NOAA Teacher at Sea – Page 73 – NOAA Teacher at Sea Blog

September 15, 2018October 4, 2018

Mark Van Arsdale: What Makes Up an Ecosystem? Part III – Zooplankton, September 15, 2018

NOAA Teacher at Sea

Mark Van Arsdale

Aboard R/V Tiglax

September 11 – 26, 2018

Mission: Long Term Ecological Monitoring

Geographic Area of Cruise: North Gulf of Alaska

Date: September 15, 2018

Weather Data from the Bridge

Mostly cloudy, winds southerly 20 knots, waves to eight feet

57.56 N, 147.56 W (in transit from Gulf of Alaska Line to Kodiak Line)

Science Log

What Makes Up an Ecosystem? Part III Zooplankton

The North Gulf of Alaska Long-term Ecological Research Project collects zooplankton in several different ways. The CalVET Net is dropped vertically over the side of the boat to a depth of 100 meters and then retrieved. This net gives researchers a vertical profile of what is going on in the water column. The net has very fine mesh in order to collect very small plankton. Some of these samples are kept alive for later experiments. Others are preserved in ethanol for later genetic analysis. One of the scientists aboard is interested in the physiological details of what makes copepods thrive or not. Copepods are so important to the food webs of the Gulf of Alaska, that their success or failure can ultimately determines the success or failure of many other species in the ecosystem. When “the blob” hit the Gulf of Alaska in 2014-2016, thousands and thousands of sea birds died. During those same years, copepods were shown to be less successful in their growth and egg production.

Chief Scientist Russ Hopcroft prepping the Multi-net

The second net used to collect zooplankton is the Multi-net. We actually use two different Multi-nets. The first is set up to do a vertical profile. In the morning, it’s dropped vertically behind the boat. Four or five times a night, we tow the second Multi-net horizontally while the boat moves slowly forward at two knots. This allows us to collect a horizontal profile of plankton at specific depths. If the water depth is beyond 200 meters, we will lower the net to that depth and open the first net. The first net samples between 200 and 100 meters, above 100 meters we open the second net. As we go up each net is opened in decreasing depth increments, the last one being very close to the surface. Once the net is retrieved, we wash organisms down into the cod end, remove the cod end, and preserve the samples in glass jars with formalin. In a busy night, we may put away twenty-five pint-sized samples of preserved zooplankton. When those samples go back to Fairbanks they have to be hand-sorted by a technician to determine the numbers and relative mass of each species. We are talking hours and hours of time spend looking through a microscope. One night of work on the Tiglax may produce one month of work for technicians in the lab.

Underwater footage of a Multi-net triggering.

The last type of net we use is a Bongo net. Its steel frame looks like the frame of large bongo drums. Hanging down behind the frame is two fine mesh nets, approximately seven feet long terminating in a hard plastic sieve or cod end. Different lines use different nets based on the specific questions researchers have for that transect line or the technique used on previous years transects. To maintain a proper time series comparison from year to year, techniques and tools have to stay consistent.

I’ve spent a little bit of time under the microscope looking at some of the zooplankton samples we have brought in. They are amazingly diverse. The North Gulf of Alaska has two groups of zooplankton that can be found in the greatest abundance: copepods and euphausiids (krill.) These are food for most other animals in the North Gulf of Alaska. Fish, seabirds, and baleen whales all eat them. Beyond these two, I was able to observe the beating cilia of ctenophores and the graceful flight of pteropods or sea angels, the ghost-like arrow worms, giant-eyed amphipods, and dozens of others.

Deep sea squid, an example of a vertical migrator caught in our plankton trawls

By far my favorite zooplankton to watch under the microscope was the larvae of the goose neck barnacle. Most sessile marine organisms spend the early, larval stage of their lives swimming amongst the throngs of migrating zooplankton. Barnacles are arthropods, which are defined by their exoskeletons and segmented appendages. Most people would recognize barnacles encrusting the rocks of their favorite coastline, but when I show my students videos of barnacles feeding most are surprised to see the delicate feeding structures and graceful movements of this most durable intertidal creature. When submerged, barnacles open their shells and scratch at particles in the water with elongated combs that are really analogous to legs. The larva of the goose neck barnacle has profusely long feeding appendages and a particularly beautiful motion as it feeds.

