Hugh R. Sharp – Page 3 – NOAA Teacher at Sea Blog

April 30, 2012March 12, 2021

Alicia Gillean: Introduction, April 29, 2012

NOAA Teacher at Sea
Alicia Gillean
Soon to be aboard R/V Hugh R. Sharp
June 27 — July 8, 2012

Mission: Sea Scallop Survey
Geographical area of cruise: Northwest Atlantic Ocean
Date: Sunday, April 29, 2012

Personal Log

Hello from Oklahoma! My name is Alicia Gillean and I am ecstatic that I was selected as a 2012 NOAA (National Oceanic and Atmospheric Association) Teacher at Sea! I am passionate about adventure, lifelong learning, and the ocean. I can’t wait to merge these three passions together for twelve days at sea this summer and to share my learning with all of my students and coworkers back in Oklahoma. I will be blogging about my adventure and learning while aboard the ship and you are invited to follow my journey and get involved by asking questions and posting comments. I’ll start by telling you a little bit about myself, then I’ll fill you in on the details of my Teacher at Sea adventure.

A Bit About Me

When I’m not pursuing adventure on the high seas, I am the school librarian (also known as a library media specialist) at Jenks West Intermediate School, a school of about 600 5^th and 6^th graders in the Jenks Public Schools District, near Tulsa, Oklahoma. I might be a bit biased, but I believe that I have the best job in the school and that I work with some of the finest teachers and students in the world.

You are probably wondering, “How did a librarian from Oklahoma become part of an ocean research cruise?” I’m glad you asked. It just so happens that this blog entry answers that very question.

I’ll admit it; I was born and raised a landlubber. There just aren’t many opportunities to visit the ocean when you grow up in the Midwest. Rumor has it that I touched the ocean once when I was about 3, but I didn’t touch it again until I was 21. More on that later.

My passion for the ocean began in high school when I took a Marine Biology class where my mind was blown by the diversity and beauty of life in the sea and the complex network of factors that impact the health of an ocean environment. I took Marine Biology 2 and 3 the following years where I set up and maintained aquariums in elementary schools and taught ocean-related lessons for elementary students.

Aquarium newspaper photo — Alicia showing a shark jaw to a three year old at the Oklahoma Aquarium

I started to become a little obsessed with marine life, went to college to become a teacher, and did a happy dance when I learned that an aquarium was going to open in Jenks, Oklahoma. I landed a job as a summer intern in the education department of the Oklahoma Aquarium and was overjoyed to be a part of the team that opened it in 2003. When I graduated from college, the aquarium hired me as an education specialist, where I worked with learners of all ages to promote our mission of “conservation through education” through classes, camps, fishing clinics, sleepovers, animal interactions, crafts… the list goes on and on.

In 2006, I became a 6^th grade teacher in Jenks Public Schools, then I earned my Masters degree and became the school librarian in 2010. I love to work with all the kiddos in my school as they learn to develop as thinkers, scientists, and citizens who have the power to impact the world. They are just the kind of advocates that the environment needs and I want to help prepare them for this important role any way possible. My experiences as a Teacher at Sea will certainly help!

Let’s go back to my actual experiences with the ocean for a moment. After graduating from college and marrying my high school sweetheart David, I hightailed it to an ocean as fast as possible. We honeymooned in Hawaii where we snorkeled, explored tidepools, went on a whale watch, and temporarily filled the ocean-shaped void in my heart.

Alicia in ocean — Alicia on a Maui Beach

I’ve been back to the ocean several times and each time I am reminded of the delicate balance that must be maintained for the fascinating world under the waves to survive and thrive. It is critical we protect the oceans and that people realize that their actions impact the oceans. Even in the landlocked state of Oklahoma, our actions matter.

So, that’s why a school librarian from Oklahoma will spend the summer of 2012 on a ship in the Atlantic Ocean, counting sea scallops. I can hardly wait for the adventure to begin! Enough about me, let’s talk about the research cruise now.

Science and Technology Log

I’ll be participating in a sea scallop survey in the Atlantic Ocean, along the northeast coast of the United States, from Delaware to Massachusetts. My adventure at sea will begin June 27, 2012 and end July 8, 2012.

