noaa ship mcarthur II – Page 3 – NOAA Teacher at Sea Blog

April 9, 2008April 2, 2021

Beth Lancaster, April 9, 2008

NOAA Teacher at Sea
Beth Lancaster
Onboard NOAA Ship McArthur II
April 6 – 14, 2008

Mission: Examine the spatial and temporal relationships between zooplankton, top predators, and oceanographic processes
Geographical area of cruise: Cordell Bank Nat’l Marine Sanctuary & Farallones Escarpment, CA
Date: April 9, 2008

Weather Data from the Bridge
Wind – Northwest 20 – 35 knots
Swell Waves – 4-12 feet
Sea Water Temp – 9.4 – 10.5^oC

A 24-hour forecast of sea conditions for April 7, 2008 off the West Coast of the United States. The red section indicates swells that range from 12 to 15 feet. — A 24-hour forecast of sea conditions for April 7, 2008 off the West Coast of the United States. The red section indicates swells 12 to 15 feet.

Reported sea surface temperatures from April 7, 2008 for coastal California from satellite data. The coastal wind did in fact cause an upwelling and cooling of water along the coast. The purple area indicates temperatures 8-8.5oC and the blue 8.6-10oC. — Today’s reported sea surface temperatures for coastal California from satellite data. The coastal wind did in fact cause an upwelling and cooling of water along the coast. The purple area indicates temperatures 8-8.5 degrees C.

The weather reports collected from the bridge of the McARTHUR II reported that the waters traveled over the course of the day did in fact reach 12 feet. The winds from the northwest cause an upwelling effect, which brings deep, nutrient-rich cooler waters to the continental shelf area off the coast of California. This nutrient-rich water plays a large role in the food web of the area, increasing primary productivity, which will then result in large numbers of marine mammals and birds due to the availability of prey items. This period of upwelling in the area of Cordell Bank and Gulf of the Farallones National Marine Sanctuaries marks the beginning of a productive time of year.

Science and Technology Log

Part of the mission on this cruise is to gather oceanographic processes data to look at the relationship between biotic (living) and abiotic (nonliving) factors within the study area. While many samples are being collected through observation and survey equipment outside of the ship, there is just as much being collected in the laboratory onboard the McArthur II. The ship is equipped with several pieces of equipment that report physical features and measurements throughout the day. This information is recorded for scientists onboard to utilize in their data analysis. The following is a list of equipment, and their functions being used to measure oceanic processes:

Thermosalinograph (TSG) – Surface water is pumped from the ocean through a hose to this piece of equipment which measures temperature and salinity. There is an additional probe that measures CO2. All information collected during the course of the cruise will be given to researchers to use in data analysis.

Scientific Echosounder – Sends a sound wave into the water column. If there is anything in the water column this sound wave will reflect back to the ship. The longer it takes for the reflected wave to get back to the ship the farther away the target is. Comparing three different frequencies emitted by the echosounder allow scientists to identify different types of plankton in the water column, and set sampling sites.

Navigation Software – Allows researchers to track where they have been and where they are going. Because nets and other equipment are being deployed from the ship this computer software allows scientists to view the charted underwater topography to determine placement and depth of equipment. By marking sample sites using the software, scientists can look at the relationship between the ocean’s topography and living organisms collected.

NOAA Teacher at Sea Beth Lancaster (left) and NOAA Chief scientist Dr. Lisa Etherington (right) view sampling areas using navigation software in the McARTHUR II’s dry lab. — NOAA TAS Beth Lancaster (left) and NOAA Chief scientist Dr. Lisa Etherington (right) view sampling areas using navigation software in the McARTHUR II’s dry lab.

Personal Log

I have been onboard the McARTHUR II for four days, and have enjoyed every minute of helping out with the research project. Scientists have been so patient and willing to answer all of my questions. The crewmembers onboard the McARTHUR II are very friendly and helpful. I now have a much better understanding of the marine physical environment than I did upon my arrival! I am enjoying living at sea, even the small bunks! The ship is actually very large you would never know there were more than twenty people onboard!

