The Beginning of the End

By Rachel Kaplan, PhD candidate, Oregon State University College of Earth, Ocean, and Atmospheric Sciences and Department of Fisheries, Wildlife, and Conservation Sciences, Geospatial Ecology of Marine Megafauna Lab

I moved to Corvallis exactly four years ago, in the deep, dark midst of the Covid pandemic, and during the added chaos of the 2020 Labor Day Fires, some of the worst in Oregon’s history. I vividly remember attending our virtual lab meeting sitting on the floor surrounded by boxes, while my labmates told me their own stories (many, surprisingly!) of moving during natural disasters. At the time, beginning graduate school represented so many big changes in my life: I had quit my job, sold my furniture, and moved across the country, hoping to explore an area of research that had been calling to me for years, and to gain a new skillset and confidence.

Highlight: A very pandemic cruise. My first day of marine mammal fieldwork in 2021, at sea with (now Dr.) Dawn Barlow.

Now, I’m starting the fifth year of my PhD, thinking about all that has happened and all that is to come. Graduate school is full of milestones to mark time and progress: I’ve taken the courses required for my program, sat for a written exam to test my broad knowledge of oceanography, and written a dissertation proposal. Earlier this year, I spent two months buried in the literature on oceanography, krill, and whale ecology in preparation for my oral qualifying exam. I’ve stared at the water for dozens of hours watching for whales off the Oregon coast, and experienced polar night studying winter krill in Antarctica. I’ve conquered my fear of learning to code, and felt constant, profound gratitude for the amazing people I get to work with.

The last four years have been incredibly busy and active, but now more than ever, it feels like the time to really do. I can see the analytical steps ahead for my final two dissertation chapters more clearly than I’ve been able to see either of the other two chapters that have come before. One of my favorite parts of the process of research is discussing analytical decisions with my labmates and supervisors, and experiencing how their brains work. Much of our work hinges on modeling relationships between animals and their environment. A model, most fundamentally, is a reduced-scale representation of a system. As I’ve learned to use statistical models to understand relationships between krill and whales, I have simultaneously been building a mental model of the Northern California Current (NCC) ecosystem and the ecological relationships within it. Just as I have long admired in my supervisors and labmates, I can now feel my own mind becoming more playful as I think about this ocean environment, the whales and krill that make a living in the NCC, and the best way to approach studying them analytically.

Highlight: Working on my dissertation proposal during a friend’s 2022 wedding celebration in Utah.

Graduate school demands that you learn and work to constantly exceed your own bounds, and pushing to that extent for years is often stressful and even existentially threatening. However, this process is also beautiful. I have spent the last four years growing in the ways that I’ve long wanted to, and reveled in feeling my mind learn to play. I wouldn’t give up a moment of the time I’ve spent in the field, the relationships I’ve built with my labmates, or the confidence I’ve developed along the way.

As I look ahead to this next, final, year of graduate school, I hope to use what I’ve learned every day – and not just about how to conduct research, but about myself. I want to always remember that krill, whales, and the ocean ecosystem are incredible, and that it is a privilege to study them. I hope to work calmly and intentionally, and to continue appreciating this process of research and growth.

Highlight: My first in-person oral presentation, at the 2024 ICES-PICES International Zooplankton Production Symposium in Hobart, Tasmania.

The Theme of the Year is Learning New Things!

By Hali Peterson, rising freshman, Western Oregon University

Hello, my name is Hali Peterson and I am a rising freshman in college. Last summer (2023) I was given the opportunity to be a paid high school intern for the OSU Marine Mammal Institute’s very own GEMM Lab (Geospatial Ecology of Marine Megafauna Laboratory) based at the Hatfield Marine Science Center in Newport, Oregon. My time working in the GEMM Lab has been supported by the Oregon Coast STEM Hub. I started my internship in June 2023 and I was one of the two GEMM Lab summer interns. However, my internship did not end when summer did, as I continued to work throughout the school year and even into this summer. 

Figure 1: Leaving work late and accompanied with a beautiful view of the Newport bridge over Yaquina Bay.

June 29, 2023 to September 20, 2024 (1 year, 2 months, and 21 days if anyone is curious) – what did I do and what did I learn during this time…

Initially, I was tasked with helping the GRANITE project (Gray whale Response to Ambient Noise Informed by Technology and Ecology) by processing drone footage of Pacific Coast Feeding Group (PCFG) gray whales and identifying their zooplankton prey. I started off my internship under the mentorship of KC Bierlich and Lisa Hildebrand and I dove into looking at zooplankton underneath a microscope and watching whales in drone footage, both gathered by the GEMM Lab field team. 

KC taught me how to process drone footage, measure whales and calibration boards, test an artificial intelligence model, as well as write a protocol of the drone processing methods that I had worked on. These tasks were a big responsibility as the measurements need to be accurate and precise so that they can be used to effectively assess the body condition of gray whales, which provides crucial insights into population health.

Figure 2: My favorite drone video of moms and calves meeting up for a playdate!

Under Lisa’s mentorship I learned how to identify and process zooplankton prey samples, process underwater GoPro videos, as well as identify and analyze kelp patches from satellite images. Within these tasks, I honed my expertise in zooplankton and habitat analysis and the results of my work will contribute to a deeper understanding of gray whale feeding habits along the Oregon coast.

Figure 3: My favorite zooplankton to see, a juvenile crab larva.

As my main mentors, KC and Lisa taught me so much about the world of science and research. All of these detail-oriented and multi-layered tasks helped me improve some of the skills I already had before I started the internship as well as gift me with skills I didn’t previously possess. For example, I learned how to collaborate and work with a team, pay attention to detail, double and even triple check everything for quality work, problem solve, and learn to ask questions. 

However, as my time in the GEMM Lab extended beyond the summer of 2023, so did my tasks. Later on I received another mentor, Clara Bird. Under Clara I learned how to identify whales from drone footage recorded in Baja, Mexico (an area that is specifically known as the breeding lagoons where the gray whales go in the winter), as well as use the Newport, Oregon drone footage and CATS (Customized Animal Tracking Solution) tag data to measure inhalation duration and bubble blast occurrences. These experiences furthered my knowledge and yet again I learned something new, a common theme throughout my time in the GEMM Lab. 

Just a few months ago, the GEMM Lab hired Laura Flores Hernandez as a new high school student summer intern, and under the guidance of both Lisa Hildebrand and Leigh Torres, I was given the opportunity to develop my own mentoring skills. I used the skills I had obtained over the past year to teach someone else how to do the tasks I once was new to. I taught Laura how to identify zooplankton, process drone footage, and measure calibration boards. Stepping into that mentor role helped me reflect on my own learning and experiences. I had to go back and figure out how I did things, where I struggled, and how I overcame those struggles. Not an easy task but one I was glad to be presented with. 