What is a sea scallop?

A sea scallop is an animal that is in the same category as clams, oysters, and mussels. One way that sea scallops are different from other animals with two shells (bivalves) is that a sea scallop can move itself through the water by opening and closing its shells quickly. How do you think this adaptation might help the sea scallop? Watch these videos to see a sea scallop in action:

Importance of Sea Scallops/Sea Scallop Survey

People like to eat scallops, so fishermen drag heavy-duty nets along the ocean floor (called dredging) to collect and sell them. Most of them are harvested in the Atlantic Ocean along the northeastern coast of the United States. The United States sea scallop fishery is very important for the economy.

Sea Scallop Habitats — Map of sea scallop habitats from NOAA’s fishwatch.gov

The problem is that sometimes people can harvest too many scallops and the sea scallops can’t reproduce quickly enough before they are harvested again. Eventually, this could lead to the depletion of the sea scallop population, which would be bad news for the ocean and for people.

This is where the NOAA Sea Scallop Survey comes in. Every year, NOAA sends scientists out in a ship to count the number of Atlantic sea scallops (Placopecten magellanicus) in various parts of their habitat. The sea scallops live in groups called beds on the ocean floor 100-300 feet deep, so scientists can’t just peer into the ocean and count them. Instead, they have to dredge, just like the fisherman, to collect samples of scallops in numerous places. The scientists record data about the number, size, and weight of sea scallops and other animals. Based on the data collected, decisions are made about what areas are okay for people to harvest scallops in and what areas need a break from harvesting for a while. I’m considered a scientist on this cruise, so I’ll get to participate in this for 12 hours a day. I hear it is messy, smelly, tiring, and fascinating. Sounds like my type of adventure! I think most good science is messy, don’t you?

The Ship

I’ll be sailing on the research vessel Hugh R Sharp. You can take a virtual tour of the ship here. It was built in 2006, is 146 feet long (a little bit shorter than the width of a football field), and is used for lots of different scientific research expeditions. When I’m out at sea, you can see where I am on the journey and track the ship here.

RV Hugh R. Sharp — R/V Hugh R. Sharp; photo from NOAA Eastern Surveys Branch

What I hope to Learn

I’m very interested to experience what daily life is like on an ocean research vessel, how scientists use inquiry, data-collection, math, and other skills that we teach our students in a real-world setting. Of course, I’m also hoping to see some fascinating ocean critters and get my hands dirty doing the work of a real scientist.

I’d love for you to join me on this adventure by following this blog and leaving your thoughts and questions in the comment section at the bottom of each blog entry. Let’s make this a learning experience that we will all remember!

May 14, 2011April 28, 2021

Channa Comer: The Voyage Begins, May 13, 2011

NOAA Teacher at Sea
Channa Comer
On Board Research Vessel Hugh R. Sharp
May 11 — 22, 2011

Mission: Sea Scallop Survey Leg 1
Geographical area of cruise: North Atlantic
Date: Friday, May 13, 2011

Weather Data from the Bridge
Air Temperature: 13.7C, Partly Cloudy
Wind Speed: 5 knots
Water Temperature 13.1C
Swell Height: 0.1 meters

Newspaper clipping — A newspaper clipping about how important food on working ships is, especially ice cream

Science and Technology Log
Day 1 – Wednesday, May 11, 2011

The coastal Research Vessel Hugh R. Sharp set sail at around 2PM on Wednesday, May 11th from Lewes, DE. There are 13 members on the science team, six who are volunteers (including myself), and nine crew members. On the first day, we met for introductions, a briefing on the schedule of the day and safety instructions.

The Hugh R. Sharp is 146 ft research vessel, weighs approximately 490 tons and has a cruising speed of about 10 knots. The vessel is diesel-electric with all the comforts of home (satellite television, heat, hot water, laundry facilities), and can be at sea for a maximum of 30 days. The vessel is configured with a pilothouse (at the top) and three decks. The “below decks” which is the bottom-most deck has the bulk of the ship’s machinery and crew cabins. The main deck is where most of the action happens. It houses the portable lab van where each catch is processed, a dry lab which houses the computers used for the survey, a wet lab, dredging equipment and the all important galley and mess area. There is also a small conference room where members of the crew can be intermittently found working, reading, listening to music, or eating ice cream.