Animals Seen Today

Black-footed Albatross, Pteropod, Pigeon Guillemot, Copepods, Brandt’s Cormorant, Ctenophore, Sooty Shearwater, Krill, Northern Fulmar, Microscopic Plankton, Black-legged Kittiwake, California Gull, Western Gull, Common Murre, Cassin’s Auklet, Rhinoceros, Auklet, and Bonaparte’s Gull.

April 7, 2008April 2, 2021

Beth Lancaster, April 7, 2008

NOAA Teacher at Sea
Beth Lancaster
Onboard NOAA Ship McArthur II
April 6 – 14, 2008

Beth Lancaster (right) preserves a plankton sample collected using a hoop net. — NOAA Teacher at Sea Beth Lancaster bottles a surface water sample that will be tested for the presence of nutrients.

Science and Technology Log

Today was the first full daytime operations. We began shortly after 7:00 a.m., and covered a 90 kilometer transect throughout the course of the day ending at 6:00 p.m. At each sampling point along the transect a series of measurements and observations were made to look at relationships between the physical ocean environment, and abundance of living organisms that are observed and collected to gain a better understanding of the physical and biological features of the area, and how they interact. The daytime crew was divided into two groups: the marine mammal and bird observers, and a second group that was responsible for collecting water and plankton samples as well as other various physical measurements of the water. I worked with the second group, and will share what sampling I assisted with.

At each sampling point we used the CTD, which is a piece of equipment that has several probes on it, to collect a vertical sample of the water column. When the CTD is deployed into the water it is sent down 200 meters below the surface and collects water conductivity (used to calculate salinity), temperature, depth, and turbidity. There is also a fluorometer attached to the CTD that measures the fluorescence of chlorophyll-a, which approximates the abundance of phytoplankton. The CTD collects all this data, and can then be downloaded onto a computer. Surface water samples were also collected at each sampling point, and will be tested for the presence of nutrients which would also have a direct impact on the abundance of organisms in the area.

To gather information on the living organisms present at each site, a hoop net was used to collect samples of plankton. The net was sent down approximately 50 meters, and collected all of the tiny living organisms (zooplankton) on a screen as the net was pulled through the water column. When the hoop net was brought back onboard, the cod end of the net (where the sample is collected) was transferred to a sample bottle, and preserved for further investigations in the laboratory. In addition to the living organisms collected in the hoop net, marine mammal and bird observations are being made from the flying bridge of the ship. That would be the highest point on the boat, and not the location for people who are afraid of heights. Due to rough sea conditions (10-12 foot swells), sightings were few and far between today. Springtime within Cordell Bank National Marine Sanctuary is a time where strong winds cause upwelling of deeper waters towards the surface near the coast. This upwelled water is colder and has higher nutrient concentrations.

Sample of krill caught in the daytime with a hoop net.

This influx in nutrients means the ecosystem becomes very productive. Given this high influx of nutrients, prey items for birds and mammals are readily available. The food of choice for a lot of these organisms is krill (a shrimplike zooplankton.) We did collect some krill in the hoop net during the day, but the abundance of krill in shallower water is much greater in the evening, when krill migrate from deep depths towards the surface. The night crew is collecting krill using a tucker trawl, which has three separate nets that are opened and closed at different depths. Krill play a vital role in the ecosystem scientists are currently studying. They provide nourishment for resident and migratory birds as well as marine mammals. There is sufficient nutrient availability for primary producers which are then food for primary consumers such as krill, and therefore food availability for secondary consumers such as fish and tertiary consumers such as whales and dolphins.

Throughout the week the same measurements will be taken at different sights along the continental shelf and continental slope in the region of Cordell Bank National Marine Sanctuary and the Farallones Escarpment (within Gulf of the Farallones National Marine Sanctuary). This information will allow scientists to better understand the dynamic relationship between zooplankton, top predators, and oceanographic processes. Data gathered will also be used in conservation planning of the marine sanctuaries.