Figure 4: Matthew Vaughan (chief scientist on the trip) and me (right) looking at a box core sample.

During my time here I was also invited to join a STEM (Science, Technology, Engineering, Mathematics) cruise led by Oregon Sea Grant with fellow high school students. On this science cruise I got to help look at box core samples (a tool used to collect large amounts of sediment off of the ocean floor). Equipped with my previous knowledge on zooplankton identification, I was able to help the chief scientist on the trip to explain to other high school students what we were seeing in the samples. This trip helped me grow my teamwork and identification skills, as well as experience what it is like to collect data while on a moving ship. 

Figure 5: Sea Kayaking through the fjord with the Girls on Icy Fjords team of 2024.

Another amazing opportunity I was selected for was to join the 2024 Girls on Icy Fjords team. This program, in association with OSU, was designed to empower young women in STEM in the backcountry of Alaska. With a team of 3 amazing instructors and 8 girls (all from different parts of the United States of America) we camped in the backcountry for 8 days, learning about glaciers and fjords, surviving in the backcountry, sea kayaking, and working as a team. I would highly recommend any young woman interested in science, art, or just an amazing experience to check out Inspiring Girls Expeditions.

Bonus Image: This is Jeff the Moyebi Shrimp and I love him.

All in all this will be a job that I will not soon forget; interning in the GEMM Lab has been both a learning opportunity as well as a challenge. My internship wasn’t without its challenges, from a computer that seemed determined to shut down whenever I made progress, to endless hours spent staring at a green screen, waiting to count a fish that might eventually swim by. Though the job had its ups and downs, I am so glad I was given this opportunity and was kept on in the lab for as long as I was. In just a few weeks, I will start my Bachelors of Aquarium Science at Western Oregon University and I’m both excited and nervous. I know that without a doubt the skills I learned during this internship will come in handy as I continue my education and pursue a career in the future. 

Thank you to all my mentors, anyone who answered one of the many questions I had, and to the friends I made along the way!

Two Leaders Wearing Two Hats: A wrap-up of the 2024 TOPAZ/JASPER Field Season

Celest Sorrentino, incoming master’s student, OSU Dept of Fisheries, Wildlife and Conservation Sciences, GEMM Lab

Allison Dawn, PhD student, Clemson University Dept of Forestry and Environmental Conservation, GEMM Lab Alum

Allison:

Celest and I were co-leaders this year, so it only feels fitting to co-write our wrap-up blog for the 2024 field season.

This was my first year training the project leader while also leading the field team. I have to say that I think I learned as much as Celest did throughout this process! This hand-off process requires the two team leaders to get comfortable wearing two different hats. For me, I not only made sure the whole team grasped every aspect of the project within the two training weeks, but also ensured Celest knew the reasoning behind those decisions AND got to exercise her own muscles in decision making according to the many moving parts that comprise a field season: shifts in weather, team needs, and of course the dynamics of shared space at a field site with many other teams. With the limited hours of any given day, this is no small task for either of us, and requires foresight to know where to fit these opportunities for the leader-in-training during our day-to-day tasks.

During this summer, I certainly gained even more respect for how Lisa Hildebrand juggled “Team Heck Yeah” in 2021 while she trained me as leader. Lisa made sure to take me aside in the afternoon to let me in on her thought process before the next days work. I brought this model forward for Team Protein this year, with the added bonus that Celest and I got to room together. By the end of the day, our brains would be buzzing with final thoughts, concerns, and excitement. I will treasure many memories from this season, including the memory of our end-of-day debriefs before bed. Overall, it was an incredibly special process to slowly pass the reins to Celest. I leave this project knowing it is ready for its new era, as Celest is full of positive energy, enthusiasm, and most importantly, just as much passion for this project as the preceding leaders.

Fig. 1: Two leaders wearing two (massive) hats. Field season means you have to be adaptable, flexible, and make the most out of any situation, including sometimes having to move your own bed! We had a blast using our muscles for this; we are Team Protein after all!

Celest:

As I sit down in the field station classroom to write this blog, I realize I am sitting in the same seat where just 12 hours ago a room full of community members laughed and divided delicious blueberry crumble with each other.

We kicked the morning of our final day together off with a Team Protein high powered breakfast in Bandon to have some delicious fuel and let the giggles all out before our presentation. When Dr. Torres arrived, the team got a chance to reflect on the field season and share ideas for next season. Finally, the moment we had all been waiting for:  at 5 PM Team Protein wrapped up our 2024 field station with our traditional Community Presentation.

Fig 2: Team breakfast at SunnySide Cafe in Bandon, which have delicious GF/DF options.

Within a month and a half, I transitioned from learning alongside each of the interns at the start of the season knowing only the basics of TOPAZ/JASPER, to eventually leading the team for the final stretch. The learning spurts were quite rapid and challenging, but I attribute my gained confidence to observing Allison lead. To say I have learned from Allison only the nitty-gritty whats and whys of TOPAZ/JASPER would not suffice, as in truth I observed the qualities needed to empower a team for 6 weeks. I have truly admired the genuine magnetic connection she established with each intern, and I hope to bring forth the same in future seasons to come.

Witnessing each intern (myself included!) begin the season completely new, to now explaining the significance of each task with ease to the very end was unlike any other. Presenting our field season recap to the Port Orford Community side-by-side with Sophia, Eden, Oceana, and Allison provided an incredible sense of pride and I am thrilled for the second TOPAZ/JASPER Decadel party in 2034 when we can uncover where this internship has taken us all.

…Until next season (:

Fig 3: Team Protein all together at the start of season all together.

Fig 4: Team Protein all smiles after wrapping up the season with the Community Presentation.

Fig 4: Our season by numbers for the 2024 TOPAZ/JASPER season!

Speeding Up, Slowing Down, and Choosing My Fig

Celest Sorrentino, incoming master’s student, OSU Dept of Fisheries, Wildlife, and Conservation Sciences, GEMM Lab

It’s late June, a week before I head back to the West Coast, and I’m working one of my last shifts as a server in New York. Summer had just turned on and the humidity was just getting started, but the sun brought about a liveliness in the air that was contagious. Our regulars traded the city heat for beaches in the Hamptons, so I stood by the door, watching the flow of hundreds upon hundreds of people fill the streets of Manhattan. My manager and I always chatted to pass the time between rushes, and he began to ask me how I felt to move across the country and start my master’s program so soon.

“I am so excited!” I beamed, “Also a bit nervous–”

Nervous? Why? 

Are you nervous you’ll become the person you’re meant to be?”

