Tag: squid

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Kathryn Lanouette, August 1, 2009

NOAA Teacher at Sea
Kathryn Lanouette
Onboard NOAA Ship Oscar Dyson
July 21-August 7, 2009 

Mission: Summer Pollock Survey
Geographical area of cruise: Bering Sea, Alaska
Date: August 1, 2009

This sonar-generated image shows walleye pollock close to the sea floor. The red line at the bottom of the image is the sea floor. The blue specks at the top of the image are jellyfish floating close to the water’s surface.
This sonar-generated image shows walleye pollock close to the sea floor. The red line at the bottom of the image is the sea floor. The blue specks at the top of the image are jellyfish floating close to the water’s surface.

Weather Data from the Ship’s Bridge 
Visibility: 10+ nautical miles
Wind direction: variable
Wind speed:  less than 5 knots, light
Sea wave height: 0 feet
Air temperature: 7.9˚C
Seawater temperature: 8.6˚C
Sea level pressure: 30.1 inches Hg
Cloud cover: 7/8, stratus

Science and Technology Log 

In addition to the Aleutian wing trawl (which I explained in Day 5 NOAA ship log) and Methot (which I explained in Day 8 NOAA ship log), scientists also use a net called an 83-112 for bottom trawls. The 83-112 net is strong enough to drag along the sea floor, enabling it to catch a lot of the animals that live in, on, or near the sea floor. This afternoon, we conducted the first bottom trawl of our cruise. Bottom trawls are usually conducted in two situations: if the walleye pollock are too close to the sea floor to use an Aleutian wing trawl or if the scientists want to sample a small amount of fish (because the 83-112’s net opening is smaller than the Aleutian wing trawl’s net). From the looks of the sonar-generated images, it appeared that most of the walleye pollock were swimming very close to the bottom so the scientists decided it would be best to use the 83-112 net.

Here I am holding one of the skates that was caught in the bottom trawl
Here I am holding one of the skates that was caught in the bottom trawl

Once the fish were spotted, we changed our course to get ready to trawl. Usually the trawl is made into the wind for stability and net control. Once the ship reached trawling speed, the lead fisherman was given the “OK” to shoot the doors. Slowly, the net was lowered to 186 meters below the surface, the sea depth where we happened to be. The water temperature down there was about 1˚C (compared to 7˚C on the sea’s surface).  I had heard from a previous Teacher At Sea that bottom trawls brought up a wide variety of animal species (compared to the relatively homogenous catches in mid-water trawls). And sure enough, when the net was brought up, I couldn’t believe my eyes!

All told, we sorted through over 7,000 animals, a total of 36 different species represented in the total catch. It took 4 of us over 4 hours to sort, measure, and weigh all these animals. There were over 350 walleye pollock in this catch as well as skates, octopi, crabs, snails, arrowtooth flounder, sea anemones, star fish, and dozens of other animals. Some of them were even walking themselves down the table.

During this catch, I also learned how to take the ear bones, or otoliths, out of a walleye pollock. Why ear bones you might ask? Using the ear bones from a walleye pollock, scientists are able to determine the exact age of the fish. Misha Stepanenko, one of the two Russian scientists on board the Oscar Dyson, showed me how to cut partially through the fish’s skull and take out two large ear bones. Once they were taken out, I put them in a solution to preserve them. Back in NOAA’s Seattle lab, the ear bones are stained, enabling scientists to count the different layers in each ear bone. For every year that the fish lives, a new layer of bone grows, similar to how trees add a layer for each year that they live. By learning the exact age of a fish, scientists are able to track age groups (called “cohorts”), allowing more precise modeling of the walleye pollock population life cycle.

A diagram of an otolith, or ear bone, of a fish. You can see that it’s a lot like looking at tree rings!
A diagram of an otolith, or ear bone, of a fish. You can see that it’s a lot like looking at tree rings!

Personal Log 

So far this trip, we have sailed within 15 miles of Cape Navarin (Russia) on at least two different occasions but fog and clouds prevented any glimpse of land both times. It was a frustrating feeling knowing that land was so close, yet impossible to see. After 12 days of looking at nothing but water and sky, seeing land would have been a welcome treat.

Despite not seeing land, I still felt like I was in Russia just from listening to different fishing vessels communicate with one another. On our first night in Russian waters, we sailed through a heavy fog, with 7 or 8 different boats fishing nearby. I was impressed with how Ensign Faith Opatrny, the Officer on Deck at the time, communicated with various vessels, using collision regulations (“the rules of the road”) to navigate safely. On a culinary note, I got my first chance to eat some of a catch. After most trawls, we discard remaining inedible specimens overboard. After our bottom trawl however, one of the scientists filleted some of the cod. The next day, the stewards cooked it up for lunch. It tasted great and it felt good to be eating some of the fish that we sampled.

