crab traps and tunicate plates. He not only was in charge of food procurement and inventory management for fish and invertebrates, but for every single species in the facility.   Always looking towards the future, Richard hoped to educate and motivate the next generation of ocean stewards. He found joy in working with youth and became involved in the Center’s after-school program, Ocean Science Club, leading dissections and classes. Richard was also active as a judge and mentor for the Alaska Ocean Science Bowl, an academic competition for teens involved in ocean science. “Richard knew more about the ocean and the creatures in it than anyone I have or more likely ever will meet.  The only thing that he enjoyed more than learning about the world's oceans was teaching others about it.  He got particular joy out of teaching the next generation about the wonders of the sea. I remember fondly how much he loved the time he got to spend as a judge for the Alaska Ocean Sciences Bowl and as a mentor for the Seward Team. Can you think of a better job for Richard than being a judge in an Alaska Ocean Science competition? I can't,” expresses Aquarist, Chuck DiMarzio.  Richard will be remembered for his kindness, infinite knowledge, selfless work, and inspiring conversation. In 2017, his coworkers fittingly designated him as the “Unsung Hero” for making a consistently important contribution to the day to day operations of the Alaska SeaLife Center. “If you know the ASLC, you know the impact and resource of Richard Hocking. He was a purveyor and connoisseur of biology and natural history, just as eager and willing to share with or learn from a first year college intern as he was a professor emeritus. If you knew Richard, you knew he valued people, what each individual may uniquely be able to offer, and great conversation,” recounts Aquarium Manager and Dive Safety Officer, Jared Guthridge.  A public memorial exhibit to celebrate the life of Richard C. Hocking will be open December 8, 2021 at the Alaska SeaLife Center from 3:30 PM to 6:30 PM. The life, work, and stories of Richard will be displayed throughout the Center and the public can tour at their own pace. A more formal outdoor memorial service is being planned for Spring 2022.

Legacy Society Your Legacy is Our Future  You can be a part of the Alaska SeaLife Center's critical work by leaving a gift through your estate plans. A planned gift allows you to support our mission after your lifetime so future generations can enjoy the bounty of Alaska's oceans. Anyone, regardless of age or financial status, can create a legacy gift to the Alaska SeaLife Center. How to Make a Planned Gift A planned gift can be as simple as naming the Alaska SeaLife Center in your will or designating the Center as a beneficiary on your retirement plan or life insurance policy. The Alaska SeaLife Center Endowment Fund, established through the Alaska Community Foundation, enables additional options for planned gifts through the Foundation's unique expertise.  Sample language to use when making a planned gift to the Alaska SeaLife Center Endowment Fund:   “I bequeath __________________________________ (describe dollar amount, property to be given, or proportion of your residuary estate) to The Alaska Community Foundation (EIN# 92-0155067), a tax exempt organization under IRS Section 501(c)(3), to be added to the Alaska SeaLife Center Endowment Fund, a component fund of The Alaska Community Foundation, and I direct that this bequest become part of this fund.”  Benefits of Planned Giving When you notify us about your gift, we will enroll you in the Alaska SeaLife Center Legacy Society. You will receive invitations to special events and be recognized in our annual report and e-newsletters, unless you choose to remain anonymous. All communications you have with our staff about planned giving is strictly confidential.      We are grateful to those who support the Alaska SeaLife Center through planned giving. Through your gift, you are ensuring that future generations will learn about and care for Alaska's oceans. To learn more about how to enroll, please contact our Development Office at 907-224-6396 or development@alaskasealife.org or download the brochure.      

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

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Spring and Summer 2024 Availability  March 1-August 4: 1:45 pm Daily August 5-September 26: 1:45 pm Wednesdays, Fridays, Saturdays, and Sundays Duration: Approximately 30-minute tour Maximum of 5 people per tour - ages 10+* Come behind the scenes for a unique experience with one of our marine mammal ambassadors! This tour will allow visitors to get an up-close view of the exceptional day-to-day care our seals or sea lions receive while learning about how these amazing species are specially adapted for Arctic and sub-Arctic environments. Each encounter will be unique (and special!).   No photography allowed on this tour. One Group Per Tour Group Size of 1-2 Guests: $274.95 Group Size of 3 Guests: $324.95 Group Size of 4 Guests: $374.95 Group Size of 5 Guests: $424.95 Members get a 20% discount, buy your membership today and use the benefits immediately. (does not include admission) *Guests aged 10-16 must be accompanied by a paying adult Tickets only valid for date selected. Online tickets must be purchased at least one day in advance. 

Starting July 23 Summer 2020 Availability - Tuesdays, Thursdays, Fridays & Sundays: 3:30 pm  Duration: Approximately 30-minute tour Maximum of 5 people per tour - minimum age 13* Meet Mara, our resident Steller sea lion mom and her pup, born June 26 on this once-in-a-lifetime exclusive tour.   Have a chance to feed Mara and watch her interact with her new pup. Learn from our marine mammal staff what it takes to be a good Steller sea lion mom and what it was like welcoming the pup into the world. Don't miss this first time offered interaction that will be available for a very limited time. For the safety and well-being of our animal residents there is no photography allowed on this tour. Flat-Rate Price: $399.95 per group of 1-5 people - members get a 20% discount, buy your membership today and use the benefits immediately *Guests under 16 must be accompanied by a paying adult Tickets only valid for date selected. Tickets must be purchased at least one hour in advance. All guests must wear a face covering on this tour. If you cannot wear a face covering due to a medical condition, please email onlinesales@alaskasealife.org to arrange an accommodation before booking the tour.