Tag: barnacles

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Dana Tomlinson: Day 10, March 10, 2002

NOAA Teacher at Sea

Dana Tomlinson

Aboard NOAA Ship Ka’imimoana

March 1 – 27, 2002

Date: Sunday, March 10, 2002
Lat: 1°N
Long: 110°W
Seas: 2-4 ft.
Visibility: unrestricted
Weather: partly to mostly cloudy
Sea Surf Temp: 79-82°F
Air Temp: 89-78°F

Today started out not looking so good – and I should know since I saw the sun rise behind the clouds. I have been up since 4am since I did the 4:30am CTD. The weather improved throughout the day, the seas have flattened out – you can tell we’re near the equator. By evening, it was just gorgeous – balmy, calm and a nice sunset behind the clouds. Ahhhhh.

Ok, I’ve strung you along long enough. Let’s talk barnacles. Actually, let’s talk about the hardest working woman on this ship: Raye Foster. She really is working in two capacities. She collects the barnacles off of the buoys. Those get sent to Dr. Cynthia Venn at Bloomsburg University in Pennsylvania. And she collects water samples from different depths for Dr. Victor Kuwahara of MBARI. Why does she do these two things?

Dr. Venn has been doing barnacle research in the Pacific Ocean for almost ten years now. Since the NOAA buoys are moored from 8°N to 8°S all across the Pacific, she has had the unique opportunity to have a systematic set of hard objects from which to collect the barnacles in the open ocean. She has been studying this distribution of pelagic barnacle species across the tropical Pacific and the effects of El Niño and La Niña conditions on them.

Raye scrapes the barnacles off every part of the buoy and puts them in buckets according to which part of the buoy they were on. Then she counts them and puts them in bottles and covers them in Formalin, a preservative. Then, she bags them up with notations on the baggies as to which buoy they came from and the date, and the barnacles will be eventually shipped to Pennsylvania for more research by Dr. Venn.

Raye also takes water samples from every CTD cast for Dr. Kuwahara. She does several different experiments, but the most interesting to me is the chlorophyll extractions. Dr. Kuwahara is doing research on the amount of chlorophyll in the ocean at different depths over a period of time. And once again, the systematic testing done by NOAA for their El Niño research works perfectly for this purpose also.

Raye is therefore needed at every buoy recovery for work that takes hours to scrape the barnacles off of the buoy. Then days to do the prep work to send them to Dr. Venn. She is also needed at the end of every cast to collect the water samples. Those casts are basically every 6 hours around the clock – every 4 hours here close to the equator!! Needless to say, Raye, you need a raise! Seriously, everyone on board is aware of her diligent competence. You go, girl. 🙂

Questions of the Day: 

I decided that there can’t be just one because I wrote about so many possible questions. Please answer any of these you can:

What does MBARI stand for?
What does pelagic mean?
What is chlorophyll and why is it important?

Answer of the Day: 

Since I haven’t received all of my mail from over the weekend (it’s sent to me from NOAA in Maryland), let’s save it for Monday’s log, ok?

Til tomorrow (a very busy day),
🙂 Dana

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Dana Tomlinson: Day 3, March 3, 2002

NOAA Teacher at Sea

Dana Tomlinson

Aboard NOAA Ship Ka’imimoana

March 1 – 27, 2002

Date: Sunday, March 3, 2002

Latitude: 25.5 N
Longitude: 114.8 W
Temperature: 70 F

Science Log

Research has not yet started.

Travel Log

When we went to bed last night, the moon was a harvest color just hanging on the horizon and there were 30 knot winds crossing the bow of the ship. The seas had picked up considerably and this morning we had fairly high surf with waves breaking, forming white caps wherever we looked. It wasn’t scary, but it was rough. By the afternoon, however, we had the predicted 2 to 4 foot seas, partly cloudy weather with temperatures in the mid-70’s – just lovely.

The crew continues to prepare for the many experiments and tests they will perform. Today, Ben and Brian used one of the cranes on board to move a Doppler radar device into position for future deployment. My roommate is an employee with MBARI (the Monterey Bay Aquarium Research Institute). She is going to be studying the barnacles that collect on the bottoms of the buoys that are brought on board. She’s been busy preparing her collection bottles, sewing netting to hold the samples and teaching me the difference between the types of barnacles to be found!