Once we were out to sea, the team got to work preparing for a test tow of the scallop dredge. The dredge is 8ft wide and is made of a metal frame from which netting and a bag constructed of rings is attached aftward. It is lowered with a winch off the stern of the vessel and descends to depths that range from 30 meters to 150 meters. As the ship moves at a speed of 3.8 nautical miles per hour for 15 minutes, the dredge scrapes the sea floor. A test tow is conducted near the shore to make sure this important equipment is working properly.

The focus of this NOAA Fisheries cruise is to survey the population of Placopecten magellanicus, the deep-sea scallop that is commercially fished and sold to the public. Chief scientist Victor Nordahl (NOAA-Fisheries) is the head of the team of researchers and coordinates all aspects of the survey. The NOAA Fisheries Service monitors the populations of sea scallops in the federal waters on the Eastern continental shelf of the U.S. In 2007, scallops represented the most valuable commercial fishery, along with lobsters. It is critical to monitor their populations to avoid over-fishing of these waters. Fishing areas are either open or closed, meaning that fishing is either allowed or not. Closed areas allow time for repopulation of the area of the commercial species.

Temperature and depth are important for scallops. The species we are studying are found in waters cooler than 20C (68F) along the North Atlantic continental shelf area between Newfoundland and North Carolina. In the 12-day time period of this survey, we will conduct approximately 15 sampling stations per day, working 24hrs a day with two crews working in 12 hour shifts. I’ve been assigned to a six person day crew with Jakub Kircun serving as watch chief.

New Term/Phrase/Word
Head = bathroom
Stateroom = bedroom
Fathom = 6 feet

Personal Log
Day 1 – Wednesday, May 11, 2011
Being on board a vessel for the first time is like being in a foreign country with a new language and new customs to learn. Everyone on board has been very helpful and generous in sharing their knowledge, advice and experience. The crew, NOAA staff and other volunteers are an eclectic bunch from all over (Maryland, Massachusetts, Virginia, Pennsylvania, Germany, Honduras, and France). Vic, chief scientist for the cruise, has been especially kind, taking the time to answer my many questions and make sure that I’m comfortable with all the new information and procedures. Sara, my bunkmate is a pleasure and we’ve gotten along great so far. After the first day, we only see each other in passing at meals since we’re on opposite shifts. I’m looking forward to a great adventure!

Day2 – Thursday, May 12, 2011
Today is day two and my first full 12-hour shift (from 12 noon until midnight).The first day was rough since we spent most of the day getting ready to leave and then heading out to the site where we would bring up our first catch. I was a little sick the entire day, eating lots of crackers and ginger. I’m sleeping in a small cabin with a desk and two bunkbeds — with NO LADDER. My bunkmate Sara, is a graduate student from Germany and since she got to the boat first, she got to choose the bunk. Guess which one she chose?! After a few bruises on my shins, I’ve pretty much figured out the best way to get in and out of my bunk without getting hurt. Today I learned how to identify a few different species of fish and how to shuck scallops, which is my least favorite activity so far since they’re still alive and sometimes fight back while you’re shucking them (Ugh!).

Did You Know?
A nautical mile is a measure of distance used at sea is derived by dividing the circumference of the earth by 360, then by 60 and actually represents minutes of latitude covered over the earth. One nautical mile is equivalent to approximately 1.2 statutory miles.

June 15, 2010March 12, 2021

Anne Byford, June 15, 2010

NOAA Teacher at Sea
Anne Byford
Aboard R/V Hugh R. Sharp
June 8 – 15, 2010

Mission: Sea Scallop Survey
Geographic Location: off the coast of New England
June 15, 2010

Aboard: R/V Hugh R. Sharp

Weather Data at 1:30pm

EDT: Clear and sunny, 14.5˚C

Location at 1:30pm

EDT: Lat: 41 23.78 N

Long: 66 56.64 W

Water Depth: 68.2 m

8^th Day at Sea

What kinds of things are you going to catch? Part 2 – non-fish along with a few new fishes

There are many more species in the areas than I have listed here; these are simply the ones that I found most interesting. There are several different types of bivalves, sea weeds, etc. Material about the species on this page came from several sources, including the Bigelow and Schroeder’s book referenced in the previous posting. Also, Kenneth Gosner’s A Field Guide to the Atlantic Seashore published by Houghton Mifflin Company in Boston, Ma, 1978. I also used Norman Mein-Koth’s Field Guide to North American Seashore Creatures published by Alfred A. Knopf in New York in 1990.