We have to “fish” for zooplankton at night for two reasons. The first is logistical. Some work needs to get done at night when the winch is not being used by the CTD team. The second is biological. Most of the zooplankton in this system are vertical migrators. They rise each night to feed on phytoplankton near the surface and then descend back down to depth to avoid being seen in the daylight by their predators. This vertical migration was first discovered by sonar operators in World War II. While looking for German U-boats, it was observed that the ocean floor itself seemed to “rise up” each night. After the war, better techniques were developed to sample zooplankton, and scientists realized that the largest animal migration on Earth takes place each night and each morning over the entirety of the ocean basins.

One of my favorite videos on plankton.

Personal Log

The color of water

This far offshore, the water we are traveling through is almost perfectly clear, yet the color of the ocean seems continuously in flux. Today the sky turned gray and so did the ocean. As the waves come up, the texture of the ocean thickens and the diversity of reflection and refraction increases. Look three times in three directions, and you will see three hundred different shades of grey or blue. If the sun or clouds change slightly, so does the ocean.

The sea is anything but consistent. Rips or streaks of current can periodically be seen separating the ocean into distinct bodies. So far in our trip, calm afternoons have turned into windy and choppy evenings. Still, the crew tells me that by Gulf of Alaska standards, we are having amazing weather.

Variations in water texture created by currents in the Gulf of Alaska.

Did You Know?

The bodies of puffins are much better adapted to diving than flying. A puffin with a full belly doesn’t fly to get out of the way of the boat so much as butterfly across the surface of the water. Michael Phelps has nothing on a puffin flapping its way across the surface of the water.

Animals Seen Today

Fin and sperm whales in the distance
Storm Petrels, tufted puffins, Laysan and black-footed and short-tailed albatross, flesh footed shearwaters

September 14, 2018October 4, 2018

Mark Van Arsdale: What Makes Up an Ecosystem? Part II – Phytoplankton, September 14, 2018

NOAA Teacher at Sea

Mark Van Arsdale

Aboard R/V Tiglax

September 11 – 26, 2018

Mission: Long Term Ecological Monitoring

Geographic Area of Cruise: North Gulf of Alaska

Date: September 14, 2018

Weather Data from the Bridge

Mostly cloudy, winds variable 10 knots, waves to four feet

58.27 N, 148.07 W (Gulf of Alaska Line)

Science Log

What Makes Up an Ecosystem? Part II Phytoplankton

Most of my students know that the sun provides the foundational energy for almost all of Earth’s food webs. Yet many students will get stumped when I ask them, where does the mass of a tree comes from? The answer of course is carbon dioxide from the air, but I bet you already knew that.

Scientists use the term “primary productivity” to explain how trees, plants, and algae take in carbon dioxide and “fix it” into carbohydrates during the process of photosynthesis. Out here in the Gulf of Alaska, the primary producers are phytoplankton (primarily diatoms and dinoflagellates). When examining diatoms under a microscope, they look like tiny golden pillboxes, or perhaps Oreos if you are feeling hungry.

Primary productivity experiments running on the back deck of the Tiglax.

One of the teams of scientists on board is trying to measure the rates of primary productivity using captive phytoplankton and a homemade incubation chamber. They collect phytoplankton samples, store them in sealed containers, and then place them into the incubator. Within their sample jars, they inject a C₁₃ isotope. After the experiment has run its course, they will use vacuum filtration to separate the phytoplankton cells from the seawater. Once the phytoplankton cells are captured on filter paper they can measure the ratios of C₁₂to C_13. Almost all of the carbon available in the environment is C₁₂and can be distinguished from C₁₃. The ratios of C₁₂ to C₁₃ in the cells gives them a measurement of how much dissolved carbon is being “fixed” into sugars by phytoplankton. Apparently using C₁₄ would actually work better but C₁₄ is radioactive and the Tiglax is not equipped with the facilities to hand using a radioactive substance.

During the September survey, phytoplankton numbers are much lower than they are in the spring. The nutrients that they need to grow have largely been used up. Winter storms will mix the water and bring large amounts of nutrients back to the surface. When sunlight returns in April, all of the conditions necessary for phytoplankton growth will be present, and the North Gulf of Alaska will experience a phytoplankton bloom. It’s these phytoplankton blooms that create the foundation for the entire Gulf of Alaska ecosystem.

