Tag: Marine Mammals

New steps towards community engagement: introducing high schoolers to the field

By Florence Sullivan, MSc, GEMM Lab Research Assistant

This summer, I had the pleasure of returning to Port Orford to lead another field season of the GEMM Lab’s gray whale foraging ecology research project.  While our goal this summer was to continue gathering data on gray whale habitat use and zooplankton community structure in the Port Orford region, we added in a new and exciting community engagement component: We integrated local high school students into our research efforts in order to engage with the local community to promote interest in the OSU field station and the research taking place in their community. Frequent blog readers will have seen the posts written by this year’s interns (Maggie O’Rourke Liggett, Nathan Malamud, and Quince Nye) as they described how they became interns, their experience doing fieldwork, and some lessons they’ve learned from the project. I am very impressed with the hard work and effort that all three of them put into making this field season a success.  (Getting out of a warm bed, and showing up at the field station at 6am sharp for five weeks straight is no easy feat for high-schoolers or an undergrad student during summer break!)

Quince hard at work scanning the horizon for whale spouts. photo credit: Alexa Kownacki

During the month of August, our team collected the following data on whale distribution and behavior:

  •  Spent 108 hours on the cliff looking for whales
  • Spent 11 hours actively tracking whales with the theodolite
  • Collected 19 whale tracklines
  • Identified 15 individual whales using photo-ID – Two of those whales came back 3 times each, and one of them was a whale nick-named “Buttons” who we had tracked in 2016 as well.

We also collected data on zooplankton – gray whale prey – in the area:

  • Collected 134 GoPro videos of the water column at the 12 kayak sample sites
  • Did approximately 147 zooplankton net tows
  • Collected 64 samples for community analysis to see what species of zooplankton were present
  • Collected 115 samples for energetic analysis to determine how many calories can be derived from each zooplankton
The 2017 field team. From left to right: Tom Calvanese (Field Station Manager), Florence Sullivan (Project Lead), Quince Nye, Maggie O’Rourke-Liggett, and Nathan Malamud. Photo credit: Alexa Kownacki

Since I began this project in 2015, I have been privileged to work with some truly fantastic interns.  Each year, I learned new lessons about how to be an effective mentor, and how to communicate our research goals and project needs more clearly. This year was no exception, and I worked hard to bring some of the things I’ve learned into my project planning.  As the team can tell you, science communication, and the benefits of building good will and strong community relationships were heavily emphasized over the course of the internship.  Everyone was encouraged to use every opportunity to engage with the public, explain our work, and pass on new things they had learned.  Whenever the team encountered other kayakers out on the water, we took the time to share any cool zooplankton samples we gathered that day, and explain the goals of our research.  Maggie and I also took the opportunity to give a pair of evening lectures at Humbug Mountain State Park, which were both well attended by curious campers.

Florence and Maggie give evening lectures at Humbug Mountain State Park

In addition, the team held a successful final community presentation on September 1 at the Port Orford Field Station that 45 people attended!  In the week leading up to the presentation, Quince and Nathan spent many long hours working diligently on the powerpoint presentation, while Maggie put together a video presentation of “the intern experience” (Click here for the video showcased on last week’s blog).  I am incredibly proud of Nathan and Quince, and the clear and confident manner in which they presented their experience to the audience who showed up to support them.  They easily fielded the following questions:

Q: “How do you tell the difference between a whale that is searching or foraging?”

A: When we look at the boundaries of our study site, a foraging whale consistently comes up to breathe in the same spot, while a searching whale covers a lot of distance going back and forth without leaving the general area.

Q: “How do we make sure that this program continues?”

A: Stay curious and support your students as they take on internships, support the field station as it seeks to provide resources, and if possible, donate to funds that raise money for research efforts.

Nathan talks about the plankton results during the final community presentation. photo credit: Alexa Kownacki
The audience during the final community presntation. photo credit: Alexa Kownacki
Quince and Nathan answer questions at the end of the community presentation. photo credit: Alexa Kownacki

When communicating science, it is important to results into context.  In addition to showcasing the possibilities of excellent research with positive community support, and just how much a trio of young people can grow over the course of 6 weeks, this summer has highlighted the value of long term monitoring studies, particularly when studying long-lived animals such as whales. We saw far fewer whales this summer than compared to the two previous years, and the whales spent much less time in the Port Orford area (Table 1). As a scientist, knowing where whales are not (absence data) is just as important as knowing where whales are (presence data), and these marked differences drive our hypotheses! What has changed in the system? What can explain the differences in whale behavior between years?  Does it have to do with food quality or availability?  (This is why we have been gathering all those zooplankton samples.) Does it have to do with other oceanographic factors or human activities?

Table 1. Summary of whale tracking efforts for the three seasons of field work in Port Orford.   Notice how in 2017 we only collected 194 whale location points (theodolite marks). This is about 92% less than in the previous years.

