Tag: northwest atlantic

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Kirk Beckendorf, July 12, 2004

NOAA Teacher at Sea
Kirk Beckendorf
Onboard NOAA Ship Ronald H. Brown
July 4 – 23, 2004

Mission: New England Air Quality Study (NEAQS)
Geographical Area: Northwest Atlantic Ocean
Date: July 12, 2004

Weather Data from the Bridge
Time 8:30 AM ET
Latitude- 42 47.28 N
Longitude- 70 42.29 W
Air Temperature 17
Air Pressure 1019 Millibars
Wind Direction at surface Southeast

Daily Log

Why are so many methods used to measure air quality, why not just one or two simple tests?

I received an email from Paige who is a student at Obsidian Middle School where I teach. She asked how air samples are taken and how air quality is measured. Those are two very big and good questions, without simple answers. This is one of the reasons that there are several hundred scientists working on NEAQS. I emailed Paige a fairly short answer but will give a more detailed explanation here. In some of the previous logs that I have written here on the BROWN, I explained some of the techniques somewhat in detail but I haven’t given you an overview, so here we go. Great questions Paige!!!

There are many different ways that the air is sampled and measured. In some cases, such as the LIDARs, samples are not taken at all. The LIDARs shoot light through the atmosphere, some of the light bounces back to the LIDAR, and this helps to measure some of what is in the air. The ozonesonde immediately and constantly measures the amount of ozone as the balloon rises through the atmosphere.

In other cases air is sucked into tubes mounted on towers at the front of the ship and the other end of the tube goes to the scientists’ equipment. (See the pictures, the big white upside down funnel and the smaller pink upside down funnel, are two of the inlets shown.) Sometimes samples are actually stored and in others the air quality is measured immediately.

Some of the instruments measure many chemicals such as one designed, built and run by Paul Goldan and Bill Kuster. It pulls in a sample of air every 30 minutes and in 5 minutes automatically measures about 150 different kinds of chemicals. It can measure the chemicals in parts per trillion. If you made some Kool-Aid that was one part per trillion, you would mix 1 drop of Kool-Aid into 999,999,999,999 drops of water. It certainly wouldn’t taste like Kool-Aid.

Other instruments measure one or just a few of the chemicals that are in the air. Today Hans Osthoff showed me a piece of equipment that he uses to measure air quality. He uses it to measure three specific chemicals in the air. One of Eric Williams’ instruments sucks in air and measures the amount of ozone every second, 24 hours a day.

Tim Bates showed me a number of pieces of equipment which suck in air and can used to find, in real time, the size and chemical composition of the particles that are floating in the air. These particles can be so small that it may take 250,000 or more laid side by side to be an inch long. Dave Covert and Derek Coffman showed me their equipment which removes particles from the air. These particles are then collected by Theresa Miller and Kristen Schulz who will analyze them. Some of the samples will be analyzed here on the ship and other samples will be analyzed once they return to Seattle.

So why not just one or two simple tests? Why so many?

Our atmosphere and the pollution in it are extremely complicated. Even though air is about 99% nitrogen and oxygen it also contains hundreds of other chemicals which are very important. Some are natural, some are man-made and some are both. This soup of chemicals is constantly changing and moving. To be able to understand pollution in the atmosphere we have to understand all of the parts. This goes back to the elephant I mentioned a few days ago. The more parts we observe and the more ways we observe the parts the better we will understand our elephant. If you feel the elephant’s leg you learn a little, if you use your nose and smell the elephant’s leg you learn a bit more, if you use your tongue and lick the elephant’s leg you will learn even more about the elephant. Understanding the pollution in our atmosphere is similar. Each type of measurement has advantages and disadvantages but each tells you more about the pollution and the atmosphere. Combined all together they can eventually give us an understanding of the whole elephant.

We had another abandon ship drill today.

Questions of the Day

What is the ozone level today where you live?

What is the level of particles where you live?

What is the maximum limit of ozone as set by the EPA (Environmental Protection Agency)?

Hint: You can probably find these on the Internet.

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Kirk Beckendorf, July 11, 2004

NOAA Teacher at Sea
Kirk Beckendorf
Onboard NOAA Ship Ronald H. Brown
July 4 – 23, 2004

Mission: New England Air Quality Study (NEAQS)
Geographical Area: Northwest Atlantic Ocean
Date: July 11, 2004

Weather Data from the Bridge
Time 8:00 PM ET
Latitude- 42 37.71 N
Longitude- 70 22.9 W
Air Temperature 17 C
Air Pressure 1018 Millibars
Wind Direction at surface Southeast
Cloud cover Partly cloudy

Daily Log

What famous event happen at Boston harbor?