As a first-generation Hispanic student, I found solace in working in hospitality. Working in a restaurant for four years was a means to support myself to attain an undergraduate degree–but I’d be lying if I said I didn’t also love it. I found joy in orchestrating a unique experience for strangers, who themselves brought their own stories to share, each day bestowing opportunity for new friendships or new lessons. This industry requires you to be quick on your feet (never mess with a hungry person’s cacio e pepe), exuding a sense of finesse, continuously alert to your client’s needs and desires all the while always exhibiting a specific ambiance.

So why leave to start my master’s degree?

Fig 1: Me as a server with one of my regulars before his trip to Italy. You can never go wrong with Italian!

For anyone I have not had the pleasure yet to meet, my name is Celest Sorrentino, an incoming master’s student in the GEMM Lab this fall. I am currently writing to you from the Port Orford Field Station, located along the charming south coast of Oregon. Although I am new to the South Coast, my relationship with the GEMM Lab is not, but rather has been warmly cultivated ever since the day I first stepped onto the third floor of the Gladys Valley Building, as an NSF REU intern just two summers ago. Since that particular summer, I have gravitated back to the GEMM Lab every summer since: last summer as a research technician and this summer as a co-lead for the TOPAZ/JASPER Project, a program I will continue to spearhead the next two summers. (The GEMM Lab and me, we just have something– what can I say?)

 In the risk of cementing “cornball” to my identity, pursuing a life in whale research had always been my dream ever since I was a little girl. As I grew older, I found an inclination toward education, in particular a specific joy that could only be found when teaching others, whether that meant teaching the difference between “bottom-up” and “top-bottom” trophic cascades to my peers in college, teaching my 11 year old sister how to do fun braids for middle school, or teaching a room full of researchers how I used SLEAP A.I. to track gray whale mother-calf pairs in drone footage.

Onboarding to the TOPAZ/JASPER project was a new world to me, which required me to quickly learn the ins and outs of a program, and eventually being handed the reins of responsibility of the team, all within 1 month and a half. While the TOPAZ/JASPER 2024 team (aka Team Protein!) and I approach our 5th week of field season, to say we have learned “so much” is an understatement.

Our morning data collection commences at 6:30 AM, with each of us alternating daily between the cliff team and kayak team. 

For kayak team, its imperative to assemble all supplies swiftly given that we’re in a race against time, to outrun the inevitable windy/foggy weather conditions. However, diligence is required; if you forget your paddles back at lab or if you run out of charged batteries, that’s less time on the water to collect data and more time for the weather to gain in on you. We speed up against the weather, but also slow down for the details.

Fig 2: Throwback to our first kayak training day with Oceana (left), Sophia(middle), and Eden (right).

For cliff team, we have joined teams with time. At some point within the last few weeks, each of us on the cliff have had to uncover the dexterity within to become true marine mammal observers (for five or six hours straight). Here we survey for any slight shift in a sea of blue that could indicate the presence of a whale– and once we do… its go time. Once a whale blows, miles offshore, the individual manning the theodolite has just a few seconds to find and focus the reticle before the blow dissipates into the wind. If they miss it… its one less coordinate of that whale’s track. We speed up against the whale’s blow, but also slow down for the details. 

Fig 3: Cliff team tracking a whale out by Mill Rocks!

I have found the pattern of speeding up and slowing down are parallels outside of field work as well. In Port Orford specifically, slowing down has felt just as invigorating as the first breath one takes out of the water. For instance, the daily choice we make to squeeze 5 scientists into the world’s slowest elevator down to the lab every morning may not be practical in everyday life, but the extra minute looking at each other’s sleepy faces sets the foundation for our “go” mode. We also sit down after a day of fieldwork, as a team, eating our 5th version of pasta and meatballs while we continue our Hunger Games movie marathon from the night prior. And we chose our “off-day” to stroll among nature’s gentle giants, experiencing together the awe of the Redwoods trees.

Fig 4A & 4B: (A) Team Protein (Sophia, Oceana, Allison, Eden and I) slow morning elevator ride down to the lab. (B) Sophia hugging a tree at the Redwoods!

When my manager asked the above question, I couldn’t help but think upon an excerpt, popularly known as “The Fig Tree” by Sylvia Plath.

Fig 5: The Fig Tree excerpt by Sylvia Plath. Picture credits to @samefacecollective on Instagram.

For my fig tree, I imagine it as grandiose as those Redwood trees. What makes each of us choose one fig over the other is highly variable, just as our figs of possibilities, some of which we can’t make out quite yet. At some point along my life, the fig of owning a restaurant in the Big Apple propped up. But in that moment with my manager, I imagined my oldest fig, with little Celest sitting on the living room floor watching ocean documentaries and wanting nothing more than to conduct whale research, now winking at me as I start my master’s within the GEMM Lab. Your figs might be different from mine but what I believe we share in common is the alternating pace toward our fig. At times we need speeding up while other times we just need slowing down.

Then there’s that sweet spot in between where we can experience both, just as I have being a part of the 2024 TOPAZ/JASPER team.

Fig 6A and 6B: (A) My sister and I excited to go see some dolphins for the first time! (~2008). (B) Taking undergraduate graduation pics with my favorite whale plushy! (2023)

Fig 7: Team Protein takes on Port Orford Minimal Carnival, lots of needed booging after finishing field work!

Little bit of Kayaking, Lot a bit of Zoops

Eden Van Maren, Homeschool Student from Brookings, TOPAZ/JASPER High School Intern

Hey! I’m Eden Van Maren, an upcoming high school senior from Brookings. I am homeschooled and am taking electives at Brookings Harbor High School. 

Growing up in rural Oregon, the outdoors have always been more than just my backyard. It’s been both my classroom and my playground. When Oceana (the other high school intern) and I were homeschooled together as children, Fridays meant her mom would take us up the Chetco River. One Friday, we took our snorkels to observe mature salmon migrating upstream. I remember being so amazed by the size and quantity of the salmon, my young brain could not understand why such large fish would want to swim up to such a small area to lay eggs. The next year when we returned to try and see if the salmon would swim upstream again, we found only one salmon swimming around. This river became my classroom, planting my initial interest in science. 

However. Let’s be clear: Being outside in nature was never “all work, no play” – Definitely lots of play! Summers were filled with sunsets on the beach, some foggy day hikes, but most importantly kayaking on the river. I have many fun memories of waking up early on a weekend to pack food for a long day of kayaking in a tandem with my dad and a bunch of other friends. As I’ve gotten older, my passion for both the environment and science have only grown.

Fig 1: My dad and I kayaking with my dog on the Chetco River.