2015 2016 2017
Hours spent watching 72:49 148:30 108
Hours spent tracking 80:39* 82:30 11
Number of individuals 43 50 15
Number of theodolite marks 2483 2414 194

*we often tracked more than one individual simultaneously in 2015

Long term monitoring projects give us a chance to notice differences between years, and ask questions about what are normal fluctuations in the system, and what are abnormal. On top of that, projects like this create the opportunity for additional internships, and to mentor more students in the scientific method of investigation.  There is so much still to be explored in the Port Orford ecosystem, and I truly hope this program is able to continue.  If you are interested in making a monetary contribution to sustain this research and internship program, donations can be accepted here (gemm lab fund) and here (field station fund).

Quince records zooplankon sample weights in the wet lab.
Quince sorts through a zooplankton sample in the wet lab.
Nathan stores zooplankton community analysis samples
Maggie and Nathan out in the kayak
Quince and Maggie in the kayak
Maggie, Florence and Quince enjoy the eclipse!
Quince and Maggie bundle up on the cliff as they watch for whales.
Nathan and Quince organize data on the computer at the end of the day.
Quince and Nathan build sand castles as we wait for the fog to clear before launching the research kayak

This research and  student internships would not have been possible without the generous support from Oregon Sea Grant, the Oregon Coast STEM hub, the Port Orford Field Station, South Coast Tours, partnerships with the Bernard and Chapman labs, the OSU Marine Mammal Institute, and the Geospatial Ecology of Marine Megafauna Lab.

Through the intern’s eyes; a video log of the 2017 gray whale foraging ecology project.

By: Maggie O’Rourke-Liggett, GEMM lab summer intern, Oregon State University

Enjoy this short video showcasing the intern experience from the gray whale foraging ecology project this summer. Check back next week for a recap of our preliminary results.

New Study Looks to Investigate the Potential Reintroduction of Sea Otters to Oregon

By Dominique Kone, Masters Student in Marine Resource Management

As I begin a new chapter as a grad student in the Marine Resource Management program at Oregon State University, the GEMM Lab is also entering into unchartered waters by expanding its focus to a new species outside the lab’s previous research portfolio. This project – which will be the focus of my thesis – will assess the potential reintroduction of sea otters to the Oregon coast through an examination of available habitat and ecological impacts. Before I explain how this project came to fruition, it’s important to understand why sea otter reintroduction to Oregon is relevant, and why this step is important to advance the conservation of these charismatic species.

While exact historical populations are unknown, sea otters were once abundant along the coasts of northern Japan, across Russia and Alaska, and down North America to Baja California, Mexico[1]. In the United States, specifically, sea otters were native to coastal waters along the entire west coast – including Oregon. However, beginning in the 1740’s sea otters were subject to intense and unsustainable hunting pressure from Russian, British, and American entrepreneurs seeking to sell their highly-valuable pelts in the lucrative fur trade[2].  Historical records suggest these hunters did not arrive in Oregon until the 1780’s, but from that point on the sea otter was exploited over the next several decades until the last known Oregon sea otter was killed in 1906 at Otter Rock, OR[3].

Pictured: Sea otter hunters near Coos Bay, OR in 1856. Photo Credit: The Oregon History Project.

After decades of intense pressure, sea otter numbers dropped to critically low levels and were thought to have gone extinct throughout most of their range. Luckily, remnant populations persisted and were later discovered in parts of Alaska, British Columbia, California, and Mexico beginning in the 1910’s. Since then sea otters have been the focus of intense conservation efforts. With the goal of augmenting their recovery, the Alaska Department of Fish and Game lead a series of translocation projects, where groups of sea otters were transported from Alaska to unoccupied habitats in Alaska, British Columbia, Washington, and Oregon (Note: these were not the only sea otter translocations.)1.

Pictured: Sea otters on glacier ice, northern Prince William Sound, Alaska. Photo Credit: Patrick J. Endres/AlaskaPhotoGraphics.com

Fun Fact: For a marine mammal, sea otters have surprisingly little blubber. Luckily, they also have the densest fur of all animals – an estimated 1,000,000 hairs per square inch – that helps to keep them well-insulated from the cold.

Many of these projects are considered successful as sea otter populations grew, and continue to expand today. With a significant exception: sea otters mysteriously disappeared shortly after reintroduction into Oregon waters and the translocation effort failed. Many hypothesized what could have gone wrong – natural mortality, dispersal, conflicts with humans – but few have concrete answers. Aside from occasional reports of strandings and sightings of sea otters in Oregon coastal waters, no resident populations have formed. This is where my thesis project comes in.

Pictured: Cape Arago, OR – one of the unsuccessful translocation sites along the Oregon coast. Photo Credit: TravelOregon.com

With renewed interests from scientists, tribes, and the public, we are now revisiting this idea from a scientific perspective. Over the next two years, we will work to objectively assess the ecological aspects of sea otter reintroduction to Oregon to identify and fill current knowledge gaps, which will help inform decision-making processes by environmental managers. Throughout this process we will give consideration to not just the ecology and biology of sea otters, but the cultural, economic, and political relevance and implications of sea otter reintroduction. Much of this work will involve working with state and federal agencies, tribes, and other scientists to gain their insights and perspectives, which we will use to shape our research questions and analyses.

