NOAA Teacher at Sea Log:Deborah Moraga NOAA Ship: Fulmar Date: July 20‐28, 2010
Mission: ACCESS (Applied California Current Ecosystem Studies) Geographical area of cruise: Cordell Bank, Gulf of the Farallones and Monterey Bay National Marine Sanctuaries
Date: June 27,2010
Weather Data from the Bridge Start Time: 0700 (7:00 am) End Time: 1600 (4:00 pm) Position:
Line 10 start on western end: Latitude = 37o 20.6852 N; Longitude = 122o 56.5215 W
Line 10 end on eastern end: Latitude = 37 o 21.3466 N; Longitude = 122o 27.5634 W Present Weather: Started with full could cover and cleared to no cloud cover by mid day Visibility: greater than 10 nautical miles Wind Speed: 5 knots Wave Height: 0.5 meters Sea Water Temp: 14.72 C Air Temperature: Dry bulb = 14 C Barometric Pressure: 1013.2 mb
Science and Technology Log
We left Half Moon Bay at 0700 (7:00 am) to survey line 10. We traveled out to about 30 miles offshore then deployed the Tucker trawl.
Tucker Trawl
When the team deploys the Tucker trawl the goal is to collect krill. They are relying on the echo‐sounder to determine where the krill are located in the water column. The echo‐sounder sends out sound waves that bounce off objects in the water and works much like a sophisticated fish finder. Dolphins hunt for their prey in much the same way. A computer connected to the echo‐sounder is used to display the image of the water column as the sound waves travel back to the boat. By reading the colors on the screen the team can determine the depth of krill.
Collecting krillCollecting krillCollecting krill
The scientists send weights (called messengers) down a cable that is attached to the Tucker trawl as it is towed behind the boat. Once the messenger reaches the end of the line where the net is located, it triggers one of the three nets to close. Triggering the nets this way allows for the researchers to sample zooplankton at three different depths.
Image of water column on computer screenWhen the cod‐ends of the nets were brought onboard Jaime Jahncke (scientist for PRBO Conservation Science) examined the contents. Some of the organisms that were collected were.
• Thysanoessa spinifera – a species of krill
• Crab megalopa larvae
Euphausia pacifica – a species of krill
NOAA Teacher at Sea Log:Deborah Moraga NOAA Ship: Fulmar Date: July 20‐28, 2010
Mission: ACCESS (Applied California Current Ecosystem Studies) Geographical area of cruise: Cordell Bank, Gulf of the Farallones and Monterey Bay National Marine Sanctuaries
Date: June 25,2010
Weather Data from the Bridge
Start Time: 0610 (6:10 am) End Time: 1630 (4:30 pm) Position:
Line 5 start on eastern end: Latitude = 37o 48.87 N; Longitude = 122o 52.74 W
Line 5 end on western end: Latitude =37o 48.078 N; Longitude = 123o 23.04 W Present Weather: Cloud cover 100% Visibility: greater than 10 nautical miles Wind Speed: 5‐10 knots Wave Height: 0.5‐1 meters Sea Water Temp: 12.86 C Air Temperature: Dry bulb = 11 C Barometric Pressure: 1014.0 mb
Science and Technology Log
Imagine standing next to an animal that is 12 times the length of you. It happened to us aboard the R/V Fulmar. Today, humpback whales where milling around our 67 foot boat. We were able to take some great pictures and some video.
Humpback Whale
The humpback consumes krill and small fish. Krill is a small (1.5 inches in average length) shrimp like organism. Krill is a primary consumer. They feed on phytoplankton. Phytoplankton is a producer in the ocean ecosystem. These small “plants” absorb light energy from the sun and through the process of photosynthesis they make energy for the consumers to ingest and use. Krill feed on this phytoplankton at night just below the surface of the ocean. During the day the krill swim to deeper parts of the water column to avoid predators like the humpback whale.
Humpback Whale
Other organisms observed today, included a pod of Pacific white‐sided dolphins, a Tufted puffin, and South Polar Skuas.