Personal Log

Interesting things to see

The night shift is not getting any easier. The cumulative effects of too little sleep are starting to catch up to me, and last night I found myself dosing off between plankton tows. The tows were more interesting though. Once we got past the edge of the continental shelf, the diversity of zooplankton species increased and we started to see lantern fish in each of the tows. Lantern fish spend their days below one thousand feet in the darkness of the mesopelagic and then migrate up each night to feed on zooplankton. The have a line of photophores (light producing cells) on their ventral sides. When they light them up, their bodies blend in to the faint light above, hiding their silhouette, making them functionally invisible.

A lantern fish with its bioluminescent photophores visible along its belly.

Once I am up in the morning, the most fun place to hang out on the Tiglax is the flying bridge. Almost fifty feet up and sitting on top of the wheelhouse, it has a cushioned bench, a wind block, and a killer view. This is where our bird and marine mammal observers work. Normally there is one U.S. Fish and Wildlife observer who works while the boat is transiting from one station to the next. On this trip, there is a second observer in training. The observers’ job is to use a very specific protocol to count and identify any sea bird or marine mammal seen along the transect lines.

Today we saw lots of albatross; mostly black-footed, but a few Laysan, and one short-tailed albatross that landed next to the boat while were casting the CTD. The short-tailed albatross was nearly extinct a few years ago, and today is still considered endangered. That bird was one of only 4000 of its species remaining. Albatross have an unfortunate tendency to follow long-line fishing boats. They try to grab the bait off of hooks and often are drowned as the hooks drag them to the bottom. Albatross are a wonder to watch as they glide effortlessly a few inches above the waves. They have narrow tapered wings that are comically long. When they land on the water, they fold their gangly wings back in a way that reminds me of a kid whose growth spurts hit long before their body knows what to do with all of that height. While flying, however, they are a picture of grace and efficiency. They glide effortlessly just a few inches above the water, scanning for an unsuspecting fish or squid. When some species of albatross fledge from their nesting grounds, they may not set foot on land again for seven years, when their own reproductive instincts drive them to land to look for a mate.

Our birders seem to appreciate anyone who shares their enthusiasm for birds and are very patient with all of my “What species is that?” questions. They have been seeing whales as well. Fin and sperm whales are common in this part of the gulf and they have seen both.

A Laysan Albatross, photo credit Dan Cushing

Did You Know?

Albatross, along with many other sea birds, have life spans comparable to humans. It’s not uncommon for them to live sixty or seventy years, and they don’t reach reproductive maturity until well into their teens.

Animals Seen Today

Fin and sperm whales
Storm Petrels, tufted puffins, Laysan and black-footed and short-tailed albatross, flesh footed shearwater

September 14, 2018September 14, 2018

Justin Garritt: I Came, We Fished, I Learned. . . 2 Amazing Weeks Aboard Shimada: September 14, 2018

NOAA Teacher at Sea
Justin Garritt
NOAA Ship Bell M. Shimada
September 1-14, 2018

Mission: End of Hake Research

Geographical area of cruise: Seattle, Washington to Newport, Oregon

Date: September 11-14, 2018: Day 11-14

Location: Off the coast of Newport, Oregon. End of research cruise.

IMG_E1260[1]

Throughout my life there have been moments when I recognize I am in the presence of something truly unique and special. Moments when I realize just how beautiful our planet can be. Moments I know will be engraved in my brain as life passes by. Hiking Zion National Park, night boat riding down the beautiful Saint Lawrence Seaway in the heart of the Thousands Islands, the view on top of Whiteface Ski Mountain, climbing the mountain islands in Greece, landing a helicopter on an Alaskan glacier, gigantic waves crashing in on an empty Puerto Rican beach with nothing but the moon in sight, taking a train ride up the gigantic Alps, and color of the fall leaves over the Castleton University skyline in Vermont are just a few of those moments I have been so privileged to have experienced in my short life. Monday evening, I got to add another new nature wonderland experience aboard the NOAA Bell M Shimada.