Sea Stars (aka starfish) – Every third dredge, the contents of the dredge are sampled and the sea stars are separated by species and counted. Most sea stars can regenerate a lost arm, but a few can regenerate an entire organism from the lost arm as well. All sea stars are predators; many species do eat scallops.

Hippasteria phygiana – a cushion star with a much wider central disk and shorter arms than the other types of sea stars.

Northern Sea Star (Asterias vulgaris) – is one of the more common sea stars found. It can have a radius of up to 20 cm.

Blood Star (Henricia sanguinolenta) – is a thin armed sea star that ranges in color from bright red to orange. This particular blood star shows some aberant regeneration occurring on one arm.

Leptasterias tenera – smaller sea stars than the others. They are usually whitish-tan. Some have purple centers and arm bands.

Sclerasteras tanneri – are spinier than the other sea stars seen. They are bright red with thin arms.

Spiny Sun star (Crossaster papposus) – is the only sea star that I’ve seen here with more than 5 arms. It has concentric rings of color radiating from the central disk of the sea star.

Green Sea Urchin (Strongylocentrotus droebachiensis) – can grow up to 8.3 cm wide and 3.8 cm high. The shell (test) is usually a greenish color and the spines are all approximately the same length.

Sand Dollar (Echinarachnius parma) – the common sand dollar. This species does not have openings in the test like the Keyhole type that is commonly found off the coast of the Carolina’s, but does have the flower-like markings on the dorsal side. A great many of these (hundreds of thousands) are found in the dredge on some tows.

Hermit Crabs (various species) – move from shell to shell as they grow.

Northern Lobster (Homarus americanus) – can grow up to 90 cm in length. Lobsters are scavengers and can be cannibalistic. Claws and tail are highly prized for meat.

Winter flounder (Pseudopleuronectes americanus) – are darker than the other flounder. Like summer flounder, they can change color to match the underlying ocean floor. Winter flounder can live up to 15 years. They can reach a maximum size of 64 cm and 3.6 kg, with the average being 31-38 cm and 0.7-0.9 kg. Winter flounder eat mostly small invertebrates, like polychaetes and shrimp and some small fishes. They are preyed upon by cod, skates, goosefish, and spiny dogfish. Winter flounder are the thickest of the flatfish, but are considered over-exploited.

winter flounder dorsal — Winter Flounder Dorsal

Haddock (Melanogrammus aeglefinus) – a silvery fish that is dark grey on the dorsal side with a dark patch behind the gills. The largest recorded haddock was 111.8 cm long and 16.8 kg. The average haddock is 35-58 cm long and 0.5-2 kg. Small haddock eat crustaceans, polychaetes, and small fish, while larger haddock eat more echinoderms, but will eat most anything. Predators include spiny dogfish, skates, cod, other haddock, hakes, goosefish, and seals. Haddock aquaculture was begun in 1995. The biomass of haddock was considered below maintenance levels in the late 1990s.

Fawn Cusk-eel (Lepophidium profundorum) – are greenish with light green or tan spots down the sides and, unlike true eels, have pectoral fins. They average about 26 cm in length. They eat sea mice, shrimp, and echinoderms. Larger fawn cusk-eels eat flatfish as well. They are eaten by skates, spiny dogfish, hakes, flounders, and sea ravens.