NOAA Teacher at Sea Log:Deborah Moraga NOAA Ship: Fulmar Date: July 20‐28, 2010
Mission: ACCESS (Applied California Current Ecosystem Studies) Geographical area of cruise: Cordell Bank, Gulf of the Farallones and Monterey Bay National Marine Sanctuaries
Date: June 24,2010
Weather Data from the Bridge Start Time: 0705 (7:05 am) End Time: 1658 (4:58 pm) Position:
CBOMP Line 6 start on eastern end: Latitude = 38o 6.6066 N; Longitude = 123o 24.804 W
CBOMP Line 1 end on eastern end: Latitude = 37o 56.1066 N; Longitude = 123o 18.7206 W
Nearshore line 1 start on western end: Latitude = 38o 8.5369 N; Longitude = 123o 5.8019 W
Nearshore line 1 end on eastern end: Latitude = 38o 8.7436 N; Longitude = 122o 57.5893 W Present Weather: Cloud cover 100% Visibility: 3‐5 nautical miles Wind Speed: light, variable winds 5 knots or less Wave Height: 0 to 1.1 meters Sea Water Temp: 11.6 C Air Temperature: Dry bulb = 11 C Barometric Pressure: 1014.0 mb
We saw Dall’s porpoises riding the bow wake. Riding the bow means the porpoises were using the energy of the wave that is created by the front of the boat to body surf. It is a treat to watch them weave back and forth then leap up out of the water.
Science and Technology Log
Today we worked the Cordell Bank transect lines (COMP). We finished all six lines of bird and marine mammal observations
Marine mammals that were spotted were…
• Blue whale
• Humpbacks‐ adult & calf
• Killer whale – male & female
• Dall’s porpoises
• Harbor porpoises
• Harbor seal
• California sea lion
• Stellar sea lion
Today, the seas were very calm. This was a good thing because we had guests on board. We also surveyed near shore line one. Near shore lines take about 40 minutes traveling at 10 knots. The offshore lines take more time to survey because they are longer and we deploy the CTD and nets. On our off shore lines today we deployed the CTD seven times and took seven water samples and one of our visitors helped by collecting the last water sample of the day.
NOAA Teacher at Sea Log:Deborah Moraga NOAA Ship: Fulmar Date: July 20‐28, 2010
Mission: ACCESS (Applied California Current Ecosystem Studies) Geographical area of cruise: Cordell Bank, Gulf of the Farallones and Monterey Bay National Marine Sanctuaries
Date: June 23,2010
Weather Data from the Bridge
Start time: 0705 (7:05am) End Time: 1708 (5:08 pm) Position:
Line 2 start on eastern end: Latitude = 38o 3.4080 N; Longitude = 123o 10.9800 W
Line 2 end on western end: Latitude = 38o 2.7660 N; Longitude = 123o 33.7800 W
Line 1 start on western end: Latitude = 38o 7.8240 N; Longitude = 123o 31.9200 W
Line 1 end on eastern end: Latitude = 38o 8.3940 N; Longitude = 123o 11.5200 W Present Weather: Cloud cover 100% Visibility: 3‐10 nautical miles Wind Speed: light, variable winds 5 knots or less Wave Height: 0.25 ‐ 1 meter Sea Water Temp: 11.5 C Air Temperature: Dry bulb = 12.1 C Barometric Pressure: 1013.5 mb
Science and Technology Log
From the flying bridge…It was noted that there are unusually high numbers of some animals from Alaska ‐ such as Northern Fulmars. There were also many sightings of humpback whales, one blue whale, numerous California sea lions and Dall’s porpoises. Today was the first sighting of a fin whale recorded on an ACCESS survey. the CTD
Krill
The seas were so calm… with a swell height of 0.25 meters, you could say the ocean looked as calm as a bathtub right before you get in.
With the seas being so calm it was great to work on the back deck (stern) of the boat. Today while working line 2 we deployed the CTD six times and took hoop net samples of zooplankton at 50 meters below the surface. The Tucker trawl was also deployed (put into the water and towed behind the boat) to 200 meters. In the jars of organisms that we sampled from line 2 we found adult and juvenile krill. We found some krill with chlorophyll still in their stomachs.
Sending out the CTD
Two small fish found their way into the hoop net. Myctophid ‐ these fish live deeper during the day and come up towards the surface at night. The scales on the myctophid looked like a colored mirror and are iridescent.
Myctophid
I had the chance to do the water samples today as the CTD was deployed. To do a water sample you throw a bucket over board (attached to the boat with a line). Pull the bucket out of the water and “clean it out” by swirling the water around. Drop the bucket back into the ocean and bring it up to the deck. You then take a small vial that is labeled with the sampling location and rinse it out several times before capping with a lid. It is then placed in the freezer to be analyzed for nutrients by another agency. I was just about to cap the sample and I heard this ‘poof’ sound. I looked over and two humpback whales surfaced just meters away from me. I knew they were humpbacks, a type of baleen whale, because their blow hole is actually two holes. They started to swim off and fluked (raised their tales above the water before diving) just as I was finishing the water sample, how lucky I am to be here!
Humpback Whale
Personal Log Getting My Sea Legs
Okay, I will admit I was seasick the first day. I mean really sick. The sea was rough… 9 foot swell and even with a patch on to combat seas sickness…breakfast came up. I have not been sick again! But tomorrow is another day out at sea!