It was 5:15pm and I was eating a terrific dinner when one of the scientists came in the galley to tell us fishing was on hold because of the abundance of marine wildlife that was surrounding our ship. I immediately ran upstairs to check it out. When I stepped in the bridge (command room of the ship) the first thing I noticed was the beautiful blue skies with a touch of clouds and the sun that set the stage for the spectacle. My ears rang with the crashing waves against the boat and seagulls squawking in the background. As I looked over the side of the boat there were two pairs of dolphins synchronized swimming all around the ship. After a few minutes, three California sea lions came floating by on their backs waving at the passing ship. Another minute later, the dolphins came back for their encore followed by a spray of a Humpback whale spouting directly behind it. As the whale came closer it swam gracefully in an up and down pattern until it bent its massive dinosaur-like body down followed by its tail flipping over as it took a deep dive below the surface. As soon as the whale took the dive another pair of sea lions came floating by smiling as they took in the heat of the sun. Before I could look again, a Pelagic Cormorant landed directly in front of me on the ship. Right after I took a picture of that I looked up and saw at least fifteen spouts surrounding the ship like a spectator would see at the Bellagio Hotel light show in Las Vegas. For the next hour whale after whale surfaced, spouted, and even breached behind the beautiful blue sky backdrop. No matter where I looked I was seeing whales grace our presence. No camera could capture the magic of that hour as I ran from side to side on the viewing tower above the bridge to soak in as much of this experience as possible. I was in awe at the majesty of the sea creatures. As the ship made its way through the evening and to sunset, the whales slowly trickled off beyond sight as the sun came down in the background. Hope that future generations can experience this beauty for centuries to come.

This slideshow requires JavaScript.

The reality is the ever growing world’s population consumes large amounts of fish. The Food and Agriculture Organization of the United Nations states that in 2016, the global seafood trade was worth $140 billion. In the US it is estimated that 1.5 million people are employed by the fishing industry. That is a lot of communities and families that rely on the resources in our water systems. Throughout the week I learned that so much of the work of NOAA is not limiting the growth and catch of our fishermen/fisherwomen, but it is to ensure there is a fish population to catch and future generations can experience what I was able to experience these past two weeks. Part of NOAA’s mission is to conserve and manage coastal and marine ecosystems and resources. Having the most high tech equipment constantly being researched to seek improvements mixed with “ground truthing (catching and surveying)” to analyze different species is crucial for the future of the world’s fisheries.

Two weeks ago I wrote about the main goals for this research cruise. The first was to gather data to study the impact of the US 32mm net liners and the CANADIAN 7mm net liners. The second was to compare the old acoustic equipment called the EK60 with the new equipment called the EK80. Throughout the last two legs of the trip, scientists have gathered data and will be working on analyzing it over the coming months to make better conclusions on these goals. The vision is for someday to reduce the number of surveying trawls needed to determine the population of fish, and instead, use this highly advanced acoustics equipment instead. If those ships are filled with as curious, hardworking, and focused people as the people I met on this ship, I am confident we will be able to obtain this goal in the future.

Here are some pictures from the final 3 days of fishing and exploring the ship:

Hake are present. . . it’s go time!

Another pile of krill (the hake eat these)

Jellyfish

Holding a Big Squid

Sturgeon poacher

Myctophids

Rockfish being caught in the net onscreen

A large catch of hake

A Big Squid

Scientists analyzing the Big Squid

Super Chu

Myctophid x-ray

Spiny dogfish shark

A Big Squid

Spiny dogfish shark

Bringing my experience back to the classroom:

Throughout the past two weeks I constantly thought about how I can bring my experience back to my students in Baltimore. My students receive half the amount of hours of science instructional time than math and reading. After much reflection I decided to use the same core standards we are obligated to teach but begin rewriting most of the 6th grade statistics unit. At the start of the unit I will begin with the purpose of NOAA, pictures of my trip, and exciting stories from my adventure. From there I will have investment in the subject from my students which will allow me to dive in to applying data collected at sea to find: mean, mode, range, variability, mean absolute deviation (MAD), and interquartile range (IQR). We will also be able to use real live data to create histograms, frequency tables, box and whisker plots, and dot plots. I believe it will be exciting for them to have the opportunity to apply required statistical concepts to learning how NOAA (along with others) survey our fish population so species will survive for generations to come. It will also make our school’s 6th grade teacher, Mr. Davis, very happy!

My view while lesson planning

rfgfg — An example of my change in classroom instructional materials to teach Box Plots with data from the research cruise.

At any given moment, there are thousands of NOAA employees studying our environment across the globe. I had the honor of sailing with incredibly intelligent and hardworking people who are dedicated to the mission. From them, I learned so many valuable things that I will carry with me as I disembark on Friday.

Chief Scientist, Rebecca Thomas was an excellent manager/role model. She taught me that leading through kindness, support, trusting others, and giving people rest will produce better and more accurate results than pushing people past their limitation.