It was a very eventful day today. The computer program that manages the wind profiler showed that there was a problem because one entire section was being shown in red instead of green. Dan Law asked if I would help him find out what was wrong. I jumped at the opportunity knowing that he really needed my expertise. I was very good at holding the wrench for him. As I was taking pictures of him and the inside of the profiler we were sailing into Boston Harbor. As we came into town our decks looked like those of a cruise ship. Most of the scientists were out on deck taking pictures and enjoying the view. Now everyone is back inside of their lab facilities which are mostly big shipping crates.

We spent most of the day in Boston Harbor near the end of Boston Logan Airport sampling the air in Boston. It was a beautiful weekend day and there were hundreds of sail and motorboats all around us. I didn’t see any tea floating in the water though. While soaking up the sun and enjoying the view of the harbor I helped Drew Hamilton, from NOAA’s Pacific Marine Environmental Lab in Seattle, Washington take some measurements with an instrument call a sunphotometer which measures the total amount of particles in the column of air above the instrument.

In the afternoon we left Boston and specifically to follow a cruise ship. Its exhaust was visible in the air and we criss-crossed back and forth across the plume to see what chemicals were being released by the ship. After we left the cruise ship’s exhaust plume our ship stopped so that we could do the daily launch of the ozonesonde. A little while before sunset one of NOAA’s WP-3 airplanes circled us several times. It is also sampling and measuring the chemicals in the air as part of NEAQS. Comparisons can then be made of the plane’s measurements with those made here on the ship.

The weather report is for winds to be blowing from the southwest through tomorrow so the plan is for us to travel tonight to the northwest so that we will be in the pollution blowing from Boston.

Questions of the Day

What does NEAQS-ITCT stand for?

What will our bearing be tonight if we are going northwest?

How many kinds of planes are being used in NEAQS-ITCT?

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Kirk Beckendorf, July 10, 2004

NOAA Teacher at Sea
Kirk Beckendorf
Onboard NOAA Ship Ronald H. Brown
July 4 – 23, 2004

Mission: New England Air Quality Study (NEAQS)
Geographical Area: Northwest Atlantic Ocean
Date: July 10, 2004

Weather Data from the Bridge
Latitude- 42 26.72 N
Longitude- 70 01.99 W
Air Temperature 16.5 C
Air Pressure 1013 Millibars
Wind Direction at surface- Northeast

Daily Log

How can you become an officer on a NOAA ship?

The RONALD H. BROWN is run by a crew of 24. The stewards make sure we are well fed, the engineers keep the ship’s generators running, the deck hands manage the deck equipment, the survey tech runs the science monitoring equipment and the officers run the ship. The BROWN is fairly new– it was launched in 1996. Specifically built for ocean going research, it can work in the deep ocean and in shallower water along the coast. It is well suited to be used to study either the ocean or the atmosphere. About 9 months out of the year it can be found out on the ocean doing research. After our NEAQS research cruise ends in August, the BROWN and its crew will still be out at sea doing other research until next March. That is a long time away from home for the crew.

To get a job as an officer on one of NOAA’s ships, a person needs to have at least a Bachelors degree with specific requirements in math and science. There are physical fitness requirements as well. Once accepted a person must then attend a special mariner’s training school. Of course once you become an officer on a ship there is still lots of on the job training.

Today Lt. Liz Jones gave me a tour of the bridge. The ship does not have a propeller like many ships and it does not have a big wheel to steer the ship like you see in the movies. Instead of a propeller it has three thrusters. Each is kind of like a funnel turned sideways where the water goes in the big end and gets forced out the little end pushing the ship in the opposite direction. The three thrusters can be rotated individually and in a complete circle to push the ship in any direction. Even in an ocean current it can stay in one spot by using the thrusters. They can also be loud. The bow thruster is next to my stateroom. Sometimes it keeps me awake when it is turned on an off during the night. Instead of the big wheel, there are a couple of ways to maneuver the ship. On the bridge are three levers, one for each thruster. In some situations when you don’t want to worry about three different levers there is a joy stick that can be used to control the ship.

Lt. Jones said one of the main jobs a person has when on the bridge is to constantly be aware of the surroundings. Looking for other ships, keeping an eye on the weather and watching the charts to know the water depth are all extremely important. The BROWN can run on autopilot to make sure it maintains its course or position even if winds, waves or currents are pushing it in another direction. Even though the bridge is loaded with state of the art electronic equipment like GPS, radars, autopilot and depth finders the crew on watch still uses paper charts and binoculars so that they are not dependant on the electronics.

Questions of the Day

What is the NOAA Corps?

Which side of the ship is starboard and which side is port?

Which end of the ship is the bow and which is aft?