After going on a college tour at the University of Oregon in January, I suddenly started thinking that I should begin planning for college and future career options. On that tour, I met Ma’yet, the Youth Program Education Coordinator at Curry Watershed Partnership who had worked with Allison. Ma’yet was familiar with the TOPAZ/JASPER program run by the GEMM Lab and, while we were discussing possible summer opportunities in science, they suggested that I would be a great fit.  

In early March, when I discovered there would be someone from the program coming to present at school, I had already been scheduled to work a shift at Dutch Bros. I managed last minute to have one of my coworkers cover the last few hours of my shift so I would be able to get there. He arrived late, so I ran to get there on time, but I made it! Upon arriving, I sat down for the presentation, and, within minutes, Allison confirmed my desire to be a part of this program. I always knew that science is where I wanted to focus my studies. When I came across this program, I was very interested because it involved exciting outdoor activities while learning and experiencing scientific field work. I was thrilled to meet Allison in person to ask questions and share my enthusiasm about the project. 


Before working at the Port Orford field station, I had never given much thought to zooplankton. I had known they were the primary prey for whales, but other than that, I hadn’t considered that there was much else to think about. After starting the work associated with zooplankton on this project, I learned through Sophia how zooplankton can be affected by water temperature and kelp abundance, among other things. Along with learning more about zooplankton ecology, part of the program includes collecting zooplankton samples from 12 different stations (using a kayak) out along the Port Orford coastal area. On my very first training day of zooplankton sampling, I pulled up a ridiculous number of zooplankton in the net (much more than the last few seasons).

Fig 2: Me pulling up my first net of zoops! Look at all that zoop!

Once we return to the lab after a morning of zoop collection, we observe these samples under a microscope, identify their species, and count how many species we collected from each station. Just two weeks into our data collection, we have collected 4291 individual zoops, which already surpasses the total amount of zooplankton collected in 2023 and 2022 combined! That’s a lot of zoops! But how do we do it? 

In our team, I am considered the zoop expert, but I couldn’t do it without a handful of Welch’s fruit snacks and my playlist full of bangers. Zoop processing can be very tedious, but I really enjoy the peace that comes with finishing a giant sample by myself. I love being able to blast AJR in the background while ID’ing each zooplankton even though my team loves to tease me for it (but really, I’m totally putting them on). As I’ve gotten better at ID’ing zooplankton, I started brainstorming about what could help teach other interns in the future. Allison and Lisa, the previous TOPAZ/JASPER leaders, created very useful guides used to train me but I felt that there could be other interactive methods to help interns learn about zoop. Having used Quizlet in the past, I thought it would be a great resource to introduce the zooplankton basics to new interns, so I created an online Zooplankton Identification quiz!

Fig 3A & 3B: Me processing a giant sample of Atylus Tridens.

Despite having only completed three weeks of our data collection season so far, I have already learned so much! From waking up at 5:30 ten days in a row, to kayaking for four hours straight, to even counting 995 (not 1000!) zooplankton in one sitting, this internship has been amazing. It’s been a great introduction to working in the scientific field as many of the responsibilities we have been taught are completely new to me. I am excited to share this internship experience as I apply to colleges and add to my list of skills “Zoop expert.”

Fig 4: My favorite zooplankton! A Dungeness Crab Larvae.

“So, I hear you’re an expert in marine mammal ecology?”

Oceana Powers-Schmitz, Brookings-Harbor High School student, TOPAZ/JASPER GEMM Lab Project, MMI Oregon State University

Hi, I’m Oceana Powers-Schmitz and while I am not quite an expert in marine mammal ecology (yet!), I am quite the expert in bringing the team together through a clever game and a heartfelt laugh. One game I turned the team onto this summer during a team dinner was “So, I hear you’re an expert in ______.” Essentially, someone in your group provides you with a niche topic and someone else will have to then go on a spiel about it for at least a minute. One of the best ones I heard so far was when we were driving back from getting Langlois Market hot dogs (don’t knock it, till you’ve tried it). I tasked Eden with “So, I hear you’re an expert in the price of tea in China”. The most fun part of this game is how you have to think on your feet when the pressure is on. This skill is helpful during this internship because I have had to troubleshoot a lot in the field. One example of this was when the team had to rethink the mechanics of our zooplankton net because it was not collecting efficiently. We solved this problem by taking a trip to Gold Beach Lumber and attaching a washer to the bottle to weigh it down, allowing for more space to catch zooplankton within the bottle.

Fig 1: Zooplankton net (Left) with fishing weights in the bottle. Zooplankton net (Right) after removing weights and adding washer.

Although I’m definitely the best at this game, the team has shown some promise at getting better as we spend more and more time together. At the start of the internship, I watched the team make our share of mess ups (fortunately during training week!) such as not turning on equipment or losing the spare zooplankton net overboard. As the internship has progressed, it has been amusing to experience us getting a handle on all the new methods and protocols that come with the TOPAZ/JASPER project. For example, in the beginning, one of the most challenging methods to execute in the field is setting up the Theodolite on an unlevel cliff side. But now Celest and I have a competition to see who can set up and level the Theodolite the fastest. (If you ask her, we’re tied— but I’m obviously winning.)

Fig 2: Celest (right) and me (left) after I assembled the theodolite. (Celest thinks she’s winning.)

Afternoons in the lab are an enjoyable part of the day (for me at least) because it is a chance to relax after an eventful, physically demanding (and hopefully whale-filled) morning. After we break for lunch, I head to the kitchen to make my go-to: 4 slices of Oven-roasted Turkey, a slab of butter, pinch of pepper and salt (can’t be stingy with the salt) on two toasted slices of Buttermilk bread. Pro tip: food is best digested with a book; I’m on my third one.

Fig 3: The best post-field day lunch combo 🙂

The afternoon is also a chance to become closer as a team. From watching the GoPro bloopers to trying desperately to get Google Earth to work in order to check if we were “on station,” these afternoons are always fun. While this statement might be a hot take, I’ve really gravitated to data processing over zooplankton ID. For this project, data processing consists of inputting RBR data, visibility metrics, and going through each station’s GoPro footage into an excel sheet. This process is an important part of the long-term study of our Port Orford field site because researchers will be able to access and use this information. Using what we have collected, future studies may draw new conclusions or make important findings that can be published and add to our knowledge of the ecology of the local gray whales.

Though I am not yet an expert in the field, this internship has solidified the idea that I could become one in marine science. I’m glad for the hands-on experience this internship has provided and through this I feel confident in the fact that I would enjoy this career path. Over the next couple weeks, I can’t wait to introduce the team to more entertaining games to keep us on our toes while we wait for whales. I’m excited for each of us to return home saying “I’m an expert at GEMM Lab’s TOPAZ/JASPER Gray Whale Project.”

Fig 4: Locked in, listening to my favorite podcast, looking through RBR data.