Chief Scientist Rebecca Thomas

Scientist Steve de Bluis encouraged me to maintain a hobby outside of work that you love. Steve loves to fly planes and dive and talked about these trips all the time. You can tell how much joy it has brought him and how excited he is to continue to dive well into his retirement in a few years. He was also a BEAST in the wet lab!

Roommate and Future Scientist Charlie Donahue taught me the importance of accuracy over speed. He constantly pushed me to be sure the data we were collecting was as accurate as possible. He never let speed and efficiency take away from quality. For those of you who know me, this is certainly an important push for me!

Scientist John Pohl taught me about supporting newcomers. He was the first guy I met aboard and always spent time breaking down complicated science topics for me.

IMG_1086[1] — Scientist John Pohl analyzes the depth of the net vs. the acoustic picture on his screen

Scientist Melanie Johnson taught me about working through chaos with calmness. She has been on both commercial and scientific ships and constantly kept calm during any situation that arose.

Scientist Dezhang Chu (Super Chu) taught me about focus. No matter what was going on “Super Chu” always kept a clear view of his own goals and purpose aboard and stayed focused on the prize. Chu was also super hard working and was in the acoustics lab at 6:30am when I went to the gym and still in on his computer analyzing data from the day when I returned from yoga at 10pm. I think he could even give KIPP Ujima Resident-Principal Reese a run for it in terms of work ethic!

Super Chu and I

Super Chu

Volunteer Scientist Heather Rippman taught me about service and life-long learning. Heather commits herself to volunteering for important science missions across the country. After leaving an executive position with Nike, she now travels and volunteers to learn all she can about marine science and give back to the marine science community. She shared so much knowledge with me and was the first person to teach me how to dissect hake.

Master Chef Arnold Dones reminded me about the power of food bringing people together. At exactly 7am, 11am, and 5pm, roughly 40 people from all over the country with all types of jobs aboard came together to feast. Arnold made that happen because of the pride he takes in his craft.

Chef Arnold

Chief Engineer Sabrina Taraboletti spent 3 hours with me on our last day to show me the massive engine room. She explained what every piece of equipment does below deck. I learned the science behind creating freshwater from sea water. I learned the regulations behind sewer and contaminants. The best part was climbing to the bottom of the ship and watching the shaft that makes the propeller turn move. Her team of engineers barely see daylight and work long hours to make sure the ship moves safely and all the amenities and scientific research equipment works flawlessly. She keeps the morale of her team high, keeps an impressively organized work space that is approximately the size of over a dozen typical garages, and is one of the most knowledgeable professionals I ever crossed paths with.

Sabrina teaching me about controlling the generators for the engines

The 2nd of 4 generators

Heather and I in the engine room

How to apply for the Teacher At Sea Program:

Ms. Ellmauer is a 25 year veteran science teacher from my hometown of Liberty, NY. She was also my high school ski coach. She has been following my blog and reached out about information on how to apply. I am humbled to see so many teachers and school officials reading my blog from across the country so I thought I would pass on the website with information about the program and how to apply for this once in a lifetime experience. Please reach out to me at JAGarritt@gmail.com if you have any questions.

https://teacheratsea.noaa.gov/#/home/

Tomorrow we pull in to Newport, Oregon, and the research cruise will come to an end. Thank you to the nearly one-thousand readers who have been following my journey. I am grateful for your support.

Good bye for now, until I hopefully sail again a part of the NOAA Teacher At Sea Alumni Program,

Justin

September 13, 2018October 4, 2018

Mark Van Arsdale: What Makes Up an Ecosystem? Part I – Chemistry, September 13, 2018

NOAA Teacher at Sea

Mark Van Arsdale

Aboard R/V Tiglax

September 11 – 26, 2018

Mission: Long Term Ecological Monitoring

Geographic Area of Cruise: North Gulf of Alaska

Date: September 13, 2018

Weather Data from the Bridge

Clear skies, variable winds, swell 4-6 ft

59.58 N, 148.38 W (Gulf of Alaska Line)

Science Log

What Makes Up an Ecosystem? Part I Chemistry

CTD (water chemistry) data visualized along the Gulf of Alaska Line.

The scientists aboard this ship are trying to understand the working parts of the North Gulf of Alaska ecosystem. Since Descartes, the western approach to science has required that the understanding of complex systems begin with the reduction of a system it to its simpler working parts. For example, to understand the clock, you must take it apart and try to understand the mechanism of each piece separately. The Gulf of Alaska is huge, and its ecosystem is both highly complex and highly variable. Changes take place because of weather, season, and climactic regime. Nonetheless, the first step to understanding it is to understand its chemistry.