The process to move forward with bringing sea otters back to Oregon will no doubt take great effort by a lot of people, consultation, patience, and time. To date, we have been reviewing the relevant literature and meeting with local experts on this topic. Through these activities, we have determined the types of questions and information – suitable habitat and potential ecological impacts – of most need to managers. My goal is to conduct a meaningful, applied project as an objective scientist, and by gaining this type of feedback at the outset, I am to help managers make better-informed decisions. I hope my thesis can serve as a critical starting point to ensure a solid foundation that future Oregon-specific sea otter research can build from.

References:

[1] Jameson et al. 1982. History and status of translocated sea otter populations in North America. Wildlife Society Bulletin. (10) 2: 100-107.

[2] The Oregon History Project: Sea Otter. Accessed September 2017. <https://oregonhistoryproject.org/articles/historical-records/sea-otter/#.WamgT7KGPIU>

[3] The Oregon History Project: Otter Hunting. Accessed September 2017. <https://oregonhistoryproject.org/articles/historical-records/otter-hunting/#.Wa2TCLKGPIU>

 

The passion of a researcher

By Quince Nye, GEMM Lab Summer Intern, Pacific High School Junior

I have spent a lot of my life surrounded by nature. I like to backpack, bike, dive, and kayak in these natural environments. I also have the luck of having parents who are always planning to take me on another adventure where I get to see nature and its inhabitants in ways most people don’t get to enjoy.

Through my backyard explorations, I have begun to realize that Port Orford has an amazing ecosystem in the coves and rivers that are very tied into our community. I’ve fished and swam in these rivers, gone on kayaking tours in these coves (with a great kayak company called South Coast Tours that we partner with), and I’ve seen the life that dwells in them.

Nathan and Maggie paddle out to Mill Rocks for early morning sample collection

Growing up in a school of less than 100 kids I have learned to never reject an opportunity to be a part of something bigger and learn from that experience. So when one of my close friends told me about an OSU project (a college I’m interested in attending) that needed interns to help collect data on gray whales, and kayak almost every day, I signed up without a doubt in my mind.

The team gets some good practice tracking Buttons (Whale #3).  Left to right; Quince, Nathan, Maggie, Florence.

Fast forward a month, and I wake up at 5:20 am. I eat breakfast and get to the Port Orford Field Station. We make a plan for the operations of both the kayak team and cliff team. Today, I’m part of the cliff team, so I head up above the station to Fort Point. Florence and I set up the theodolite and computer at the lookout point and start taking half hour watch shifts searching the horizon for the spout of a gray whale.  Sometimes you see one right away, but other times it feels like the whales are actively hiding from you. These are the times I wish Maggie was here with her endless supply of Disney soundtracks to help pass the hours.

Imitating a ship’s captain, Quince points toward our whale while shouting “Mark”.

A whale spouts out at Mill Rocks and starts heading across to the jetty. Hurray, its data collection time! I try to quickly move the cross-hairs of the theodolite onto the position of the whale using a set of knobs like those on an etch-a-sketch. As you may understand, it’s not an easy task at first but I manage to do it because I’ve been practicing for three weeks. I say “Mark!” cueing Florence to click a button in the program Pythagoras on the computer to record the whale’s position.

The left hand side of Buttons – notice the scatter of white markings on the upper back.

Meanwhile, Florence sees that the whale has two white spots where the fluke meets the knuckles. Those are identifying marks of the beloved whale, Buttons. This whale has been seen here since 2016 and is a fan favorite for our on-going research program. Florence gets just as excited every time and texts her eagerly awaiting interns of previous years all about the sighting. Of course Buttons is not the only whale to have identifying marks such as scars and pigmentation marks. This is why we make sure to get photos of the whales we spot, allowing us to do photo-ID analysis on them through comparison to our database of pictures from previous years.

Quince practices CPR protocol on a training mannequin on his first day.

So far I have gained skill after skill in this internship. I got CPR certified, took a kayak training class, learned how to use a theodolite, and have spent many educational (and frustrating) hours entering data in Excel. I joined the program because I was interested in all of these things. It surprised me that I was developing a relationship with the whales I’m researching. By the end of August I’m now sure that I will also know many of the whales by name. I will probably be much better at using an etch-a-sketch, and I will have had my first taste at what being a scientist is like. What I strive for, however, is to have the same look in my eyes that appears in Florence’s whenever a familiar whale decides to browse our kelp beds.

Curiosity and Community, new ways of exploring our environment.

By Nathan Malamud, GEMM Lab summer intern, Pacific High School senior

I am someone who has lived in a small town for all his life. Pretty much everyone knows each other by their first name and my graduating class only has around 20 people. Everywhere you look you will find a farm, ranch, or cranberry bog (even our school has two bogs of their own!). Because of my small town life, I have a strong sense of community. However, I have also developed a curiosity about natural and global phenomena. I try to connect these two virtues by participating in scientific efforts that help my community. When I heard that the OSU Port Orford Field Station was offering internships, I knew right away that it would definitely be a great experience for me.