Winter Skate (Leucoraja ocellata) – large, heart-shaped skate. Like the barndoor skate, winter skates can be quite large, up to 150 cm long. They eat bivalves, shrimp, crabs, echinoderms, and many types of fishes. They are eaten by sharks, other skates, and grey seals. They are considered to be commercially important.

winter skate female dorsal 2 — Winter Skate Female Dorsal

Personal Log

I have to admit, when I first went up to the bridge of the ship, with its wrap-around windows, the first words that came to mind were the lines from Rhyme of the Ancient Mariner (which I may have not remembered entirely correctly)

Water, water everywhere

And not a drop to drink
Water, water everywhere
And all the boards did shrink

At the time that I was there, no land and no other ships were within sight; there was nothing but water and wavelets as far as I could see. We’ve see several ships on the horizon, and two container ships close enough to get a good look at. One of those passed quite close as we had a dredge down.

June 8, 2010March 12, 2021

Anne Byford, June 8, 2010

NOAA Teacher at Sea
Anne Byford
Aboard R/V Hugh R. Sharp
June 8 – 15, 2010

Mission: Sea Scallop Survey
Geographic Location: off the coast of New England
June 8, 2010

Weather Data at 6pm EDT: Calm, Clear, 23˚C
Location at 6pm EDT:
Lat: 39 42.68 N
Long: 73 24.98 W
Water Depth: 86.4m

First day at sea

The first day was mostly spent steaming to the first dredge site, about 14 hours away from Lewes, Delaware. In the morning, all of the safety information was covered and those of us who had not tried an exposure suit before put one on. After the ship reached the ocean, we did a test dredge to ensure that all of the equipment was working and that we all knew what to expect.

The process is basically the same for all dredges on the Sea Scallop survey. Each tow is at a specific, pre-selected random site, using the same type of dredge, at the same angle to the bottom for the same amount of time and at the same speed as all other tows. This ensures that the data gathered is comparable from tow to tow and particularly from year to year. Once the dredge is pulled back up, it is dumped onto a sorting table on the rear deck of the ship. Everything is sorted into 4 categories: scallops, fish and squid, sea habitat (which is anything that is not scallops or finfish), human trash. Once the initial sorting is done, the sea habitat is counted by the bucket-load and dumped back into the ocean; the fish are sorted by species and weighed and counted. Some species (skates, flounder/flukes, and goosefish, also called monkfish) are also measured for length. Scallops are weighed, counted and measured. Some specific samples may be kept for researchers on shore and the rest is thrown back. Human trash is kept aboard for proper disposal later. After all of the sorting and measuring is finished, the buckets are rinsed and stacked for the next dredge, which isn’t usually that long in coming.

Fortunately, we are not measuring things with a tape measure or having to manually input lengths into the computer. The ship has 3 “fish boards” that are electronic magnetic measuring devices that automatically send the data to the shipboard computers. Operators choose the species of fish being measured and then each fish is put on the board and a magnetic wand is used to mark the end of the tail of the fish. Each length is sent to the computer and stored. Historically, the data was collected on paper and the lists sent to a prison to be hand entered into a database. The database then had to be proofread and corrected if necessary. While the data still must be audited, it is much faster and easier, and less prone to error, to take the hand written stage of data collection out of the process.

Species Seen:

At the dock in Lewes: Osprey pair and at least one chick in the nest, Sea gulls

At sea: Pod of dolphins playing in the ship’s wake, jellyfish, pelicans

In the dredge: Squid, gulfstream flounder, windowpane flounder, summer flounder, spotted hake, sea robins, small skates, clearnose skates, several kinds of crabs (spider and rock), moon snails, sea stars, sand dollars, whelks, sea urchins, scallops, sea mice (polycheate worms)

Personal log:

We couldn’t have asked for better weather, clear and calm. After the safety meeting and test dredge, there was a great deal of down time until we reached the first site at about 10pm. I am on the day watch from noon to midnight and so got to sort the first real dredge. We did find scallops, ranging from about 1 inch across to about 5 inches across, but we found more sand dollars. After spending countless hours walking beaches to find even a few sand dollars, it was amazing to see hundreds or thousands on the sorting table to be tossed back as sea trash. I also discovered that you can easily loose track of time simply sitting in the sun on the deck watching the world go by.

