NOAA Teacher At Sea: Elizabeth Warren Aboard NOAA Ship Pisces
Mission: Reef Fish Surveys Geographical Area of Cruise: Gulf of Mexico Date: July 5, 2010
Getting Ready..
I’m all packed and ready to go. It was hard to do as my practical side was at war with my fashionable side. No you do not need to bring those shoes, no you do not need to bring those earrings… basics here basics. I did decide to leave my rubber boots at home since they don’t fit in my suitcase.
I spent some time over the last couple of days reading the other blogs of the teachers who were on the first leg of the Reef Fish survey. Melinda Story’s blog was very interesting. She saw a tiger shark attack a whale carcass! Check it out on TAS’s website! I’m imagining the many creatures and sights I’m going to see along the way. After today my blog is going to change a bit to follow the TAS guidelines. I’ll say where we are, give a scientific update on what we are doing, and a personal update. I plan on posting a ton of pictures!
It’s going to be a great trip. I am so glad it is finally here!
NOAA Teacher at Sea Kimberly Lewis NOAA Ship: Oregon II July 1 -July 16 2010
Mission: SEAMAP Summer Groundfish Survey Geographical Area of Cruise: Gulf of Mexico Date: Sunday, July 5, 2010
Weather Data from the Bridge Time: 1000 hours (10:00am) Position: Latitude = 27.58.38 N; Longitude = 096.17.53 W Present Weather: partly cloudy, haze on the horizon Visibility: 8-10 nautical miles Wind Speed: 17 knots Wave Height: 2-4 feet Sea Water Temp: 28.6 C Air Temperature: Dry bulb = 29.2 degrees Celsius; Wet bulb = 26.1 C Barometric Pressure: 1011.1 mb
Science and Technology Log
The purpose of the SEAMAP Summer Groundfish Survey is to collect data for managing commercial fisheries in the Gulf of Mexico. SEAMAP stands for Southeast Area Monitoring and Assessment Program.
Right now we’re working along the Gulf Coast of Texas, far from the BP Deepwater Horizon oil spill, so we’re not seeing any effects of oil here. However, part of our mission is to collect fish for testing to make sure that oil spill has not impacted the marine life in this area and that the fish and shrimp from Texas are safe to eat. We’re also collecting water samples from this area to use as baseline data for the long-term monitoring of the impact of the oil spill in Gulf.
There are four main ways the Oregon II is gathering SEAMAP data on this cruise, and we’ve already learned how to use all of them. The main way we collect data is by trawling, and this is where we do most of our work on the Oregon II. In trawling, we drag a 42’ net along the bottom for 30 minutes, haul it up, and weigh the catch. We then sort the haul which involves pulling out all of the shrimp and red snapper, which are the most commercially important species, and taking random samples of the rest. Then we count each species in the sample and record weights and measurements in a computer database called FSCS (Fisheries Scientific Computer System).
Here on the Texas coast, where we’re working now, the SEAMAP data is used to protect the shrimp population and make sure that it’s sustained into the future. Since 1959, Texas has been closing the shrimp fishery seasonally to allow the population to reproduce and grow. The SEAMAP data allows Texas to determine the length of the season and size limits for each species. Judging by our trawls, the Texas shrimp population is healthy.
Here I am flushing out the CTD to prepare for the next use.
Another method of data collection is the CTD, which stands for Conductivity, Temperature, and Depth. The CTD takes measurements from the surface to the bottom, creating a CTD profile of the water column at our trawling locations. These data are important to assess the extent of the hypoxic “dead zone” in the Gulf of Mexico, and to relate the characteristics of our trawling hauls to DO levels. SEAMAP data collected since the early 1980s show that the zone of hypoxia in the Gulf has been spreading, causing populations to decline in hypoxic areas.
We also use Bongos and Neustons to gather data on larval fish, especially Bluefin Tuna, Mackerel, Gray Triggerfish, and Red Snapper. The Neuston is a rectangular net that we drag along the surface for ten minutes to collect surface-dwelling larval fish that inhabit Sargassum, a type of seaweed that floats at the surface and provides critical habitat for small fish and other organisms. We drag the Bongos below the surface to collect ichthyoplankton, which are the tiny larvae of fish just after they hatch. The Neuston and Bongo data on fish larvae are used for long-term planning to maintain these important food species and keep fish stocks healthy.
In this photo I am untying the knots at the bottom of the Neuston to gather the ‘catch’. You can see a lot of Sargassum in this haul.
Personal Log
Day 1: docked
Day 2: we left the port in Galveston (July 2). My shift started immediately but by the time we actually left port and reached the first station my shift was over 1200 noon. So far so good!