NOAA Teacher at Sea Log:Deborah Moraga NOAA Ship: Fulmar Cruise Dates: July 20‐28, 2010
Mission: ACCESS (Applied California Current Ecosystem Studies) Geographical area of cruise: Cordell Bank, Gulf of the Farallones and Monterey Bay National Marine Sanctuaries Date: June 21, 2010
The R/V Fulmar
Overview
The R/V Fulmar sets out from the dock early each morning. This ACCESS cruise has 5 members of the scientific team and myself (the NOAA Teacher at Sea.) There are two crew members for a total 8 people onboard.
The three central California National Marine Sanctuaries and the ports where the R/V Fulmar docksApplied California Current Ecosystem StudiesNational Marine Sanctuaries
ACCESS is an acronym for Applied California Current Ecosystem Studies. This is a partnership between PRBO Conservation Science, Cordell Bank National Marine Sanctuary and the Gulf of the Farallones National Marine Sanctuary. These groups of conservation scientists are working together to better understand the impacts that different organisms have on the marine ecosystem off the coast of central California.
Immersion suit for safety
They do this so that policy makers (government groups) have the most accurate data to help them make informed decisions on how the productive waters off the coast can be a resource for us and still protect the wildlife. You can read a more in depth explanation at http://www.accessoceans.org
Flying Bridge
The R/V Fulmar is a 67 foot Marine Grade Aluminum catamaran (a multi hulled vessel.) This vessel can travel 400 miles before refueling and can reach 27 knots (30 miles per hour) with a cruising speed of 22 knots (25.3 miles per hour.) Although that may sound slow compared to the cars we drive… you have to take into account that there can be 10 foot waves to go over out on the ocean.
The Fulmar’s homeport (where the boat ties up to dock most of the time) is in Monterey Bay, CA. For this cruise we will come into port (dock) in Bodega Bay, Sausalito, and Half Moon Bay. Each morning the crew wakes up an hour before the time we start out for the day. They check the oil and look over the engines, start the engines, disconnect the shore power and get the boat ready to sail out for a ten hour day.
Today (July 23, 2010) we left at 0700 (7:00 a.m.) out of Bodega Bay. Bodega Bay is on the coast of Sonoma county, California. It is from Bodega Bay that we will travel offshore to the “lines” that we will be surveying. Today we will survey lines one and two.
Then after the day’s work is done, we will sail into port, tie up to the dock and have dinner. The scientists and crew members sleep on the boat in the berths (bunks) that are located in the hulls of the boat.
Surveys
“Okay, take a survey of the types of pets your classmates have at home. Then create a graph.” How many times have math teachers assigned that assignment and expected that students knew how to survey? Today I received firsthand knowledge of how a survey takes place.
Marine scientist scanning for wildlife
Up on the flying bridge (about 5.5 meters from the surface of the ocean) scientists are surveying birds and marine mammals. There is a protocol that each follows. Here, the protocol is basically a list of agreed upon rules on how to count the marine life seen on the ocean. One researcher inputs the data into a waterproof laptop…imagine chilling at the pool and being able to surf the web! There are other researchers sitting alongside and calling out the types of birds and marine mammals they see. The researchers surveying the birds and mammals use not only their eyes but also binoculars.
Krill collected by the Trucker Trawl
After the researcher spots and identifies the birds or mammals, they call out their findings to the recording scientist in a code like fashion, doing this allows for the data to be inputted faster. The team can travel miles without Krill collected by the Trucker Trawl Researcher recording observations on the flying bridge Pacific White Sided dolphins bow riding seeing any organisms or there may be so many that the scientist at the laptop has a tough time keeping up. In this case the surveying scientist may have to write down their findings and report them when there is a break in the action.
Imagine that you are driving down the highway with your family. You have been asked to count the number humans, cows, horses, goats, dogs, cats, cars or trash on your trip. How would you make sure that your family members didn’t double count and still record all that you see? This is where protocols (instruction/rules) come in. So, let us say that you are behind the driver, and your brother or sister is in the backseat next to the window. There is also a family member in the passenger seat up front (yeah they called ‘shot gun’ before you did.) This is much like the seating arrangement on the flying bridge of the R/V Fulmar.
Researcher recording observations on the flying bridge
So how could you split up the road and area around the road so that you do not count something twice? You could split the area that you see into two parts. Take your left arm and stick it straight out the window. Have your sister/brother stick their right arm out their side window. If we drew an arc from your arm to your sibling’s arm it would be 180 degrees. Of the 180 degree arc, you are responsible for counting everything from your arm to the middle of the windshield. So, you are responsible for 90 degrees and your sibling has the other 90 degrees from the middle of the windshield to their arm.