*P.S. Here’s a great podcast to listen to when processing data, you can thank me later 🙂

Radio Lab Link

Getting to the Bottom of it

Sophia Kormann, NSF REU Intern in the GEMM Lab, St. Olaf College

Hello! My name is Sophia Kormann and I am an NSF REU intern this summer in the GEMM lab being mentored by PI Leigh Torres, Allison Dawn, and Clara Bird. I was introduced in last week’s blog as part of our awesome whale team (deemed “Team Protein”) working out of Port Orford. I am a rising senior at St. Olaf College where I am studying statistics and biology. One of my personal goals for this summer was to get to the bottom of what is next for me. A pretty small task if you ask me… I really want to figure out if research is the route I want to go within the intersection of these two subjects or if something else would be a better fit. When looking into internships I wanted to find something where I could analyze data and see how research works as a career first hand, but not be stuck at a desk all day. I pretty much struck gold with the GEMM lab.

This summer I get to participate in field work that involves ocean kayaking, tracking whales, and identifying zooplankton, while also conducting statistical analysis on data collected from the past two years of this decade-long project. In 2022, the TOPAZ project introduced a new sensor to the data collection procedures, the RBR concerto,which records for dissolved oxygen and temperature readings during a “cast” through the water column. My big task for the summer was to explore how temperature and dissolved oxygen affect zooplankton abundance data that were simultaneously collected via a GoPro during the 2022 and 2023 field seasons. 

Figure 1. Me (!) doing my first zooplankton sampling in our kayak R/V Robustus. 

My project involves modeling zooplankton abundance as a response to temperature and dissolved oxygen. The ultimate goal would be to be able to plug in the dissolved oxygen and temperature to an equation and get back an accurate prediction for the zooplankton abundance, but this is often tricky to do with data that has been collected from the field. I needed to get to the bottom of what causes a change in zooplankton abundance. After a lot of trial and error, I eventually determined that temperature and dissolved oxygen at the lowest depth of each cast has the best relationship with zooplankton abundance along the whole cast, and thus produce the most accurate predictions of zooplankton abundance from the model. I literally had to go to the bottom of the ocean to get to the bottom of the relationship. 

In hindsight, these relationships make a lot of sense for the Port Orford ecosystem. Ask anyone at the field station this summer and we can all tell you that it can be VERY windy here. This abundance of wind mixed with the shallow depths of the system make for very well mixed water, which means that there is little variation in the temperature and dissolved oxygen in the entire water column from the surface to the floor (Kämpf 2017).  The wind here causes an increase of upwelling, which is the process of moving surface water away from the coast and allowing for deeper water to replace it. This upwelling brings cold, nutrient dense water that is low on oxygen to the surface (Bograd 2023). Since this Port Orford ecosystem is so well mixed, the bottom is likely the most stable in terms of temperature and dissolved oxygen (Ni 2016). Therefore, it would make sense that this stability would then lead to a better prediction of zooplankton as it is less affected by other factors that could be affecting the zooplankton abundance such as wind speed, land temperature, turbidity and other variables that we did not take into account while modeling.

Figure 2. Functional response curves produced from a general additive model for zooplankton abundance in response to bottom dissolved oxygen (top left), bottom temperature (top right), and station (bottom).

Table 1. Zooplankton abundance is significantly affected by bottom dissolved oxygen and bottom temperature.

At this point during my summer. I have made a lot of progress in completing the data analysis and I also have made a lot of progress in getting to the bottom of “what’s next?” for me. Thankfully, this effort did not involve going to the bottom of the ocean, although I aced my kayak safety and basic life safety training since being here, so I would definitely be able to self-rescue even if I did end up there. Anyhow, one thing that helped me with this process is that I had the privilege of attending the Decadal Celebration for the TOPAZ/JASPER project. I got the chance to interact with so many people that had been in my exact place as an intern on this project over the last nine years. We discussed gap years, masters programs, and just got to hear about so many different pathways to current roles. There truly is no one “right way” to go from here. 

This internship experience also taught me that I really enjoy sharing what I have discovered in this research. Whether answering the “What are you doing?” questions we get almost everyday from tourists while we are doing cliff work, or creating templates of my code for future researchers to use, or teaching Leigh Torres Gen-Z slang over dinner (ask her what “I’m dead” and “Let him cook” mean… she knows now!), I have found out that I love sharing information with others.

Figure 3. Me teaching the other interns and our new team lead how to analyze the GoPro footage. 

Part of what has drawn me to statistics is the ability to turn a long string of data into an easily digestible graph for the general public. Being a part of this opportunity has allowed me to really figure out my interests and I have discovered a very genuine passion for making sense of the unknown through data analysis. With this experience I know I will be happy with whatever comes next for me as long as there is someone to share results with and a challenging question for me to get to the bottom of.

We have four more weeks of work for this field season which means more time on the ocean and hopefully more time with whales! I am very excited to see what the near future holds for me and what more we will be able to uncover this summer. With our community presentation in front of us, I am excited to share our summer with those in Port Orford. I also get to present my own research in our REU poster symposium. I look back on the almost six weeks that have already flown by with gratefulness for all I’ve already been able to learn and look forward to the next four weeks with excitement for what’s yet to be discovered.

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References 

Bograd, SJ, Jacox, MG, Hazen, EL, Lovecchio, E, Montes, I, Pozo Buil, M, Shannon, LJ, Sydeman, WJ, Rykaczewski, RR (2023) Climate change impacts on eastern boundary upwelling systems. Annual Review of Marine Science 15

Kämpf, J (2017) Wind-driven overturning, mixing and upwelling in shallow water: A nonhydrostatic modeling study. Journal of Marine Science and Engineering, 5(4), 47. https://doi.org/10.3390/jmse5040047

Ni, X, Huang, D, Zeng, D, Zhang, T, Li, H, & Chen, J (2016) The impact of wind mixing on the variation of bottom dissolved oxygen off the Changjiang Estuary during summer. Journal of Marine Systems, 154, 122–130. https://doi.org/10.1016/j.jmarsys.2014.11.010 

Giving Ecologists Mega Muscles: Introducing the 2024 Port Orford Gray Whale Foraging Ecology Project Team, “Team Protein”!

Allison Dawn, Master’s alumni, OSU Department of Fisheries, Wildlife and Conservation Sciences, Geospatial Ecology of Marine Megafauna Lab

In addition to honoring the decade-long legacy, this year is also special as I am co-leading “Team Protein” with Celest Sorrentino, incoming GEMM lab Master’s student. Now with four South Coast summers under my belt, I am beyond excited to get to share what I’ve learned with someone equally as passionate about immersive marine science education and mentorship. While I am teaching Celest how to prepare for weather-dependent fieldwork, lead a team of 5, shop on a budget, organize the lab, and more, I am also learning so much from her. I am especially grateful for her bright energy and unwavering positivity, which are skills that can rarely be taught yet have such a powerfully positive influence on the success of a field season. After just a week together I feel there is no one better suited for me to pass on the “GoPro/RBR torch” to and I know she will lead the project successfully into its next chapter.