The view from our field site at Fort Point in Port Orford

Port Orford, on Oregon’s southern coast, is a town that is closely tied to the ocean. So naturally, it’s important to understand and monitor our surroundings so that our town can thrive. Last year, my Marine Science class helped me further understand the complexity of the ocean. Our first semester taught us all about marine biology, zoology, and ecology. Our second semester immersed us into oceanography, ocean geology, and ocean chemistry. During the second semester, we also took trips to our town’s marine science center and to the marine reserve near Rocky Point. I loved this course and decided to try to expand my knowledge about the subject by going to the OSU Field Station.

Our safety instructor teaches takes us through basic paddling techniques

As an intern, I am currently working with three teammates to understand the feeding behavior of gray whales – what places they like to eat zooplankton the most and why they like to eat there. This whale project helps our community by Port Orford enabling high school students to perform college-level scientific research and inquiry, as well as allowing us to learn valuable skills such as CPR, surveying using a theodolite, working with chemicals in a lab, and data processing.

We had to learn how to rescue ourselves just in case we have an accident in the boat.
We all made it back in the boat!

This internship with OSU’s GEMM Lab has taught me many new skills and given me new experiences that I have never had before. Before this internship, I had never been in a kayak. Now, I go out on the water nearly every other day! When on the water, I always try to sharpen my navigating skills. I use a GPS to pinpoint the locations of our sampling stations, and I communicate to my partner where we need to go and how we will get there.

Its very important to stretch before kayaking every morning.

Once we are there, it is my job to keep the boat close to the station location so that my partner can get accurate samples. This part is a very tricky task, because not only do I have to pay attention to the GPS to make sure we are within 10 meters of the spot, but I also have to pay attention to my surroundings. I have to look at the ocean, and figure out what direction the waves are coming from. I have to watch how external forces, like wind and currents, can cause the boat to drift far from station, and I have to correct drifting with gentle paddle strokes. This is hard, especially since the kayak is so light and easy to get pushed around by the wind. However, despite the difficulty, I have learned that it is crucial not to panic. Frustration only makes things worse. The key is to maintain a harmonic balance of concentration and zen.

I have also learned that when collecting data in the field, it’s important to observe and document as much as possible. When we are in the kayak, we have 12 stations that we try to visit every day (as long as the weather cooperates). At each station, we first use a secchi disk to test the water clarity, then lower the GoPro to film the water column and see where the zooplankton are. Sometimes we catch other interesting things on the video too, such as siphonophores (my personal favorites are jellies and salps) and rockfish.

A siphonophore
A rockfish captured with our GoPro.

Next we tow a zooplankton net through the water, and let it collect zooplankton of all shapes and sizes, from tiny mysids to skeleton shrimp. Then we proceed to the next station and repeat the process. We have to remember to label everything, and tell the GoPro camera what station we’re at so we can sort all the information correctly when we get back to the field station. At the end of the day, we log our data into a computer, and preserve half our plankton samples with ethanol, so that we can identify the species present.  The other half gets frozen for caloric content analysis by our collaborator Dr. Kim Bernard to help us understand how much zooplankton a whale needs to eat to meet its energy needs each day.

By repeating this entire process every day, we are able to look at daily changes, which also helps us to better understand why whales spend time in certain areas and not others. Be sure to check out my teammate Maggie’s blog post about some of the tools and technologies we use to track the whales!

This whale project has been, and definitely still is, a great experience for me! I have learned a lot and have worked with some amazing people. I believe that I am learning many valuable skills, and that the skills I learn will allow me to help my community.

A Little Slice of Heaven

Guest writer: Maggie O’Rourke-Liggett, GEMM Lab summer intern, Oregon State University,

One of the biggest obstacles an undergraduate can face is fulfilling the degree requirement of completing an internship or research opportunity. With almost every university and degree program requiring it for graduation and many employers requiring prior experience, the amount of pressure and competition is intense.

After being rejected from the internships I applied for earlier in the year, I heard about Dr. Leigh Torres’s research with the Geospatial Ecology of Marine Megafauna (GEMM) Lab . I decided to email her and ask if she had any open positions. Fast-forward a few weeks and I am collaborating with Florence Sullivan, a recent masters graduate from OSU, on the logistics of my Gray Whale Foraging Behavior internship with the GEMM Lab.

 

My workstation while I conduct photo identification analysis in the field station classroom. The photos are displayed and organized in Adobe Bridge. Source: Maggie O’Rourke-Liggett

During my time with the GEMM Lab team, I have been assisting with photo identification analysis of gray whales (Eschrichtius robustus), using a theodolite and Pythagoras computer program to track their movements, collecting samples of the zooplankton they eat, and recording other oceanographic data with our time-depth recorder. This project is hoping to identify the drivers of gray whale fine-scale foraging behavior.  For instance: Why do gray whales spend more time in some areas than others?  Does the type or density of prey affect their behavior? Do the whales use static features like kelp beds to help find their food? As a senior currently studying oceanography, who desires to study whale behavior in the future, this internship is like finding a gold mine.