Day 3: 2400 hrs or Day 4: 00:00 hrs.
– the sea sickness is getting me a little now. The rough seas are most likely the main culprit, however, I have not been out to sea for this period of time before. Once the seas calm down I should have a better idea. I do know this, my shift leader Alonzo and the chief scientist Andre have both been very understanding of my adjustment to sea life. The entire staff on board for that matter are very understanding and concerned for everyone’s well being.
– This was my first full shift. We are BUSY aboard the Oregon II ! A catch will come in for processing, which I will explain processing on my next blog, and we sometimes are still processing the last batch or we are up front taking CTD samples and bringing in our bongos/neustrons. I have learned a lot of things in a short period of time.
July 4, 2010 – Lots of stations (places where we deploy our nets) tonight. We actually got a little backed up. There are five people on my shift and it takes all 5 of us working non-stop to get the job done.
July 5, 2010 – I am feeling better today, so much that I uploaded my blog! I keep waking up at 5pm and unable to go back to sleep, but I am going to try now to catch a couple more hours as my shifts starts again in 3 hours.
NOAA Teacher at Sea Michele Brustolon Onboard NOAA Oscar Dyson June 28 – July, 2010
NOAA Ship Oscar Dyson Mission: Pollock Survey Geographical area of cruise: Eastern Bering Sea (Dutch Harbor) Date: July 4, 2010
Weather Data from the Bridge
Time: 1500 Latitude: 57.59N Longitude: 171.10W Cloud Cover: 100% Wind: 11 knots Air Temperature: 7.20 C/ 44.960 F Water Temperature: 5.50 C/ 41.90 F Barometric Pressure: 1010 mb
Science and Technology Log
Now that I have provided you with information about the importance of pollock and how the Oscar Dyson works to survey the stock in the Eastern Bering Sea, I wanted to answer a few related questions.
What about other species?
In the Bering Sea, pollock are so abundant that our mid-water trawls capture mostly pollock. However, there are a lot of other species in the Bering Sea that scientists are interested in. In addition to the Oscar Dyson, NOAA charters fishing boats (such as the Alaska Knight and the Aldebaron) to trawl on the ocean floor. This allows scientists to see more species in the Bering Sea. These ships trawl all day; sometimes up to 6 trawls a day. The GF boats cover the eastern Bering Sea shelf, extending up to the region around St. Lawrence Island (a wider area than the Oscar Dyson will cover). While the Oscar Dyson focuses on euphausiids and pollock, the ground fishing boats examine everything else found on the bottom.
Euphausiids from Methot trawlKatie proudly holding a pollock from our first Aleutian wing Trawl
Who owns the water? International laws provide countries with an Exclusive Economic Zone (EEZ) within 200 miles of their shoreline. The area we are studying in the Bering Sea can be fished solely by fishing boats operated in the United States. On the other side of the Sea, Russians fish in their own 200-mile zone. However, in the middle there is a “donut hole” which is considered “international waters”. This Donut Hole supported a large pollock fishery in the late 1980’s.
Transects for Leg II on Oscar DysonThe “Donut Hole” or “Bubleek” in Russian, is shown here in the shaded circular area between U.S. and Russia.
How do American scientists collaborate with scientists from other countries?
The United States works with other Pacific countries to conduct research on the Pacific Ocean and the Bering Sea. For example, the Oscar Dyson, in addition to hosting two Teachers at Sea, is hosting two Russian scientists from the Pacific Research Institute of Fisheries and Oceanography (TINRO) in Vladivostok, Russia – Mikhail Stepanenko and Elena Gritsay.
I had the opportunity to sit down with Mikhail the other night and asked him about his experience and how he ended up on the Oscar Dyson. Born and raised in Primorye, Mikhail spent a great deal of time at the Ussuri River. He studied biology at The Far East State University in Vladivostok and began researching at sea soon after his graduation in 1968. After the first USA-USSR agreement regarding marine research, Mikhail visited the United States and worked out of La Jolla, CA starting in 1969. He has spent about 5-6 months at sea per year for the last 40 years, including the last 18 summers on the NOAA summer pollock survey (specifically on the Oscar Dyson and its sister ship the Miller Freeman)
This wealth of experience has made Mikhail an expert and he is a well-respected member of the Pacific marine science community. Throughout the years, there have been numerous conferences between stakeholder countries, and Mikhail has played an active role in recommending action for working together to maintain the populations of pollock and other fish. Mikhail has served on the Intergovernmental Consultative Committee – a six-nation committee that meets biannually to discuss fishing polices in the “donut hole.” In addition, Mikhail worked as a Russian delegate during meetings which led to the creation of PICES (North Pacific Marine Science Organization), an “intergovernmental scientific organization, was established in 1992 to promote and coordinate marine research in the northern North Pacific and adjacent seas.” (Visit their website for more information). Mikhail was elected Chairman of the Fisheries Science Committee (FIS), a branch of PICES, in 2008 and is currently preparing for their next meeting in October.