The CTD gets dropped or “cast” at each station. On this boat, that means four people shoving it out the back door while trying not to fall out themselves. There is more than $100,000 worth of equipment attached to the CTD Rosette and there is a moment in each cast where the CTD swings precariously before the winch lowers it down into the water. When the CTD comes back up, all of that data is run through a computer and it paints a picture of what conditions are like at depth.

Inside the "van" where water samples are processed for trace medals — Inside the “van” where water samples are processed for trace medals

CTD stands for conductivity, temperature, depth. In reality, it tests for those things plus salinity, dissolved oxygen, nitrates, pressure, and florescence (which is a measurement of the chlorophyll in phytoplankton). The CTD also has a camera onboard that takes gray-scale images of particles and plankton in the water column as it goes down. Most of our CTD “casts” are showing a water column that is highly stratified, with a surface layer that is relative warm (34^o Celsius), lower salinity, and a chlorophyll maximum around twenty meters. The CTD shows a thermocline (rapid change in temperature) around fifty meters. Below that, the water is colder and has a higher salinity, both of which results in water with a higher density. The density differences between these two layers make it so that they don’t easily mix. The stratification effect had been intensified by the recent stretch of sunny weather and light winds. Stratification by density “traps” phytoplankton at the surface in waters ideal for photosynthesis except that in September, the availability of nutrients needed for growth is quite low. Nitrates, nitrites, and silica have been used up by growing phytoplankton earlier in the summer and their absence now limits growth.

Catch from a Multi-net, mostly small euphausiids (krill)

We have scientists on board measuring the surface waters for trace metals – iron in particular. It’s a common joke on board that the smaller the subject you study, the greater the equipment needs. Whale watchers just need binoculars but the chemists have their own lab set up inside a twenty-foot shipping container or “van” strapped to the top deck. The metals team drags a missile shaped device along the side of the boat known as an “iron fish.” The iron fish, is connected to a long plastic tube and pump that provides them a constant stream of surface water. Samples are continuously collected and frozen for later analysis back in Fairbanks. Months of work will be required to process all of the samples collected on this trip.

Our plankton catches were much less variable last night. The Multi-net caught almost exclusively small euphausiids (krill.) The Methot net caught four kinds of jellies, including one moon jelly that the jelly expert was very excited about – perhaps a species not described in Alaska before. The Methot net also caught a lot of small fishes swimming at the surface. One of which was the three-spine stickleback. This was exciting for me because the three-spine stickleback is a species we use in my AP Biology class as an easy to understand and highly local example of natural selection. The three-spine stickleback is a small fish, around 1 inch in size, found in both fresh and saltwater. In saltwater, they have three large spines that discourage predators from eating them. Out here in the ocean, the spines give the fish a selective advantage. During the last ice age, some sticklebacks were trapped in fresh water ponds and lakes in South Central Alaska. There, they underwent a change. The spines which were such a great defense in the ocean were a disadvantage to them in freshwater. Aggressive dragonfly larva use the spines like handles to grab the small fish and eat them. Over time there was a selective advantage to have smaller spines, and today freshwater sticklebacks have greatly reduced pelvic spines as compared to their saltwater cousins. Natural selection did not design a better fish, it simply picked which variants were more likely to survive and reproduce in its environment.

Personal Log

Cetacean acoustic recording buoy recovered by the Tiglax.

My second night shift was not any easier, but it was more pleasant. Just before sunset, we took a slight detour from our transect line to recovery a buoy for a scientist from Scripps Institution of Oceanography. An acoustic recorder, designed to count whales by their unique calls, it had been deployed a year earlier in 900 meters of water. The crew had onboard a device that would talk to the buoy and signal it to release from its mooring. It took about a half an hour, but eventually there we saw it bobbing at the surface. Luckily the seas were pretty calm, and we were able to pull it through the side door.

The seas and weather continue to be excellent. Last night we were treated to a display of the aurora around 3:30 AM. It was so calm and so quiet that at one point, we could hear whales breathing around us. Both served as distractions to the routine of net deployment, net retrieval, sample containment, repeat.