Figure 1: Allison and Celest, on a particularly windy day, fully packed with gear and groceries, ready and excited to head to the South Coast Outpost!

That said, we still have 5 weeks before the 10th year has officially culminated, and it is my honor and pleasure to introduce you to the team who will be paddling us through this incredible milestone! Before I talk about each individual, I’d like to explain the inspiration behind our team name this year.

Every Port Orford field team gets to choose their team name, and we quickly settled on ours – “Team Protein”! After we spent a few days together, the five of us found we have at least two things in common: we all love exercise and to fuel up on protein. Between quick 2-3 mile evening runs, competitive pushups after dinner, yoga – on top of our kayaking and gear-carrying- and so much baked chicken, we are undoubtedly getting stronger together. 

In addition to this name describing the team well, we also have seen an increase in zooplankton abundance sampled during the first-week than in previous years. Because whale food seems to be prevalent this year, we all agree that this season’s whales will also be on “Team Protein”. We hope that means we will see strong, healthy PCFG whale visitors in the next several weeks!

Figure 2: Logo for “Team Protein”, created by NSF REU Sophia Kormann

So, who exactly are the brains and brawn behind Team Protein? First, we have team leader Allison (me!). I defended my master’s degree in June 2023 and loved the beauty and community of the South Coast so much I decided to stick around for one more adventure-filled year before moving on to begin my doctorate at Clemson University in South Carolina. There I will be implementing all the skills and lessons learned in the GEMM Lab into studying grassland bird habitat using remote sensing technologies. I am thrilled to get another year of leading this incredibly dynamic project, mentoring students, and obviously increasing my muscle mass before I move on from studying (gray) whales to (bobwhite) quails.

Figure 3: Allison stoked on great conditions for our first kayaking sampling training day

Next, we have our co-lead, Celest Sorrentino!

Figure 4: Celest, Allison, and Leigh grabbing a selfie before the awesome Decadal Party!

Name: Celest Sorrentino

School/year: Oregon State University, incoming master’s student 

What interested you in this project/what are you most excited for?

As an older sister of four, teaching and mentoring them has always been something I’ve loved to do and intended to hone my skills in as I pursued higher education. When the opportunity arose during a conversation with Dr. Torres last summer to be able to develop these valuable skills during my masters, I couldn’t be more excited. Now having completed just my first week here in Port Orford, I can totally understand the enamor Allison has shared for this project. I am excited to continue to learn from her as not only a lead for this project, but also from her own mentorship style that is both naturally impactful and unique. 

Our third team member is our NSF REU student Sophia Kormann. Stay tuned for her blog next week on the exciting project that she has been co-mentored by myself, Leigh and Clara.

Figure 5: Sophia enjoying the beautiful moonrise on the cliff site at the Decadal Party.

Name: Sophia Kormann

School/year: rising senior at St. Olaf College

What interested you in this project/what are you most excited for?

I was looking for something within biology research that would allow me to do a lot of analysis but wouldn’t just be sitting at a desk all day. And if you get the chance to whale watch everyday for the summer…you take it. I am the most excited to combine my interests in biology and statistics.

Next we have Eden Van Maren, who I met during a recruitment talk in Brookings. Eden immediately stood out as an enthusiastic and bright student.

Figure 5: Eden’s first zooplankton net sample had more amphipods than Allison had ever seen in the net!

Name: Eden Van Maren

School/year: I am homeschooled doing electives at Brookings-Harbor High School. 

What interested you in this project/what are you most excited for?

I was interested in this opportunity because of the opportunity to do scientific field work while getting to kayak on the ocean. I’m excited to learn about how ocean conditions affect zooplankton and how that impacts whale foraging.

Last but not least, we have Oceana Powers-Schmitz. Oceana is a passionate bookworm and impressive history buff. In addition to taking on this fieldwork internship, she is also teaching herself Algebra 2 in order to test out of taking the class next year.

Figure 6: Oceana finds a red urchin at Nellie’s Cove!

Name: Oceana Powers-Schmitz

School/year: Brookings-Harbor High School

What interested you in this project/what are you most excited for?

Getting actual research/lab experience as well as using it to see what part of science I’m interested in, and to hopefully have a whale-filled summer. 

Well, as a surprise to no one, we’re off to do some yoga. Tune into our Instagram takeover by following @gemm_lab on instagram for more real-time updates from “Team Protein”!

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Burning Krillories – Determining Krill Caloric Content in New Zealand’s South Taranaki Bight

By Nina Mahalingam, University of California Davis, OSU CEOAS REU program

Hello! I’m Nina Mahalingam, a rising junior at the University of California, Davis studying biochemistry and molecular biology. Growing up in New Hampshire and Massachusetts, the Boston Aquarium was practically in my backyard –  and with just one feel of a touch tank, a lifelong affinity for marine sciences began. CEOAS has provided me with a grand opportunity to pursue this passion, and I can’t wait to dip my toes into the salt water!

Figure 1. Nina posing with a Parr Semimicro Calorimeter.

Here at OSU, I’m researching how our tiny friends, the krill, can provide a krill-uminating perspective on trophic ecology and the vitality of marine ecosystems by investigating the caloric content of an understudied species of krill off the coast of New Zealand. Nyctiphanes australis serves as a key prey species to numerous higher trophic levels. Limited knowledge exists regarding the distribution of N. australis in the South Taranaki Bight (STB), with only a handful of studies focused exclusively on the species. The majority of recent information available on the species in the STB came out of research on blue whales and their foraging behaviors (e.g., Barlow et al., 2020). However, given that the spatial distribution of N. australis directly influences the distribution of predator species that depend on them for sustenance (Barlow et. al. 2020), studying the krill may yield a more comprehensive understanding of blue whale behavior as well as ecosystem resilience.

Figure 2. Nyctiphances australis. Photo by A. Slotwinski, CSIRO.