Each organization is trying to find the best policies to help understand the organisms through reproduction, population dynamics, stock assessments and fishery management. Mikhail’s wealth of knowledge, collaborative scientific research and commitment to the sustainable fishing benefits all members of the international community and we are lucky to have such a science superstar in our midst.
Catch of jellyfish and pollock coming in (Abby: left; Kathy: right)This is a lumpsucker. Isn’t it cute?
The Fourth of July ending up being a packed day! First thing I was able to help with the CTD (remember from previous journals- conductivity, temperature, depth). You definitely wake up standing on the Hero Deck at 0400! My day of adventure continued when we got to fish after lunch. Why was this such a big deal? We hadn’t fished since June 30! We saw 100s of pounds of Chrysaora melanaster (jellies) that were so large we had to struggle to move them. We focused more on the pollock that were 1-3 years old this trawl, but the COOLEST animal by far was the lumpsucker! I was able to help sort the pollcok, sex them, and take the otoliths out for research. After we cleaned up the wet lab, we had a great ending to our day…
We had a cookout on the Boat Deck. Ray, the Chief Steward, with the help of Floyd Pounds, 2nd Cook, made everything you could possible imagine: a variety of kabobs, cheese burgers, salmon, different salads, cake, fruit, and the list goes on. To top the evening off (remember, it’s still light out!), Ensign (ENS) Amber Payne gathered and shot off expired flares for our “light show.” I enjoyed having the time to hang out with some people that I never see now that we are all working our shifts. It is a Fourth of July that I will remember always!
Fourth of July cookout on the Boat Deck
Animals Seen brown jellies or northern sea nettle- Chrysaora melanaster
pollock- many 1-3 years
smooth lumpsucker
rock sole
fulmars
Word of the Day
Propiate: appease New Vocabulary
GF boats: ground fishing boats
“Donut hole”: the area between Russia and the U.S. that was considered International waters” so it did not belong to a certain country
NOAA Teacher at Sea: Bruce Taterka NOAA Ship: Oregon II
Mission: SEAMAP Summer Groundfish Survey Geographical Area of Cruise: Gulf of Mexico Date: Sunday, July 4, 2010
Out in the Gulf
Weather Data from the Bridge
Time: 1000 hours (10:00am) Position: Latitude = 27.58.38 N; Longitude = 096.17.53 W Present Weather: partly cloudy, haze on the horizon Visibility: 8-10 nautical miles Wind Speed: 17 knots Wave Height: 2-4 feet Sea Water Temp: 28.6 C Air Temperature: Dry bulb = 29.2 degrees Celsius; Wet bulb = 26.1 C Barometric Pressure: 1011.1 mb
Science and Technology Log
The purpose of the SEAMAP Summer Groundfish Survey is to collect data for managing commercial fisheries in the Gulf of Mexico. SEAMAP stands for Southeast Area Monitoring and Assessment Program.
Right now we’re working along the Gulf Coast of Texas, far from the BP Deepwater Horizon oil spill, so we’re not seeing any effects of oil here. However, part of our mission is to collect fish for testing to make sure that oil spill has not impacted the marine life in this area and that the fish and shrimp from Texas are safe to eat. We’re also collecting water samples from this area to use as baseline data for the long-term monitoring of the impact of the oil spill in Gulf.
Analyzing a water sample in the Oregon II’s lab.
There are four main ways the Oregon II is gathering SEAMAP data on this cruise, and we’ve already learned how to use all of them. The main way we collect data is by trawling, and this is where we do most of our work on the Oregon II. In trawling, we drag a 42’ net along the bottom for 30 minutes, haul it up, and weigh the catch.
Hauling in the trawl net.
We then sort the haul which involves pulling out all of the shrimp and red snapper, which are the most commercially important species, and taking random samples of the rest. Then we count each species in the sample and record weights and measurements in a computer database called FSCS (Fisheries Scientific Computer System).
Logging a sample into FSCS.
Here on the Texas coast, where we’re working now, the SEAMAP data is used to protect the shrimp population and make sure that it’s sustained into the future. Since 1959, Texas has been closing the shrimp fishery seasonally to allow the population to reproduce and grow. The SEAMAP data allows Texas to determine the length of the season and size limits for each species. Judging by our trawls, the Texas shrimp population is healthy.