As we traveled the ten nautical miles between stations, the flood lights on the front deck were turned off and I would sit down to watch the stars. To ancient mariners, the clear night sky was a map that could direct you across an ocean. It made me think of the Polynesian navigators tracking their small canoes across the Pacific. It also made me think about Ptolemy, who thought the Earth was encased in a perfect glass sphere with stars painted along its interior. I could see how you would think of such a sky as art.

Did You Know?

Did you know the Earth is round? It seems silly to have to say, but as a science teacher, the battle against the fantasies and fallacies of the Internet are never ending. Last year was the first year in twenty-one years of teaching that I was challenged by a student to prove to him that the Earth is round, and it happened twice. So here goes. On a boat in the Gulf of Alaska on a clear day, you know the Earth is round because as you move slowly away from the mountains, they disappear from the bottom up. By the end of the day we had traveled far enough from shore that we saw just the snow-covered tips of mountain peaks.

Sunset, it must be time to go to work. — Sunset with the mountains receding in the background, it must be time to go to work.

Animals Seen Today

Dall porpoise
Lots of seabirds including black-footed and Laysan albatross, sooty shearwater, puffins and fulmars.

September 13, 2018

Ashley Cosme: Special Situation Lights, September 11, 2018

NOAA Teacher at Sea

Ashley Cosme

Aboard NOAA Ship Oregon II

August 31 – September 14, 2018

Mission: Shark/Red Snapper Longline Survey

Geographic Area of Cruise: Gulf of Mexico

Date: September 11, 2018

Weather data from the Bridge:

Latitude: 28 40.5N
Longitude: 91 08.5W
Wind speed: 22 Knots
Wind direction: 080 (East)
Sky cover: Scattered
Visibility: 10 miles
Barometric pressure: 1014.5 atm
Sea wave height: 3-4 feet
Sea Water Temp: 29.9°C
Dry Bulb: 25.9°C
Wet Blub: 24.6°C

Science and Technology:

When NOAA Corps officers go through training they learn a poem to help them remember how to identify Special Situation Lights on other vessels.

Red over green, sailing machine.

Red over white, fishing boat in sight.

Green over white, trawling at night.

White over red, pilot ahead.

Red over red, captain is dead.

The mast of the Oregon II is identified by the arrow.

When driving a vessel like the Oregon II it is always important to have the ability to analyze the radar, locate other vessels in the water, and determine their current situation by reading their mast lights. Line 1 of the poem describes a vessel that is currently sailing by use of wind without the use of an engine, line 2 describes a boat engaged in fishing operations, line 3 indicates that the vessel is currently trawling a net behind the boat, line 4 indicates that the vessel is a pilot boat (a boat containing a pilot, who helps guide larger tanker and cargo ships into harbors), and line 5 of the poem is used for a situation when the vessel is not operating properly and other vessels should steer clear.

Personal Log:

There are currently three named storms in the Atlantic, including a category 4 hurricane (Florence) that is headed towards the Carolinas. I have never experienced a bad storm while out on the water. The waves the last 24 hours have ranged from 3-5 feet, with an occasional 8 foot wave. We have changed our port call location and will now be going back to Pascagoula, Mississippi instead of Galveston, Texas. There was also no internet for part of the day so my team and I sat in the dry lab and told ghost stories. I was also introduced to the “dinosaur game” in Google Chrome, which is sort of like a low budget Mario. Apparently it is the dinosaur’s birthday so he is wearing a birthday hat.

I am still making the most of every minute that I am out here. Our last haulback was very active with many large blacktip sharks. It is a workout trying to handle the sharks on deck, while collecting all required data, and getting them back in the water as fast as possible. I am loving every second!

Did you know:

Sharks possess dermal denticles (skin teeth) that makes their skin feel rough when running your hand tail to nose. Shark skin used to be used as sandpaper before it was commercially manufactured. It can also give you shark burn, which is sort of like a rug burn, if the shark brushes up against you.

Animals Seen:

Atlantic Sharpnose Shark (Rhizoprionodon terraenovae)

Blacknose Shark (Carcharhinus acronotus)

Blacktip Shark (Carcharhinus limbatus)

Flying Fish (Exocoetus peruvianus)

Gafftopsail Catfish (Bagre marinus)

Pantropical Spotted Dolphin (Stenella attenuate)

Red Snapper (Lutjanus campechanus)

Spinner Shark (Carcharhinus brevipinna)

Tiger Shark (Galeocerdo cuvier)