I’m looking forward to helping her with some of her work. More tomorrow on the other activities I’ll be involved with. I’d love to hear from you. Please email with questions and I’ll be happy to get back to you and to use the answers to some of them in this daily log.

Til then, here’s to FAIR seas and following winds!
Dana

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Jane Temoshok, October 18, 2001

NOAA Teacher at Sea
Jane Temoshok
Onboard NOAA Ship Ronald H. Brown
October 2 – 24, 2001

Mission: Eastern Pacific Investigation of Climate Processes
Geographical Area: Eastern Pacific
Date: October 18, 2001

Latitude: 20º S
Longitude: 85º W
Air Temp. 21.0º C
Sea Temp. 19.0º C
Sea Wave: 2 – 3 ft.
Swell Wave: 3 – 4 ft.
Visibility: 10 miles
Cloud cover: 5/8

Science Log

What lies beneath?

This is our third day “on station” at 85 W. Since successfully retrieving the mooring yesterday most of the scientists on board have been taking apart all the scientific instruments that came up with it. Their hope is that data was recorded all year long and that now they can transfer it to their onboard computers to bring home.

Along with that many people are preparing for tomorrow’s deployment of the new buoy. There are many things to consider, such as the length of rope (4400 meters!) and the depth order in which the instruments are to be attached. Each instrument must be placed along the rope so that it hangs precisely at a certain depth. Furthermore, the barnacles that were attached to the instruments that were brought in yesterday really made it difficult to get at the sensors. So today many of us are painting the instruments with a special paint that barnacles and other sea life don’t like. It’s called “anti-foul” paint. It’s used a lot on the bottoms of boats and such and it smells really bad! Hopefully it will make the buoy unattractive to barnacles.

The most important thing to consider though is where to put the mooring. X may mark the spot on a map, but it doesn’t work in the ocean. Just like the land around you has hills and mountains and valleys and plains the ocean floor is not smooth. In general the depth of the ocean in this part of the world is 4000 to 5000 meters. But if you needed to sink something to the bottom it would be important to know that it’s not going to land on an underwater mountaintop or be pulled down into a deep valley. The Ron Brown has a type of radar called the “sea beam” that looks straight down to the bottom of the sea and sends out acoustic signals. It measures how quickly those signals bounce off the bottom and return to the ship. This tells the computer how deep it is right there. It keeps doing this so the computer can form a picture of the bottom of the sea. It actually forms a map so the scientists can “see” where to drop the anchor.

Travel Log

MYSTERY PACKAGE

Shortly after completing our “web cast” while I was still on the bridge, the ensign on duty reported seeing an object in the water. We all took up binoculars and sighted a bright orange rectangular shaped object, about the size of a shoebox, that was floating off the starboard side. The captain quickly called the crew on deck and told them to prepare to retrieve the item as the ship approached. Of coarse everyone crowded around to see it being brought on board and was speculating as to what it might be. Drugs! Money! Perhaps a love letter! Because of its bright orange wrapping it was obviously meant to be discovered. Some speculated that it was just a piece of safety equipment that had fallen off a ship. The first thing we all noticed when it was lifted on to the deck was the barnacles attached to its underside. From this we inferred it had been in the water for several months, but because of the small size of the barnacles, probably less than a year. The captain came down and used a knife to cut it open. Alas, nothing but Styrofoam inside. We felt so let down!

In my broadcast today, I said I would give a t-shirt to the first student who could identify the signal flags on the back of the shirt. Look at the photo carefully, and if you think you know the answer, send me an e-mail. Be sure to include your name and teacher’s name so I know how to contact you! Good luck.

Question of the day: Is it necessary to paint all the instruments that will hang along the rope with anti-foul. Should the ones hanging at 50 meters get the same amount as those that hang at 500 meters or 1500 meters? Why or why not?

Photo descriptions: This is my roommate Claudia and a scientist from Ecuador helping paint the instruments with Anti-Foul Paint.

Temoshok 10-18-01 paintinginstruments

This is a photo of the Sea Beam Radar that is mapping the floor of the ocean underneath the ship.