May 11, 2010April 7, 2021

Julianne Mueller-Northcott, May 11, 2010

NOAA Teacher at Sea
Julianne Mueller-Northcott
Onboard R/V Hugh R. Sharp
May 11 – 22, 2010

University of Delaware R/V Hugh R. Sharp
Mission: Sea Scallop Survey: Leg III
Port of Departure: Lewes, Delaware
Date: May 11, 2010

Weather Data from the Bridge
Overcast, rainy, in the 50s

Science and Technology Log – Data Collection/Sampling Methodology
For NOAA’s scallop survey, it is divided into three different legs or cruises, each sampling a different area along the east coast. This cruise that I am on is the first in the series. During this time, since we will be working around the clock, we will probably do somewhere between 150-200 dredges and the NOAA team will sample about 500 total for the season. But how do scientists determine where to dredge? How can they be sure that the sites that are sampled will give them an accurate representation of the number of scallops on the sea floor? To determine where to sample, scientists use the Stratified Random Sampling Design. This is the method for determining the average number of an animal in a given area. This sampling technique is based on the fact that the scallop population density depends on the ocean depth. Scallops like to hang out in 50-100 m of water. Scientists break up the coastline that their studying into different “strata” or quadrants. And then instead of a totally random sample in a given area, the stratified random sampling design uses a computer to select more collection sites in the depths where you would be likely to find the most scallops, since that is what scientists are interested in.

Scallop Fisheries

The US scallop fishery is an economically important fishery, maybe second only to the lobster industry in the Atlantic. One question that one of my students asked was, “Is the scallop population growing or is it in danger?” I asked our chief scientist that question this afternoon. His response was very promising, that the scallops are doing very well. Part of the reason for their success is due to the regulations that are set in place, the same regulations that are based on the data collected by this trip. One type of regulation that has been helpful is the temporary closure of certain areas. These closures give scallops in a particular area a chance to grow. So if during a scallop survey cruise, scientists notice a lot of young scallops in a given area, that data will get reported an maybe lead to the temporary closure, meaning that you can’t fish for scallops there for a couple of seasons. Then after some time for the animals to grow, the area will be reopened. By rotating these closed areas, it allows the time necessary for population growth. Astrid B. asked the following question, “Does the dredge hurt the ocean bottom?” Our dredge is fairly small, about eight feet across. But a commercial fishing boat has two dredges that are about 15 feet wide that go down at the same time. And at a given time, there might be as many as 500 boats out fishing for scallops. Before and after photographs have shown that the dredges do impact the bottom. It works to flatten everything in its path, including living organisms. It also affects an important habitat. Fish species like cod like to hang out around the nooks and crannies that are created by benthic creatures, but without that important living structure, the cod population doesn’t have the habitat it prefers (which may be an explanation for why that population has been slow to recover). While more research needs to be done to find out how long it takes for the substrate to recover and return to its pre-dredge state, dredging does have some pretty clear impacts on the sea floor habitat.

Brandon O had a fun question, “What is the funniest thing that got brought up by the dredge?” The chief scientist said that once they brought up pieces of an airplane in a dredge. I asked if it hurt the dredge and it didn’t because the plane was made of light aluminum. And then he said that they have also found mammoth teeth. That is very cool! A long time ago this whole area was not covered by water, but instead it was land for wooly mammoths to walk over. I think this is especially neat after just seeing lots of skeletons of mammoths at the Natural History Museum during our trip to New York City over vacation. I can’t wait to find out what will be the most interesting thing we’ll find during this trip!

Personal Log
We just officially set out to sea! It was a long day waiting for all the preparations to be finalized and for the water to be high enough so we could leave port. It is a chilly day, with the wind blowing on the ocean and a little drizzle coming down—but so exciting to be moving and heading out! Lots of students had many questions for me about food, especially considering my mantra, “Fish are friends, not food.” So far so good, lots of chicken, pasta and the most unbelievable snack cabinet—featuring all sorts of goodies that we never keep at home (Oreos, cheese-its, candy bars, soda). And then today, I saw for the first time–the ice cream freezer. And entire freezer, dedicated to the storage of frozen treats—what a beautiful concept! As it turns out, there used to be a treadmill on the boat, but they had to move it off to make room for the ice cream. I like where their priorities are and it is clear that I won’t be going hungry!