Nathan Malamud, our other high school intern, and I working together to set up the theodolite in backyard during a practice run. Source: Florence Sullivan

Ever since day one at Hatfield Marine Science Center, I’ve been working with people who share the same passions for marine mammals as me. Spending hours upon hours sorting thousands of pictures may seem like a painful, tedious job, but knowing my work helps others to update existing identification catalogs makes it worthwhile. Plus, who wouldn’t want to look at whales all day?! After a while, you start to recognize specific individuals based on their various pigment configurations and scars. Once you can recognize individuals, it makes the sorting go by faster and helps with recognizing individual whales in the wild faster. It’s always exciting to sort through the photos and observe from the cliff or kayak and recognize a whale from the photo identification work.

After Florence taught me how to set up and operate the theodolite, a survey tool used to track a whale’s movements, we taught a class to undergrads on how to use it. I’ll never get over how people’s faces lit up when we discussed how the instrument works and its role in the overall mission.

Quince Nye, one of our high school interns, using side strokes to stabilize the kayak while I deploy our zooplankton net over the side with a down rigger. Source: Florence Sullivan

These past two weeks at OSU’s Port Orford Field Station have been like living on a little slice of heaven. My days are filled with clear views of the coast and the sound of waves crashing serve as a backdrop on my home for the month, the bed-and-breakfast turned field station. Each morning, the sun fills my room as I gather my gear for the day and help my teammates load the truck. We spend long days on the water collecting zooplankton samples and GoPro video or on the cliff recording whale behavior through the theodolite. To anyone searching for an internship and feeling burnt out from completing application after application, don’t give up. You’ll find your slice of heaven too.

Life in the lab: notes from a lab meeting

By Florence Sullivan, MSc, Oregon State University

One of my favorite parts about working as a member of the GEMM lab is our monthly lab meeting. It’s a chance for everyone to share exciting news or updates about their research, discuss recent advances in our field, and of course, make the schedule for who is in charge of writing the blog each week!  Our fearless leader, Leigh, usually also has an exercise for us to complete. These have varied from writing and editing abstracts for conferences, conducting mock interviews of each other, reading and discussing relevant papers, R coding exercises, and other useful skills. Our most recent meeting featured an exciting announcement, as well as a really interesting discussion of the latest International Whaling Commission (IWC) reports of the scientific committee (SC) that I felt might be interesting to share with our readers.

First, the good news – Six GEMM lab members submitted abstracts to the 2017 Society of Marine Mammalogy Conference, and all six were accepted for either a speed talk or an oral presentation! We are very proud and excited to present our research and support each other at the conference in October.

And now, a little science history:

The IWC was originally formed as a management body, to regulate the global catch of great whales. However, it never had much legal power to enforce its edicts, and was largely ineffective in its task.  By 1986 whale populations had been decimated to such low numbers by commercial whaling efforts that a worldwide moratorium on harvest was imposed. The SC of the IWC meets on an annual basis, and is made up of leading experts in the field who give advice and recommendations to the commission.  If you are interested in seeing reports from over the years, follow this link to the IWC Archive.  The reports presented by the various sub committees of the Scientific Committee are dense, packed full of interesting information, but also contain lots of procedural minutiae.  Therefore, for this lab meeting, each of us took one of the 2017 Annexes, and summarized it for the group.

Alyssa and Dawn reviewed Annex J: Report of the working group on non-deliberate human induced mortality of cetaceans.  The report shared new data about scarring rates of bowhead whales in the Bering Sea, notably, that 2.4% of the population will acquire a new scar each year, and that by the time an individual is 25 years old, it has a 40% chance of being scarred from a human derived interaction. The study noted that advances in drone technology may be an effective tool to assess scarring rates in whale populations, but emphasized that it is important to examine stranded carcasses to ground truth the rates we are able to capture from aerial and boat based photography.  The discussion then turned to the section about ship strikes, where we learned that in a comparison of fresh scars on humpback whales, and rates of voluntarily reported ship strikes, collisions were vastly under reported. Here it was noted that injuries that did not cause visible trauma could still be lethal to cetaceans, and that even moderate speed collisions can cause non-immediate lethal injury.

Leila walked us through Annex K: Report of the standing working group on environmental concerns. This subcommittee was the first one formed by the SC, and their report touched on issues such as bioaccumulation of heavy metals in whales, global oil spill emergency response training, harmful algal blooms (HABs), marine debris, diseases of concern, strandings and related mortality, noise, climate change, loss of arctic sea ice, and models of cetacean reaction to these impacts.

A few notes of particular interest:

-PCBs and other toxins are known to accumulate in killer whales, but this report discussed high levels of lead and cadmium in gray whales, leading to the question of what might be the source – sediment deposits? Fish?