A graph showing the adult walleye pollock biomass estimates from 1965 to 2008.
A graph showing the adult walleye pollock biomass estimates from 1965 to 2008.

As the cruise starts to wind down, I also want to express my gratitude to all the NOAA scientists and Oscar Dyson crew. Everyone in the science group took time to explain their research, teach me scientific techniques, and answer my many questions. On numerous occasions, the deck crew explained the mechanics of fishing nets as well as the fishing process. The engineering crew gave me a tour of the engine rooms, describing how four diesel engines power the entire boat. The survey techs explained how different equipment is operated as well as the information it relays back to the scientists. The NOAA Corps officers showed me how to read weather maps, take coordinates, and explained ship navigation. The ship’s stewards described the art and science behind feeding 33 people at sea. And the USFWS bird observers patiently showed me how to identify numerous bird species. From each of them, I learned a tremendous amount about fisheries science, fishing, boats, sailing, birding, and life in the Bering Sea. Thank you!

Answer to July 28 (Tuesday) Log: How has the walleye pollock biomass changed over time? 
In the past few years, the walleye pollock biomass has decreased (according to the acoustic-trawl survey, the survey that I joined.) It should be noted that there is a second complementary walleye pollock survey, the eastern Bering Sea bottom trawl survey. This survey studies walleye pollock living close to the sea floor. As walleye pollock age, they tend to live closer to the sea floor, thus the bottom trawl survey sometimes shows different biomass trends than the acoustic-trawl survey. Both surveys are used together to manage the walleye pollock stock.

An up-close look at one of the squid’s tentacles
An up-close look at one of the squid’s tentacles

Animals Seen 
Auklet, Arrowtooth flounder, Basket star, Bering skate, Cod, Hermit crab, Fin whale, Fur seal, Octopus, Sculpin, Sea mouse, Sea slug, Shortfin eelpout, Snow crab, Squid, and Tanner crab.

New Vocabulary: Bottom trawl – fishing conducted on and near the bottom of the sea floor. Catch – fish brought up in a net. Shoot the doors – a fishing expression that means to lower the 2 metal panels that hold open the fishing nets in the water. Stewards – the name for cooks on a ship. Table – nickname for the conveyor belt where the fish are sorted for sampling. Vessels – another word for ships. 

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Jennifer Fry, July 22, 2009

NOAA Teacher at Sea
Jennifer Fry
Onboard NOAA Ship Miller Freeman (tracker)
July 14 – 29, 2009 

Mission: 2009 United States/Canada Pacific Hake Acoustic Survey
Geographical area of cruise: North Pacific Ocean from Monterey, CA to British Columbia, CA.
Date: July 22, 2009

Weather Data from the Bridge 
Wind speed: 13 knots
Wind direction: 003°from the north
Visibility: clear
Temperature: 13.6°C (dry bulb); 13.2°C (wet bulb)
Sea water temperature: 15.1°C
Wave height: 1-2 ft.
Swell direction: 325°
Swell height: 4-6 ft.

Science/Technology Log 

Today we did a fishing trawl off the coast of Oregon. First, the scientists used multiple acoustic frequencies of sound waves.  After analyzing the sonar data, the scientists felt confident that they would get a good sampling of hake. The chief scientist called the bridge to break our transect line (the planned east/west course) and requested that we trawl for fish.

Here is an acoustic image (2 frequencies) as seen on the scientist’s screen. The bottom wavy line is the seafloor, and the colored sections above are organisms located in the water column.
Here is an acoustic image (2 frequencies) as seen on the scientist’s screen. The bottom wavy line is the seafloor, and the colored sections above are organisms located in the water column.

The NOAA Corps officers directed operations from the trawl house while crew members worked to lower the net to the target depth.  The fishing trawl collected specimens for approximately 20 minutes. After that time, the crew members haul in the net. The scientists continue to record data on the trawl house.

The trawl net sits on the deck of the Miller Freeman and is ready to be weighed and measured.
The trawl net sits on the deck of the Miller Freeman and is ready to be weighed and measured.

Today’s total catch fit into 2 baskets, a “basket” is about the size of your laundry basket at home, approximately 25-35 kilos. Included in the sample were some very interesting fish:

  • Viper fish
  • Ctenophores or comb jellies
  • Larval stage Dover sole, lives at the sea bottom
  • Jelly fish, several varieties (*Note: Jelly fish are types of zooplankton, which means they are animals floating in the ocean.)
  • Hake, approx. 30 kilos

The scientists made quick work of weighing and identifying each species of fish and then began working with the hake. Each hake was individually measured for length and weighed.  The hake’s stomach and otolith were removed. These were carefully labeled and data imputed into the computer.  Scientists will later examine the contents of the stomach to determine what the hake are eating. The otolith (ear bone) goes through a process by which the ear bone is broken in half and then “burnt.” The burning procedure allows one to see the “age rings” much like how we age a tree with its rings.