Seawater temperatures around New Zealand have been increasing since 1981 (Sutton & Bowen, 2019), and there is a growing concern about the implications to marine life. In particular, increasing ocean temperatures have had significant impacts on local aquaculture and fisheries (Sutton et al. 2005; Bowen et al. 2017). Although warming trends along the North Island, north of East Cape, have been more severe (around 0.4℃ increase per decade), warming has also been observed in the central and western areas of the STB, averaging around 0.15-0.20℃ increase per decade (Sutton & Bowen, 2019). During Marine Heat Waves (MHWs) (data collected between 2002 and 2018), warming anomalies were observed to decrease phytoplankton presence (Chiswell & Sutton, 2020). Being krill’s primary food source, this suggests a consequent decrease in krill health and reproduction. A recent study on blue whale reproductive patterns in the STB found that whale feeding activity decreased during MHWs, leading to a decline in their reproductive activity during the following breeding season (Barlow et al., 2020). Concurrently, the study observed that there were less krill aggregations and that they were less dense on average (Barlow et al., 2020). This is presumed to be a result of less upwelling nutrients, and therefore poor conditions for krill feeding and reproduction. These findings indicate that the absence of their primary food source, krill, during MHWs can lead to severely negative consequences for the blue whale populations (Barlow et al., 2023).

Anthropogenic activity in the STB, including high vessel traffic, as well as petroleum and mineral exploration and extraction activities, has also been identified as a threat to the local blue whale population (Torres et. al., 2013). Given the cultural significance of the blue whales in this region, there is an urgent need for improved, dynamic management practices in the STB that can be achieved using predictive models to forecast blue whale spatial distribution. Using environmental factors to inform predictive spatial distribution models (SDMs) of blue whales (Redfern et al. 2006, Elith & Leathwick 2009), Barlow et al. (2021) designed a blue whale forecasting tool for managers and decision-makers in New Zealand.

Given the ecological and cultural significance of blue whales and their krill prey in the STB, a Project SAPPHIRE (Synthesis of Acoustics, Physiology, Prey, and Habitat in a Rapidly changing Environment) was developed to examine the impacts of climate change on the health of these crucial species. The overarching goal of Project SAPPHIRE is to measure prey (krill) and predator (blue whales) response to environmental change off the coast of New Zealand. Despite forecasts of high probability of occurrence of blue whales in the STB during the first field season conducted in January-February 2024, both the blue whales and their krill prey were scarce, and it is currently unclear why. My research will focus on examining the calorie content of N. australis in order to advance understanding of how they fulfill the energetic needs of blue whales. Thus, this data can inform future SDMs to forecast impacts of climate change on New Zealand’s marine ecosystem.

Figure 3. Map of SAPPHIRE’s survey effort for 2024. Gray lines represent visual tracking, dotted lines represent aerial tracking. Red dots represent whale sightings and purple stars indicate where two hydrophones were deployed.

This project has already proven tricky – but I’m ready to embrace the challenge. I would like to thank the CEOAS REU program as well as my mentors Kim Bernard, Rachel Kaplan, and Abby Tomita for their continued support. I can’t wait to see what this summer brings!

References

Barlow DR, Klinck H, Ponirakis D, Branch TA, Torres LG. 2023. Environmental conditions and marine heatwaves influence blue whale foraging and reproductive effort. Ecol Evol. 2023;13:e9770.

Barlow D, Kim S. Bernard, Pablo Escobar-Flores, Daniel M. Palacios, Leigh G. 2020. Torres Links in the trophic chain: modeling functional relationships between in situ oceanography, krill, and blue whale distribution under different oceanographic regimes. Marine Ecology Progress Series.

Sutton, P.J.H., & Bowen, M. 2019. Ocean temperature change around New Zealand over the last 36 years. New Zealand Journal of Marine and Freshwater Research, 53(3), 305–326.

Sutton P.J.H., Bowen M, Roemmich D. 2005. Decadal temperature changes in the Tasman Sea. New Zealand Journal of Marine and Freshwater Research. 39:1321–1329.

Bowen M, Markham J, Sutton P, Zhang X, Wu Q, Shears N, Fernandez D. 2017. Interannual variability of sea surface temperatures in the Southwest Pacific and the role of ocean dynamics. Journal of Climate.

Stephen M. Chiswell & Philip J. H. Sutton. 2020. Relationships between long-term ocean warming, marine heat waves and primary production in the New Zealand region. New Zealand Journal of Marine and Freshwater Research.

A Summer of Crustacean Investigation

By Matoska Silva, OSU Department of Integrative Biology, CEOAS REU Program

My name is Matoska Silva, and I just finished my first year at Oregon State University studying biology with a focus in ecology. This summer will be my first experience with marine ecology, and I’m eager to dive right in. I’m super excited for the opportunity to research krill due to the huge impacts these tiny organisms have on their surrounding ecosystems. The two weeks I’ve spent in the CEOAS REU so far have been among the most fun and informative of my life, and I can’t wait to see what else the summer has in store for me.

Figure 1. Matoska presents his proposed research to the CEOAS REU program.

I’ve spent most of my life in Oregon, so I was thrilled to learn that my project would focus on krill distribution along the Oregon Coast that I know and love. More specifically, my project focuses on the Northern California Current (NCC, the current found along the Oregon Coast) and the ways that geographic distribution of krill corresponds to climatic conditions in the region. Here is a synopsis of the project:

The NCC system, which spans the west coast of North America from Cape Mendocino, California to southern British Columbia, is notable for seasonal upwelling, a process that brings cool, nutrient-rich water from the ocean depths to the surface. This process provides nutrients for a complex marine food web containing phytoplankton, zooplankton, fish, birds, and mammals (Checkley & Barth, 2009). Euphausiids, commonly known as krill, are among the most ecologically important zooplankton groups in the NCC, playing a vital role in the flow of nutrients through the food web (Evans et al., 2022). Euphausia pacifica and Thysanoessa spinifera are the predominant krill species in the NCC, with T. spinifera mainly inhabiting coastal waters and E. pacifica inhabiting a wider range offshore (Brinton, 1962). T. spinifera individuals are typically physically larger than E. pacifica and are generally a higher-energy food source for predators (Fisher et al., 2020). 

Temperature has been previously established as a major factor impacting krill abundance and distribution in the NCC (Phillips et al., 2022). Massive, ecosystem-wide changes in the NCC have been linked to extreme warming brought on by the 2014-2016 marine heatwave (Brodeur et al., 2019). Both dominant krill species have been shown to respond negatively to warming events in the NCC, with anomalous warm temperatures in 2014-2016 being linked to severe declines in E. pacifica biomass and with T. spinifera nearly disappearing from the Oregon Coast (Peterson et al., 2017). Changes in normal seasonal size variation and trends toward smaller size distributions in multiple age groups have been observed in E. pacifica in response to warming in northern California coastal waters (Robertson & Bjorkstedt, 2020). 