Some Animal Sightings
Black-footed Albatross, Ancient Murrelet, Northern Fulmar, Laysan Albatross, and Pacific White-sided Dolphin.

June 9, 2007April 1, 2021

Elsa Stuber, June 9, 2007

NOAA Teacher at Sea
Elsa Stuber
Onboard NOAA Ship McArthur II
June 4 – 9, 2007

Mission: Collecting Time Series of physical, chemical and biological data to document spatial and temporal pattern in the California Current System
Geographical Area: U.S. West Coast
Date: June 9, 2007

Science and Technology Log

Up at 06:00 and arrived in San Francisco @ 08:00 Unloaded equipment, mostly by winch onto truck; cleaned quarters and wet and dry labs.

In preparing my report I have included the data from the casts I worked on. As they were a dollar each to reproduce at Kinkos, I decided to only include those four-colored graphs for beam transmission, depth, salinity, and temperature that illustrate different types of locations, near shore or at sea of varying depths. These graphs certainly show the increase in salinity with depth and the falling of temperature with depth. They show the inverse relationship between the beam transmission and fluorescence. Compare Table 3, Table 6, Table 7, and Table 9 that are from very different depths. There is a lot of information here for my students to analyze.

This has been a stimulating learning experience. My students like most high school students are not near the ocean, maybe have never been to an ocean. I think sharing this first hand experience along with the pictures and doing demonstrations of our work and showing the data collected will open a perspective in their minds about the ocean. They will realize from the chlorophyll analysis and fluorescence the narrow level of the bottom of the food chain. This will bring home the concern for the protection of the health of the biotic life in our oceans. I intend to do a mock set up of our lab procedures and have them brainstorm how experimental error could be introduced. This should reinforce the importance of careful procedure in any scientific work.

The scientific staff on this cruise has been exceptional in willing to share their knowledge and, even when we were all tired, to answer my many, many questions about each individuals work in oceanography. I have found them to be conscientious scientists very interested, stimulated in their work. Some have given me pictures. Several have done extended work in Antarctica, which was particularly interesting to me. As well, the MBARI staff was very supportive as the other Teacher At Sea and I were learning procedures for our work. It felt good to see how cooperative, flexible they all were with one another no matter how long the days. I wish we could have been able to go to the MBARI lab this coming week to see how the work continues there. I intend to go on line and read more about their research and research findings. This will be something to investigate and follow with my students and extending their understanding of the oceans and the oceanographers’ work.

June 8, 2007April 1, 2021

Elsa Stuber, June 8, 2007

NOAA Teacher at Sea
Elsa Stuber
Onboard NOAA Ship McArthur II
June 4 – 9, 2007

Weather from the Bridge
Visibility: clear
Wind direction 282 NW
Wind speed: 18.9 knots
Sea wave height: 3-5 feet
Sea temperature: 10.5 C
Air temperature: 13.5 C
Sea level pressure: 1013.36
Cloud cover: 100 % status clouds

Science and Technology Log

Wind woke me up at 06:00, boat rolling. Early morning 03:00—05:00 winds were 30 knots. Casts 31, 32, and 33 processed by other teams.

Cast 34 @ 09:24 Station H3 Latitude 36.44117 N Longitude 122.01108 W Cast depth 1000 meters CTD cylinders tripped at 1000, 200, 150, 100, 80, 60, 40, 30, 20, 10, 5, 0 meters Samples processed and stored. Data for cast is Table 16 at the end of the report. Worked on chlorophyll analysis with flurometer.

Cast 35 @ 11:47 Station C1 Latitude 36.478487N Longitude 121.508392 W Cast depth 225 meters CTD cylinders tripped at 225, 200,. 150, 100, 80, 60, 40, 30, 20, 10, 5, 0 meters Samples processed and stored. Data for cast is Table 17 at the end of the report. I worked on chlorophyll analysis off and on throughout the day.