Another tool for data collection is the CTD, which stands for Conductivity, Temperature, and Depth. The CTD also measure dissolved oxygen, chlorophyll and other characteristics of the marine ecosystem and takes measurements from the surface to the bottom, creating a CTD profile of the water column at our trawling locations. These data are important to assess the extent of the hypoxic “dead zone” in the Gulf of Mexico, and to relate the characteristics of our trawling hauls to dissolved oxygen levels. SEAMAP data collected since the early 1980s show that the zone of hypoxia in the Gulf has been spreading, causing populations to decline in hypoxic areas.
We also use Bongos and Neustons to gather data on larval fish, especially Bluefin Tuna, Mackerel, Gray Triggerfish, and Red Snapper. The Neuston is a rectangular net that we drag along the surface for ten minutes to collect surface-dwelling larval fish that inhabit Sargassum, a type of seaweed that floats at the surface and provides critical habitat for small fish and other organisms.
Examining the results of a Neuston drag.Bongos.
We drag the Bongos below the surface to collect ichthyoplankton, which are the tiny larvae of fish just after they hatch. The Neuston and Bongo data on fish larvae are used for long-term planning to maintain these important food species and keep fish stocks healthy.
Personal Log
This is a great learning experience, not only about marine science but also about living and working on a ship. The Oregon II is literally a well-oiled machine, and the operation of the ship and the SEAMAP study depends on a complex effort and cooperation among the science team, the crew, the officers, engineers, and the steward and cook. Everyone seems to be an expert at their job, and the success of our survey and our safety depends on that. It’s a different feeling from life on land.
Life aboard the Oregon II is comfortable, especially now that I’ve gotten my sea legs.(I was hurting after we set out on Friday in 4’ to 6’ swells, but by Saturday afternoon I felt fine.) The food is excellent and most of the ship is air conditioned. The Gulf – at least the Gulf Coast off of Texas right now – is beautiful. The seas are deep green and blue and teeming with marine life. I’m looking forward to spending the next 2 weeks on board the Oregon II and being part of the effort to study the marine ecosystem in the Gulf and how it’s changing.
In a previous post, I briefly mentioned that acoustics helps Oscar Dyson scientists locate aggregations of pollock. I didn’t know much about acoustics surveying before I arrived on board but think its pretty cool.The Oscar Dyson has 5 transducers on its center board and 1 temporary transducer on the side of the center board that looks horizontally. The transducers allow us to see where the fish are. Because of where the transducers are placed, we can only see the pollock from 16m to the bottom. This means that if there are any fish between the surface and 16m they will not be detected. This is the near surface “dead zone”. At right you will see a picture of the acoustic data picked up by the transducers. Why this happens? The transducers are mounted on the bottom of the centerboard about 9 m below the water line, and near the transducer face (first 7 m), no good data are collected. Why it’s okay? Pollock tend to hang out in mid-water. Although a few baby pollock might be in the near surface “dead zone,” the majority of pollock will be in the area we are watching. There is also a bit of a “dead zone” at the other end near the ocean floor.
Acoustic Data
Why acoustics?
Ideally, the acoustic data collection would allow us to track aggregations of pollock without actually having to fish them out of the water. All parties involved (scientists, fish, bank accounts) would benefit from this change but scientists are still in the process of perfecting this process. The Oscar Dyson is part of a fleet of five boats that was specifically designed for acoustics. Specifically, it is considered a “quiet boat” where the engine noise is decreased to prevent scaring the fish. Other acoustic projects include: Pacific hake off the coast from California to Vancouver Island (run as a joint project with Canada), herring in the northwest Atlantic, and krill in the Antarctic. Acoustics are used throughout the globe and many countries depend on acoustics for their fish surveys.
Sonar
Looking in more than one direction
Along with the transducers, there is also a multibeam SONAR that produces the same information as the transducers but with a wider angle range. Scientists use this program to help separate species in the water column. The multibeam ME70 sends its signal out after the transducers information is sent and returned. They alternate about 1.5 seconds apart. Scientists around the world are working to improve this technology and we use information from a group at University of New Hampshire along with a program from Tasmania to analyze these data. Scientists utilize the multibeam ME 70 along with the transducers and fish trawling to ensure they are capturing an accurate picture of the mid-waters.
How the survey data we collect are used.
The data we collect on the Oscar Dyson during the summer pollock surveys are used by scientists and policy makers to determine the fishing quota (the “take”) of pollock for the next season. Quotas are important for maintaining the population of pollock (and other species) for this generation and generations to come. The data we collect on the Oscar Dyson help ensure that maximum stock can be taken without negatively impacting the Eastern Bering Sea pollock population.Thought Question: What could happen if we didn’t regulate the amount of fish that could be caught? Bonus points for anyone who can identify an area where overfishing has impacted the ecosystem.