Temoshok 10-18-01 seabeam

Here are 2 photos of the mystery package that turned out to be nothing!

Look carefully at the signal flags on the T-shirt. Do you know what letter each flag signals?

Temoshok 10-18-01 tshirtflags

Keep in touch,
Jane

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Jane Temoshok, October 17, 2001

NOAA Teacher at Sea
Jane Temoshok
Onboard NOAA Ship Ronald H. Brown
October 2 – 24, 2001

Mission: Eastern Pacific Investigation of Climate Processes
Geographical Area: Eastern Pacific
Date: October 17, 2001

Latitude: 10º S
Longitude: 85º W
Air Temp. 19.2º C
Sea Temp. 18.6º C
Sea Wave: 2 – 3 ft.
Swell Wave: 3 – 4 ft.
Visibility: 10 miles
Cloud cover: 5/8

Science Log

Mooring Retrieval Day

Did you know that glass floats? Well it does when it’s round like a balloon and full of air. Try putting a holiday ornament in a bowl of water. Did you know that glass can be stronger than steel? Well it is. That’s why 80 air filled glass balls, each 17 inches in diameter, were attached to the anchor that was holding the mooring in place at 10S, 85W. They had to be strong enough to withstand the incredible pressure at 4000 m. below the surface. But when an acoustic signal was sent out to the hook that was holding the rope to the anchor, the hook released the anchor to the bottom of the sea and the balls floated to the surface in one big group. That was the first step in retrieving the mooring.

The big deal with getting the mooring on board the ship is that it all weighs so much. Just imagine the thick rope leading from the surface all the way down to the anchor. The rope alone weighs thousands of pounds! All along the rope there are science instruments that have been collecting and storing data about things like current, temperature, and salinity. So when the glass balls floated the bottom end of the rope, it allowed us to pull it in from the bottom up. A small orange boat called a RHIB (rigid hull inflatable boat) was sent out to hook onto the balls and guide them to the ship. They were hoisted onto the deck of the ship using a big winch. Take a look at all the simple machines in the photos! Pulleys, levers, inclined planes, wheels with axels, and so much more. Slowly the rope was brought in and wrapped along a big spool. Each instrument was carefully detached and catalogued. They will be carefully transported back to Dr. Weller’s laboratory in Massachusetts where the information will be studied. The instruments from lower end of the rope came up nice and clean. The instruments that were attached to the middle part of the rope had a few creatures stuck on to them. But the instruments near the surface were covered with crabs and mussels and barnacles! How did they get there? Remember that the food chain often starts off quite small. The barnacles that you see in the photo started off as really tiny “plankton” that drift around until it finds something to attach itself to (like the rope!). Then they start to grow, attracting other sea creatures to feed off of them. In no time at all there is a complete food chain living on and around the buoy.

When most of the rope was onboard the RHIB went back out to secure the mooring. This time I got to ride along! It was thrilling to be in such a little boat so far away from the RON BROWN. Even though the sea wave height was only 3 – 4 feet, the little boat got really knocked around! It was like an amusement park ride! You can see that I’m wearing my safety vest and hardhat and I’m holding on tight! We guided the mooring to the ship and then a big crane took hold of it and lifted it onto the deck. Finally the mooring was on board.

TAS Jane Temoshok rides in the Rigid Hull Inflatable Boat (RHIB)– she’s the last blue hard hat in the back.
The RHIB heads out to retrieve 80 air-filled glass balls that were attached to the mooring’s anchor.
The floating glass balls ensure scientists can retrieve the instruments on the cable linking the anchor to the mooring buoy.
The mooring buoy brought on board.

 

Travel log:

Today was a big day on board the RON BROWN. The mooring that was set out here a year ago was located and retrieved. To the uninitiated that may not sound like the biggest deal, but it really is an unbelievable undertaking that requires a lot of forethought, communication, equipment, and muscle. The safety aspects alone require so much preparation. Fortunately it was a successful retrieval and no one was hurt. Now we get to look forward to cleaning the instruments of all those barnacles!

Science fact: The “glue” by which a barnacle sticks (adheres) to something is one of the strongest adhesives known to man!

Keep in touch,
Jane