-Lots of research has been done on the outfall of HABs involving domoic acid; now there is a need for research on other types of HABs

-A website has been created to increase surveillance, diagnosis and risk management of cetacean diseases, and is currently being refined: https://cdoc.iwc.int

-Changing climate is prompting distribution shifts in a number of species, putting animals at risk of interactions with shipping lanes, and increasing contact with invasive species.

-Models of cetacean bioenergetics have found that being entangled has energy costs equivalent to migration or pregnancy. Another model found that naval noise increased the metabolic rate of individuals by 30%. Models are becoming more and more accurate and complex every year, and each new one helps provide a framework to begin to assess cumulative impacts of human-cetacean interactions.

To wrap things up, I gave a brief overview of Annex N: Report of the subcommittee on whalewatching. This report gave quick updates on a number of different whale watching research projects around the world:

-Humpback whales in Hawaii change their swim speed and dive time when they encounter vessels.

-Endangered humpbacks in the Arabian Sea may need management intervention because there have been minimal advances in standards and attitudes by whale watching outfits or recreational boaters in Oman.

-Increased interactions and close encounters may be eroding the protective social barriers between bottlenose dolphins and the public.  The committee emphasizes that cetacean habituation to humans is a serious conservation cause of concern.

After research updates, the document then details a review from the working group on swim-with-whale operations. They emphasize the need for a global database, and note that the Convention on Migratory Species and the World Cetacean Alliance are both conducting reviews of this section of the whale watching industry and that a collaboration could be beneficial. Finally, this committee often gives feedback to ongoing projects and local management efforts, but is not convinced that their recommendations are being put into practice.

As one reads this litany of issues that face cetaceans in the modern world, it can be quite disheartening. However, reports like these keep researchers up to date on the current state of knowledge, areas of concern, and questions that need answering.  They help us set our priorities and determine which piece of the puzzle we are capable of tackling.  For more on some of the projects that our lab has under taken to help tackle these issues, check out Leila’s work on stress in gray whales, Dawn’s work looking at blue whales in New Zealand, Solene’s work on humpback habitat selection, or my work on vessel interactions. Individually, it’s easy to feel small, but when you look through the archives of the IWC, and realize how far we’ve come from extractive management to active conservation, you realize that every little project adds to those before it, and together, we can make a difference.

 

 

 

Finding the edge: Preliminary insights into blue whale habitat selection in New Zealand

By Dawn Barlow, MSc student, OSU Department of Fisheries and Wildlife, Geospatial Ecology of Marine Megafauna Lab

I was fortunate enough to spend the Austral summer in the field, and so while the winter rain poured down on Oregon I found myself on the water with the sun and wind on my face, looking for blue whales in New Zealand. This spring I switched gears and spent time taking courses to build my analytical toolbox. In a course on technical writing and communication, I was challenged to present my research using only pictures and words with no written text, and to succinctly summarize the importance of my research in an introduction to a technical paper. I attended weekly seminars to learn about the diverse array of marine science being conducted at Oregon State University and beyond. I also took a course entitled “Advanced Spatial Statistics and Geographic Information Science”. In this skill-building course, we were given the opportunity to work with our own data. Even though my primary objective was to expand the tools in my toolbox, I was excited to explore preliminary results and possible insight into blue whale habitat selection in my study area, the South Taranaki Bight region (STB) of New Zealand (Figure 1).

Figure 1. A map of New Zealand, with the South Taranaki Bight (STB) region delineated by the black box. Farewell Spit is denoted by a star, and Kahurangi point is denoted by an X.

Despite the recent documentation of a foraging ground in the STB, blue whale distribution remains poorly understood in New Zealand. The STB is New Zealand’s most industrially active marine region, and the site of active oil and gas extraction and exploration, busy shipping traffic, and proposed seabed mining. This potential space-use conflict between endangered whales and industry warrants further investigation into the spatial and temporal extent of blue whale habitat in the region. One of my research objectives is to investigate the relationship between blue whales and their environment, and ultimately to build a model that can predict blue whale presence based on physical and biological oceanographic features. For this spring term, the question I asked was:

Is the number of blue whales present in an area correlated with remotely-sensed sea surface temperature and chlorophyll-a concentration?

For the purposes of this exploration, I used data from our 2017 survey of the STB. This meant importing our ship’s track and our blue whale sighting locations into ArcGIS, so that the data went from looking like this:

… to this:

The next step was to get remote-sensed images for sea surface temperature (SST) and chlorophyll-a (chl-a) concentration. I downloaded monthly averages from the NASA Moderate Resolution Imaging Spectrometer (MODIS aqua) website for the month of February 2017 at 4 km2 resolution, when our survey took place. Now, my images looked something more like this:

But, I can’t say anything reliable about the relationships between blue whales and their environment in the places we did not survey.  So next I extracted just the portions of my remote-sensed images where we conducted survey effort. Now my maps looked more like this one:

The above map shows SST along our ship’s track, and the locations where we found whales. Just looking at this plot, it seems like the blue whales were observed in both warmer and colder waters, not exclusively in one or the other. There is a productive plume of cold, upwelled water in the STB that is generated off of Kahurangi point and curves around Farewell Spit and into the bight (Figure 1). Most of the whales we saw appear to be near that plume. But how can I find the edges of this upwelled plume? Well, I can look at the amount of change in SST and chl-a across a spatial area. The places where warm and cold water meet can be found by assessing the amount of variability—the standard deviation—in the temperature of the water. In ArcGIS, I calculated the deviation in SST and chl-a concentration across the surrounding 20 km2 for each 4 km2 cell.