Personal Log 

A view from the trawl house during a fishing trawl.
A view from the trawl house during a fishing trawl.

Everyone works so very hard to make the Hake Survey successful.  All hands on the ship do a specific job, from cook to engineer to captain of the ship.  It is evident that everyone takes their job seriously and is good at what they do. I feel very fortunate to be part of this very important scientific research project.

 

 

A viper fish
A viper fish

Did You Know? 
Bird facts: An albatross’ wing span can be 5 feet, which equals one very large sea bird. A shearwater is slimmer and smaller yet resembles an albatross.

Animals Seen Today 
Ctenophore, Jelly Fish, Dover sole, Hake, Humboldt squid, Fulmar, Albatross, Gull, and Shearwater.

Here is something interesting, a hake with two mouths discovered in the trawl net.
Here is something interesting, a hake with two mouths discovered in the trawl net.
A hake and its stomach contents, including krill, smaller hake and possibly an anchovy
A hake and its stomach contents, including krill, smaller hake and possibly an anchovy
Dover Sole, larval stage
Dover Sole, larval stage†
NOAA Oceanographer John Pohl and NOAA Fish Biologist Melanie Johnson discuss data about the fish collected.
NOAA Oceanographer John Pohl and NOAA Fish Biologist Melanie Johnson discuss data about the fish collected.
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Jennifer Fry, July 21, 2009

NOAA Teacher at Sea
Jennifer Fry
Onboard NOAA Ship Miller Freeman (tracker)
July 14 – 29, 2009 

Mission: 2009 United States/Canada Pacific Hake Acoustic Survey
Geographical area of cruise: North Pacific Ocean from Monterey, CA to British Columbia, CA.
Date: July 21, 2009

Boatswain Matt Faber, and Skilled Fisherman, Gary Cooper, tend to full net of hake from one of the day’s trawl.
Boatswain Matt Faber, and Skilled Fisherman, Gary Cooper, tend to full net of hake from one of the day’s trawl.

Weather Data from the Bridge 
Wind speed: 10 knots
Wind direction: 011°from the north
Visibility: cloudy
Temperature: 16.2°C (dry bulb); 14.9°C (wet bulb)
Weather note: When you speak of wind direction you are talking about the direction in which the wind is coming. 

Science/Technology Log 

You can see by the weather data above that the seas were much calmer today. We were able to conduct 3 fishing trawls amounting to several thousand kilograms of hake. Once the fish were hauled onto the deck, we began measuring, weighing, dissecting, and removing otoliths, ear bones, for age analysis. I removed my first pair of otoliths today.  The best part of the day was the last and final trawl. We collected approximately 3,000 pounds of Humboldt squid which equals 444 squid.  The math problem to calculate is… “How much would one squid weigh in our catch?”

Julia Clemons, NOAA Fisheries and Jennifer Fry, TAS pictured with Humbolt squid. Today’s catch totaled 444 squid.
Julia Clemons, NOAA Fisheries and Jennifer Fry, TAS pictured with Humbolt squid. Today’s catch totaled 444 squid.

Personal Log 

What strikes me today is just how dedicated the scientists and crew are to their jobs.  Everyone has a specific job aboard the Miller Freeman that they take seriously.

Question of the Day 

Can you use squid ink as you do regular ink? Is there a market for squid inked products such as cards?

New Term/Phrase/Word 

Cusk eel

Animals Seen Today 

Fish:  Humbolt squid, Hake, Iridescent Cusk eel (see photo), Myctophid
Birds:  Shearwaters, Albatross, Gulls

The Squid 
The squid come on little tentacled feet
Falling, splatting, rolling, and sliding out of its netted jail.
Free at last
To be weighed and measured
Sitting on a strong mantle in a flowing liquid of ebony and midnight.
Your silent escape goes unnoticed.

The Clouds 
The clouds slither on little squid tentacles
The midnight inky darkness envelopes the sky and warns us of foreboding
It sits looking over ships and sea lions
Its silent mantle quietly slides away.