The El Niño-Southern Oscillation (ENSO) is a worldwide climatic pattern that has been linked to warming events and ecosystem disturbances in the California Current System (McGowan et al., 1998). El Niño events of both strong and weak intensity can result in changes in the NCC ecosystem (Fisher et al., 2015). Alterations in the typical zooplankton community accompanying warm water conditions and a decline in phytoplankton have been recorded in the NCC during weak and strong El Niño occurrences (Fisher et al., 2015). A strong El Niño event occurred in 2023 and 2024, with three-month Oceanic Niño Index means reaching above 1.90 from October 2023 to January 2024 (NOAA Climate Prediction Center, https://www.cpc.ncep.noaa.gov/data/indices/oni.ascii.txt).   

Figure 2. A graph of the ONI showing variability across two decades. Retrieved from NOAA at https://www.climate.gov/news-features/understanding-climate/climate-variability-oceanic-nino-index 

While patterns in krill responses to warming have been described from previous years,  the effects of the 2023-2024 El Niño on the spatial distribution of krill off the Oregon coast have not yet been established. As climate models have predicted that strong El Niño events may become more common due to greenhouse warming effects (Cai et al., 2014), continuing efforts to document zooplankton responses to El Niño conditions are vital for understanding how the NCC ecosystem responds to a changing climate. By investigating krill spatial distributions in April 2023, during a period of neutral ENSO conditions following a year of La Niña conditions, and April 2024, during the 2023-2024 El Niño event, we can assess how recent ENSO activity has impacted krill distributions in the NCC. In addition to broader measures of ENSO, we will examine records of localized sea surface temperatures (SST) and measurements of upwelling activity during April 2023 and 2024.

Understanding spatial distribution of krill aggregations is both ecologically and economically relevant, with implications for both marine conservation and management of commercial fisheries. Modeling patterns in the distribution of krill species and their predators has potential to inform marine management decisions to mitigate human impacts on marine mammals like whales (Rockwood et al., 2020). The data used to identify krill distribution were originally collected as part of the Marine Offshore Species Assessments to Inform Clean Energy (MOSAIC) project. The larger MOSAIC initiative centers around monitoring marine mammals and birds in areas identified for possible future development of offshore wind energy infrastructure. The findings of this study could aid in the conservation of krill consumers during the implementation of wind energy expansion projects. Changes in krill spatial distribution are also important for monitoring species that support commercial fisheries. Temperature has been shown to play a role in the overlap in distribution of NCC krill and Pacific hake (Merluccius productus), a commercially valuable fish species in Oregon waters (Phillips et al., 2023). The findings of my project could supplement existing commercial fish abundance surveys by providing ecological insights into factors driving changes in economically important fisheries.

Figure 3. The study area and transect design of the MOSAIC project, during which active acoustic data was collected (MOSAIC Project, https://mmi.oregonstate.edu/marine-mammals-offshore-wind). 

I’m very grateful for the chance to work on a project with such important implications for the future of our Oregon coast ecosystems. My project has a lot of room for additional investigation of climate variables, with limited time being the main constraint on which processes I can explore. There are also unique methodological challenges to address during the project, and I’m ready to do some experimentation to work out solutions. Wherever my project takes me, I know that I will have developed a diverse range of skills and knowledge of krill by the end of the summer.

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References

Brinton, E. (1962). The distribution of Pacific euphausiids. Bulletin of the Scripps Institution of Oceanography, 8(2), 51-270. https://escholarship.org/uc/item/6db5n157 

Brodeur, R. D., Auth, T. D., & Phillips, A. J. (2019). Major shifts in pelagic micronekton and macrozooplankton community structure in an upwelling ecosystem related to an unprecedented marine heatwave. Frontiers in Marine Science, 6. https://doi.org/10.3389/fmars.2019.00212 

Cai, W., Borlace, S., Lengaigne, M., van Rensch, P., Collins, M., Vecchi, G., Timmermann, A., Santoso, A., McPhaden, M. J., Wu, L., England, M. H., Wang, G., Guilyardi, E., & Jin, F. F. (2014). Increasing frequency of extreme El Niño events due to greenhouse warming. Nature Climate Change, 4, 111–116. https://doi.org/10.1038/nclimate2100 

Checkley, D. M., & Barth, J. A. (2009). Patterns and processes in the California Current System. Progress in Oceanography, 83, 49–64. https://doi.org/10.1016/j.pocean.2009.07.028 

Evans, R., Gauthier, S., & Robinson, C. L. K. (2022). Ecological considerations for species distribution modelling of euphausiids in the Northeast Pacific Ocean. Canadian Journal of Fisheries and Aquatic Sciences, 79, 518–532. https://doi.org/10.1139/cjfas-2020-0481 

Fisher, J. L., Peterson, W. T., & Rykaczewski, R. R. (2015). The impact of El Niño events on the pelagic food chain in the northern California Current. Global Change Biology, 21, 4401–4414. https://doi.org/10.1111/gcb.13054 

Fisher, J. L., Menkel, J., Copeman, L., Shaw, C. T., Feinberg, L. R., & Peterson, W. T. (2020). Comparison of condition metrics and lipid content between Euphausia pacifica and Thysanoessa spinifera in the Northern California Current, USA. Progress in Oceanography, 188, 102417. https://doi.org/10.1016/j.pocean.2020.102417

McGowan, J. A., Cayan, D. R., & Dorman, L. M. (1998). Climate-ocean variability and ecosystem response in the Northeast Pacific. Science, 281, 210–217. https://doi.org/10.1126/science.281.5374.210 

Phillips, E. M., Chu, D., Gauthier, S., Parker-Stetter, S. L., Shelton, A. O., & Thomas, R. E. (2022). Spatiotemporal variability of Euphausiids in the California Current Ecosystem: Insights from a recently developed time series. ICES Journal of Marine Science, 79,   1312–1326. https://doi.org/10.1093/icesjms/fsac055 

Phillips, E. M., Malick, M. J., Gauthier, S., Haltuch, M. A., Hunsicker, M. E., Parker‐Stetter, S. L., & Thomas, R. E. (2023). The influence of temperature on Pacific hake co‐occurrence with euphausiids in the California Current Ecosystem. Fisheries Oceanography, 32, 267–279. https://doi.org/10.1111/fog.12628

Peterson, W. T., Fisher, J. L., Strub, P. T., Du, X., Risien, C., Peterson, J., & Shaw, C. T. (2017). The pelagic ecosystem in the Northern California Current off Oregon during the 2014–2016 warm anomalies within the context of the past 20 years. Journal of Geophysical Research: Oceans, 122(9), 7267–7290. https://doi.org/10.1002/2017jc012952 

Robertson, R. R., & Bjorkstedt, E. P. (2020). Climate-driven variability in Euphausia pacificasize distributions off Northern California. Progress in Oceanography, 188, 102412.https://doi.org/10.1016/j.pocean.2020.102412