Now, how do I tie all of these qualitative visual assessments together to produce a quantitative result? With a statistical model! This next step gives me the opportunity to flex some other analytical muscles, and practice using another computational tool: R. I used a generalized additive model (GAM) to investigate the relationships between the number of blue whales observed in each 4 km2 cell our ship surveyed and the remote-sensed variables. The model can be written like this:

Number of blue whales ~ SST + chl-a + sd(SST) + sd(chl-a)

In other words, are SST, chl-a concentration, deviation in SST, and deviation in chl-a concentration correlated with the number of blue whales observed within each 4 km2 cell on my map?

This model found that the most important predictor was the deviation in SST. In other words, these New Zealand blue whales may be seeking the edges of the upwelling plume, honing in on places where warm and cold water meet. Thinking back on the time I spent in the field, we often saw feeding blue whales diving along lines of mixing water masses where the water column was filled with aggregations of krill, blue whale prey. Studies of marine mammals in other parts of the world have also found that eddies and oceanic fronts—edges between warm and cold water masses—are important habitat features where productivity is increased due to mixing of water masses. The same may be true for these New Zealand blue whales.

These preliminary findings emphasize the benefit of having both presence and absence data. The analysis I have presented here is certainly strengthened by having environmental measurements for locations where we did not see whales. This is comforting, considering the feelings of impatience generated by days on the water spent like this with no whales to be seen:

Moving forward, I will include the blue whale sighting data from our 2014 and 2016 surveys as well. As I think about what would make this model more robust, it would be interesting to see if the patterns become clearer when I incorporate behavior into the model—if I look at whales that are foraging and traveling separately, are the results different? I hope to explore the importance of the upwelling plume in more detail—does the distance from the edge of the upwelling plume matter? And finally, I want to adjust the spatial and temporal scales of my analysis—do patterns shift or become clearer if I don’t use monthly averages, or if I change the grid cell sizes on my maps?

I feel more confident in my growing toolbox, and look forward to improving this model in the coming months! Stay tuned.

Building scientific friendships: A reflection on the 21st annual meeting of the Northwest Student Chapter of the Society for Marine Mammalogy

By Dawn Barlow, M.Sc. student, Department of Fisheries and Wildlife, Geospatial Ecology of Marine Megafauna Lab

I recently had the opportunity to attend and present my research at the 21st meeting of the Northwest Student Chapter of the Society for Marine Mammalogy. This gathering represented a community of graduate and undergraduate students from the Pacific Northwest, networking and discussing their research on the biology of marine mammals. Dr. John Ford, whose name has become synonymous with killer whale research in the Pacific Northwest, delivered a compelling keynote speech on not only the history of his research, but also the history of the relationships he has built in the field and the people that have shaped the past five decades of killer whale research. This theme of cultivating scientific relationships was a thread that carried us through the weekend. Beautiful weather had us all smiling happily as we ate our lunches outside, musing about science in the sunshine. A philosopher’s café event facilitated roundtable discussions with experts in veterinary science, spatial statistics, management consulting, physiology, and marine pollution. Students were given the space to ask questions ranging from manuscript writing advice to the worth of our work in the current political climate (and write notes or doodle drawings on the paper-covered tables as we listened).

The oral and poster presentations were all very impressive. I learned that bowhead whales are likely feeding year-round in the Canadian Arctic, adjusting their dive depth to the vertical location of their copepod prey. I learned that the aerobic dive limit of stellar sea lions is more of a sliding scale rather than a switch as it is for Weddell seals. I learned that some harbor seals are estuary specialists, feeding on salmon smolt. And I learned about the importance of herring to Northeast Pacific marine mammals through an energy-based ecosystem model. I had the opportunity to present my research on the ecology of New Zealand blue whales to an audience outside of Oregon State University for the first time, and was pleased with how my presentation was received.

Aaron Purdy, MSc student with the University of British Columbia’s Marine Mammal Research Unit, moderates the first oral presentation session wearing the designated “fluke tuke”. I may have giggled at the Canadian word for beanie, but I have to admit, “fluke tuke” has a much better ring to it than “fluke beanie”!

But beyond the scientific research itself, I also learned that there is a strong community of motivated and passionate young scientists in the Pacific Northwest studying marine mammals. Our numbers may not be many and we may be scattered across several different universities and labs, but our work is compelling and valuable. At the end of the weekend, it felt like I was saying goodbye to new friends and future colleagues. And, I learned that the magnificent size of a blue whale never fails to impress and amaze, as all the conference attendees marveled over the blue whale skeleton housed in the Beaty Biodiversity Museum at the University of British Columbia.