(Inspired by Carl Sandberg’s “The Fog”)

The squid were examined, weighed, and the data entered into the data base.
The squid were examined, weighed, and the data entered into the data base.
A cusk eel
A cusk eel
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Jennifer Fry, July 18, 2009

NOAA Teacher at Sea
Jennifer Fry
Onboard NOAA Ship Miller Freeman (tracker)
July 14 – 29, 2009 

Mission: 2009 United States/Canada Pacific Hake Acoustic Survey
Geographical area of cruise: North Pacific Ocean from Monterey, CA to British Columbia, CA.
Date: July 18, 2009

Weather Data from the Bridge 
Wind speed: 40 knots
Wind direction: 350°from the north
Visibility: foggy Temperature: 12.9°C (dry bulb); 12.0°C (wet bulb)
Wave height: 8-10 feet

Science and Technology Log 

Lisa Bonacci, chief scientist and Melanie Johnson, fishery biologist in the Freeman’s acoustics lab
Lisa Bonacci, chief scientist and Melanie Johnson, fishery biologist in the Freeman’s acoustics lab

Acoustics: Lisa Bonacci, chief scientist, and Melanie Johnson, fishery biologist, are in the acoustics lab onboard the Miller Freeman as it travels along a transect line. NOAA scientists can detect a variety of marine life under the sea. They use sonar—sound waves bouncing off an object—to detect the animals. There is an onboard sonar system that puts out four different frequencies of sound waves.  Each type of fish will give off a different signal depending on its size, shape, and anatomy.  The fish are then identified on the sonar computer readout.  The strength of the sonar signal will determine the number of hake and the way that they are swimming.  As soon as it appears on the sonar as if hake are present, Ms. Bonacci then calls the bridge to request that we trawl for fish.

This is the sonar readout as it’s seen on the computer screen.
This is the sonar readout as it’s seen on the computer screen.

Personal Log 

The boat was rocking in all directions with 40 knot winds and 8-10 foot waves. The fishing trawl brought up scores of fish including a lot of hake. The sonar signals worked really well to locate them. We dissected and measured many fish, but not before we sat in a giant vat of hake (see photo.)  It was a great learning day.

Animals Seen Today 
Hake,spiny dogfish, Humbolt squid, Myctophidae, and Birds.

Here we are in a giant vat of hake!
Here we are in a giant vat of hake!

Discovery from the Briny 
As the trawl net was raised from the depths
The sun broke through the clouds revealing a sparkling azure sky.
Scores of seagulls circled the stern
In the hopes of a bountiful offering
Tasty morsels from the deep
Soon to be thrown overboard.

American fishery biologist, Melanie Johnson, and Canadian fishery biologist, Chris Grandin, take biological samples.
American fishery biologist, Melanie Johnson, and Canadian fishery biologist, Chris Grandin, take biological samples.
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Jennifer Fry, July 16, 2009

NOAA Teacher at Sea
Jennifer Fry
Onboard NOAA Ship Miller Freeman (tracker)
July 14 – 29, 2009 

Mission: 2009 United States/Canada Pacific Hake Acoustic Survey
Geographical area of cruise: North Pacific Ocean from Monterey, CA to British Columbia, CA.
Date: July 16, 2009

Here is Dr. Chu using a sonar readout to determine where the hake are located.
Here is Dr. Chu using a sonar readout to determine where the hake are located.

Weather Data from the Bridge 
Wind speed: 20 knots
Wind direction: 358°from the north
Visibility: foggy
Temperature: 15.2°C (dry bulb); 13.4°C (wet bulb)

Science and Technology Log 

We conducted several sea trawls for hake and other various fish species.   First, the scientists conduct an acoustic survey using 4 different frequencies. Then the nets are lowered and drug at depth. The fun begins when we don our rubber overalls, gloves, and galoshes and count, identify and, weigh the fish. The most numerous fish in the trawls were myctophids (see photo), bioluminescent fish with some species having 2 headlights in front of their eyes to help attract prey.

Here we are sorting the catch.
Here we are sorting the catch.

HAB/ Harmful Algal Blooms Test:  Throughout the day we took HAB samples, “harmful algae blooms”, which measures the toxins, domoic acid, and chlorophyll levels in the water (which correspond to the amount of plankton present). The HAB sample entails collecting sea water and putting it through a filtering process. Julia Clemons, a NOAA Oceanographer, and I conducted the HAB survey (pictured below).  Fifty milliliters of sea water is measured into a graduated cylinder then filtered.

This is a type of fish called a myctophid. They are bioluminescent.
This is a type of fish called a myctophid. They are bioluminescent.

Sea water is collected at specific times during each transect or line of study.  The sea water goes through a filtering process testing domoic acid and chlorophyll levels.  These results will be evaluated later in the lab. One thing that strikes me is the importance of careful and accurate measurement in the lab setting. The harmful algal bloom samples are conducted 5-6 times daily and accuracy is essential for precise and definitive results.  Later scientists will review and evaluate the data that was collected in the field.  It is very important that the scientists use the same measurements and tools so that each experiment is done the same way. Making accurate data collection makes for accurate scientific results.

Animals Seen Today 
Numerous albatross circling the stern of the ship, Viper fish, Octopi (approx. 6 inches in length), Squid (approx. 3 inches in length), and Myctophidae (see photo).

Zooplankton
Zooplankton
Here I am observing Julia as she filters a HAB sample.
Here I am observing Julia as she filters a HAB sample.