Pacific White Sided dolphins bow riding
Once you start counting you need to record the data you are collecting. Can you write and count at the same time? Not very well, so we need someone to record the data. There are actually a lot of points of data that you need to enter.
You need to tell the recorder…
• Cue: How did you see the item you are counting?
• Method: Were you searching by eye or using a pair of binoculars?
• Bearing: The angle that the item is from the car as related to the front of the car.
• Reticle: How far the item was from your car when you first observed it (you would use your binoculars for this measurement).
• Which side of the car are you on and who is dong the observing?
• Behavior: What was the organism doing when you spotted it? Was it traveling, feeding or milling (just hanging out)?
Deploying the CTD
You also have to determine the age and sex of the organism. You need to record the species of the organism and how many you observed.
Now that is all for the species above the ground… what would you do for the animals below the road surface? On the R/V Fulmar they collect species from below the surface of the ocean and data about the water. They do this several different ways…
Bringing in the Hoop Net
1. CTD: Conductivity, Temperature, and Depth. This is a tool that records the physical properties of the ocean. It records…
a. Salinity (amount of salt in the water)
b. Temperature (how hot or cold the water is)
c. Depth (how far the instrument travels below the surface)
d. How much chlorophyll is in the water
e. Turbidity (how murky or clear the water is)
f. How much oxygen is in the water
Deploying the Tucker Trawl
2. Hoop Net: Looks like a very heavy hula hoop. Except this hoop has a cone shaped cylinder made of fine mesh attached to it. At the apex of the cone, a small PVC container, called a cod end, is attached. Zooplankton (tiny swimming animals) and some phytoplankton (tiny marine plants) are funneled into the cod end of the net as it is towed behind the boat. When the net comes back to the boat, the researchers take off the cod end and use this sample of organisms.
Collecting data from the CTD
3. Tucker Trawl: Is like three hoop nets attached together. The cool thing about this big net is that the scientists can close each net at different depths. As Map of the transect lines Retrieving the Hoop Net Phytoplankton Net the net is towed behind the boat they “close” each net to capture zooplankton at different depths. The tucker trawl is used primarily to collect krill
Map of the transect lines
Transects
Have you ever lost something in your room? Perhaps it was your homework? The bus is coming and you have to find your binder. So you start tearing your room apart. By the time the bus is five minutes away… you room looks like a disaster and you can’t remember where exactly you have looked and yet, still no binder.
Imagine a group of scientists 30 miles offshore, doing that same type of “looking” for organisms, with the captain piloting (driving) the boat any which way. Just like your binder that was missed when you were looking for it, number and location of organisms in parts of the ocean would be missing from the data set.
Retrieving the Hoop Net
So if you wanted a systematic way to look for your homework that is lost in your room, you would imagine a grid. You would have lines running from one wall to another. These lines would be parallel to each other. You would walk along the line looking for you binder. When you came to the end of the line (at your wall) you would then start on another line. By walking back and forth in your room in this systematic way, you will not miss any part of your room.
Phytoplankton Net
You have just traveled along a transect line. A transect is a path you travel and as you do you are counting and recording data. On the R/V Fulmar, scientists are counting birds, marine mammals, and collecting krill. By counting how many and what kinds of organisms are along the transect line, scientists will be able to calculate the density of organisms in a given area. There are several different types on lines that we survey. There are the near shore transects…which extend 12 kilometers from the shore (that is as long as running back a forth a football field 131 times). Offshore lines are 50 to 60 kilometers from the coast. Imagine how many football fields that would be!
Bow of R/V Fulmar
Density… Take your right hand and put it in your right front pocket of your pants and pull out all the coins you have in your pocket. Looking down at your hand you count 10 dimes. Now do the same for your left hand. You found you have two dimes. The “area” those coins were located is equal… meaning your pockets are the same size. The density of coins in your pockets is greater in your right pocket because there are more coins per square inch than in your left pocket.
Humpback Whale
The researchers on the ACCESS cruise use the data they have collected out in the field (in this case the field is the three central California National Marine Sanctuaries) to calculate the density of the organisms they are researching. They are counting and recording the number of organisms and their location so they can create graphs and maps that show the distribution of those organisms in the waters off the coast.
Taking a surface water sample
Why do they need this information? The data starts to paint a picture of the health of the ecosystem in this part of the world. With that information, they can make suggestions as to how resources are used and how to protect the waters off the California coast. By using data that has been collected over many years, suggestions can be made on how the ocean can still be utilized (used) today while insuring that future generations of humans, marine mammals, birds and krill have the same opportunities.