Left to right: Michelle Fournet, Samara Haver, myself, and Niki Diogou representing Oregon State University at the student conference. Behind us is a blue whale skeleton, housed in the Beaty Biodiversity Museum on the University of British Columbia campus.

Many thanks to the graduate students from the University of British Columbia who organized such a successful event! At the end of the conference, it was decided that the next meeting of the Northwest Student Chapter will be hosted by the Oregon State University students here at Hatfield Marine Science Center in Newport. It is a year away, but I am already looking forward to seeing these newfound peers again and hearing how their research has progressed.

A happy student selfie at the end of a successful conference! We are looking forward to a reunion at Hatfield Marine Science Center next May!

“Marching for Science” takes many forms

By Florence Sullivan, MSc student, Oregon State University.

Earth day is a worldwide event celebrated annually on April 22, and is typically observed with beach, park, or neighborhood clean ups, and outreach events sponsored by environmental groups.  Last year, environmentalists rejoiced when 195 nations signed the Paris Agreement – to “strengthen global response to the threat of climate change by keeping global temperature rise below 2 degrees C”.

GEMM Lab member Dawn Barlow helps carry the banner for the Newport, OR March for Science which over 600 people attended. photo credit: Maryann Bozza

This year, the enviro-political mood is more somber. Emotions in the GEMM Lab swing between anger and dismay to cautious optimism and hope. The anger comes from threatened budget cuts, the dismissal of climate science, and the restructuring of government agencies, while we find hope at the outpouring of support from our local communities, and the energy building behind the March for Science movement.

The Newport March for Science. photo credit: Maryann Bozza

What is perhaps most striking about the movement is how celebratory it feels. Instead of marching against something, we are marching FOR science, in all its myriad forms. With clever signs and chants like “The oceans are rising, and so are we”, “Science, not Silence”, and “We’re nerds, we’re wet, we’re really quite upset” (it rained on a lot of marches on Saturday) echoing around the globe, Saturday’s Marches for Science were a cathartic release of energy, a celebration of like-minded people.

Our competition room for NOSB 2017! Game officials are in the front of the picture, competitors at the first two desks, and parents, coaches and supporters in the back.

While millions of enthusiastic people were marching through the streets, I “Ran for Science” at the 20th annual National Ocean Science Bowl (NOSB) – delivering question sheets and scores between competitors and graders as 25 teams competed for the title of national champion! Over the course of the competition, teams of four high school students compete through rounds of buzzer-style multiple choice questions, worksheet style team challenge questions, and the Scientific Expert Briefing, a mock congressional hearing where students present science recommendations on a piece of legislation.  The challenges are unified with a yearly theme, which in 2017 was Blue Energy: powering the planet with our ocean.  Watching the students (representing 33 states!) compete is exciting and inspiring, because they obviously know the material, and are passionate about the subject matter.  Even more encouraging though, is realizing that not all of them plan to look for jobs as research scientists. Some express interest in the arts, some in policy, or teaching or engineering. This competition is not just about fostering the next generation of leading marine scientists, but rather about creating an ocean-literate, and scientifically-literate populace.  So, congratulations to Santa Monica High School, who took home the national title for the first time this year! Would you like to test your knowledge against some of the questions they faced? Try your luck here!

Santa Monica competes in the final round

The GEMM Lab also recently participated in the Hatfield Marine Science Center’s Marine Science Day.  It’s an annual open house where the community is invited to come tour labs, meet scientists, get behind the scenes, and learn about all the exciting research going on.  For us as researchers, it’s a great day to practice explaining our work and its relevance to many different groups, from school children to parents and grandparents, from artists to fishermen to teachers, fellow researchers, and many others.  This year the event attracted over 2,000 people, and the GEMM Lab was proud to be a part of this uniquely interactive day.  Outreach events like this help us feel connected to our community and the excitement present in all the questions field during this event reassure us that the public still cares about the work that we do.

Lab members Florence, Leila, and Dawn (L to R) answer questions from the public.

Our science is interdisciplinary, and we recognize the strength of multiple complimentary avenues of action to affect change.  If you are looking to get involved, consider taking a look at these groups:

500 Women Scientists: “working to promote a diverse and inclusive scientific community that brings progressive science-based solutions to local and global challenges.” Read their take on the March for Science.

314Action: starting from Pi (3.14), their mission is “to (1) strengthen communication among the STEM community, the public and our elected officials, (2) Educate and advocate for and defend the integrity of science and its use, (3) Provide a voice for the STEM community on social issues, (4) Promote the responsible use of data driven fact based approaches in public policy and (5) Increase public engagement with the STEM Community through media.”

She should run: “A movement working to create a culture that inspires women and girls to aspire towards public leadership. We believe that women of all backgrounds should have an equal shot at elected leadership and that our country will benefit from having a government with varied perspectives and experiences.” https://peoplesclimate.org/

And finally, The March for Science is finishing up it’s week of action, culminating in the People’s Climate March on April 29.

How will you carry the cause of science forward?