The HyperPro instrument to measure light up to 40 meters depth in the water has been tested at mid-day each day. One tube is pointed down and opposite tube is pointed up sensing light levels. A third tube is strapped to the railing registering light levels at all times. Seechi was used during the daylight hours as well. MBARI staff gave us some Styrofoam cups, two sizes, to decorate as we wanted using different permanent colored markers. We put all of them in a mesh laundry bag and attached it to a 1000-meter depth cast. When they came back up they had shrunk to 1/6^thof the original size. It demonstrates the amount of air in the Styrofoam, which should be a good illustration for my students.

Wildlife observations: humpback whales, dolphins, sea gulls, cormorants, sooty shearwaters, and albatross. Kathryn said the sooty shearwater cannot take off from the ground very well. This bird will climb up the trunk of a tree a ways and take off from there. They will wear the bark down going up a path on the tree. She hoped we would see a Yaeger bird, a bird that chases other birds that have been feeding, making them drop their food. That’s how the Yaeger feeds. It is very aggressive she said in pursuing other birds.

Moved to an area in Monterey Bay where whales had been sighted. Saw five at a distance of half a mile, sometimes a fin, but mostly the whale’s spout from the blowhole.

Packing up equipment so ready to unload early tomorrow in San Francisco.

Each day the plan of the day is posted by the FOO. I include an example at the end of the report.

We did extra stations as we are ahead of schedule. Cast 36 @23:58 nutrients only. Final station done by Troy, nutrients only at 03:00 June 9, 2007

Bed at 01:00 June 9th

June 7, 2007April 1, 2021

Elsa Stuber, June 7, 2007

NOAA Teacher at Sea
Elsa Stuber
Onboard NOAA Ship McArthur II
June 4 – 9, 2007

Weather from the Bridge
Visibility: clear
Wind direction: NW
Sea wave height: 5-8 ft.
Sea temperature: 12.79 C
Air temperature: 14.7 C
Swell wave: 5-8 ft.
Sea Level pressure: 1016.
Cloud cover: partly cloudy

Science and Technology Log

Up at 06:30. Breakfast and watched with mammal observer on flying bridge. Saw a few albatross. Very rough water, windy, cold.

Cast 21, 22 and 23 taken by other teams.

Cast 24 @ 08:55 Station 67-75 Latitude 35.5749N Longitude 123.504491 W Cast depth 1000 meters CTD cylinders tripped at 1000, 2000, 150, 100, 80, 60, 40, 30, 20, 10, 5, 0 meters Very windy. Data for cast is Table 12 at the end of the report

Cast 25 @ 11:35 Station NPS 5 Latitude 36.026137 N Longitude 123.400087 W Cast depth 1000 meters CTD cylinders tripped at 1000, 900, 800, 700, 600, 500, 400, 300, 200, 100, 50, 0 meters Nutrient samples only taken at this cast. Data for cast is Table 13 at the end of the report. Very windy (23 knots)

Spent time again on the flying bridge with mammal observer. She said on the Beaufort Scale winds above 4 one doesn’t expect to see wildlife out in the ocean. Beaufort scale today is “5”.

Casts 26, 27, and 28 ( wind 26 knots) processed by other teams.

Cast 29 @ 21:27 Station NPS 3 Latitude 36.22583N Longitude 122.57275 W Cast depth 1000 meters CTD cylinders tripped at 1000,900, 800, 700, 600, 500, 400, 300, 200, 100, 50, 0 meters Nutrients samples only collected at this cast. Very windy (wind 22 knots) and water is rough. Data for cast is Table 14 at the end of the report. Worked on chlorophyll analysis.

Took photos of some of the net tow specimen jars to show the extreme of near shore and out at sea differences in material. Specimens observed today–some shrimp, a few jellyfish, a squid, pteropods, heteropods. There is not the large amount of krill as observed in the net tow collections closer to shore.

Cast 30 @ 23:37 Station 67-60 Latitude 36.275608 N Longitude 122.466380 W Cast depth 1000 meters CTD cylinders tripped at 1000, 200, 150, 100, 80, 60, 40, 30, 20, 10, 5, 0 meters Very windy (23 knots) Samples processed and stored Data for cast is Table 15 at the end of the report.

Bed 01:00 June 8th