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Kirk Beckendorf, July 9, 2004

NOAA Teacher at Sea
Kirk Beckendorf
Onboard NOAA Ship Ronald H. Brown
July 4 – 23, 2004

Mission: New England Air Quality Study (NEAQS)
Geographical Area: Northwest Atlantic Ocean
Date: July 9, 2004

Weather Data from the Bridge
Time 8:00AM ET
Latitude- 43 43.31N
Longitude- 66 15.13 W
Air Temperature 11 C
Air Pressure 1010 Millibars
Wind Direction at surface SE
Wind Speed at surface <5 MPH
Wind Direction at 1 Kilometer- E
Wind Speed at 1 Kilometer <5 MPH
Wind Direction at 2 Kilometers E
Wind Speed at 2 Kilometer <5 MPH
Cloud cover and type Fog

Daily Log

One of the blind men observed an elephant and said it is like a tree, another said it was like a rope, another said it is like a water hose. Which was correct?

This morning I visited with Christoph Senff and Rich Marchbanks. After lunch I visited with Alan Brewer. All three are here from NOAA’s Environmental Technology Lab in Boulder, Colorado. Chris and Rich are operating a LIDAR, which remotely measures amount of ozone in the atmosphere. Alan has a Doppler LIDAR which remotely measures wind speed and direction. By “remotely,” that means they can measure ozone and wind from 3-4 kilometers away. An amazing thing about many of the instruments on board is that they have been designed and built by the scientists themselves. They can’t just run down to some high-tech store and buy their equipment, what they need isn’t for sale anywhere. They decide what needs to be done, and then they design and build the equipment that will do the job. The LIDARS that are being used here on the BROWN and in the rest of NEAQS project are examples of some of that “homemade” equipment.

In the case here on the ship “homemade” certainly does not mean it is just thrown together, held up with bubble gum, baling wire and duct tape. The LIDARS and the other instruments on board are extremely intricate, sophisticated and complicated devices.

To understand the very basics of how a LIDAR can detect ozone and air movement forget about LIDARS and just think about a normal flashlight. Pretend that you go outside in the middle of a completely dark night, no light from anywhere. Point your flashlight straight up and turn it on. Now imagine that there are a flock of white pigeons circling overhead, you will not see them unless the light from your flashlight hits them and then bounces back into your eye (hopefully it’s just the light that gets in your eye).

Now imagine that several of the pigeons poop and their poop is completely black and is between you and the pigeon. Yeah I know pigeon poop is usually white but for now pretend it is black. Because the poop is completely black when your beam of light hits the poop the light will not bounce off, instead it will be absorbed by the poop. The more poop in the air the more of the light is absorbed and less light bounces back to your eye.

Picture this. You are standing in the dark with your flashlight. The pigeons are circling over your head- between you and them is their poop. Quickly turn your flashlight on and then back off and measure the amount the amount of light that leaves. The light shoots up through the poop (which absorbs some of the light) and hits the pigeons. Some light bounces off the pigeons back through the poop and to your eye. You measure the light that comes back. By figuring out how much light was absorbed by the poop you can get an idea of how much is in the air above you.

Instead of visible light other wavelengths of light, like ultraviolet (UV) and infrared (IR), are used. Christoph, Rich and Alan use a laser rather than a flashlight and their LIDARs can turn the light on and off in nanoseconds. They can also measure many things about the light that leaves the laser and the light that returns.

Let’s take this one step further. Imagine that flashlight, dark night and poop and pigeons over head again. Also imagine that you can measure how long it takes for the beam of light to go out to some pigeons and then bounce back to your eye. If you know how fast the light is going you could calculate how far away they are and where the poop is located. If we put this all together and measure both how much light bounces back and how much time the light has traveled, you could determine the amount of poop at different distances.

Enough pretending and imagining, lets get back to the LIDARs. Light travels approximately 186,000 miles every second (it is about 25,000 miles around the equator) and the LIDARS can measure the time it takes the light to travel just a few hundred yards. Rich and Christoph’s ozone LIDAR is sensitive enough to measure ozone in parts per billion from 2-3 kilometers away and Alan’s LIDAR can measure wind speed and direction 3-4 kilometers away from here. They do this using a principal similar to the flashlight example, but obviously much more complicated. Chris and Rich’s ozone LIDAR uses a UV laser, picked specifically because its light will bounce off particles in the air (the pigeons) and be absorbed by ozone molecules (the pigeon poop). Allan uses an infrared laser that will bounce off particles floating and moving with the air. The particles, which are much too small to be seen would, as Allan said, seem like boulders to the beam of light.

What that all means, is that for the next six weeks along the ship’s path, the LIDAR’s will be measuring the amount of ozone pollution in the atmosphere, the wind speed and the wind direction.

The ozone LIDAR’s will eventually be used to show the amount and location of ozone pollution in the atmosphere from about 50 meters above the ocean surface up to 2-3 kilometers. The Doppler LIDAR data will be used to make a similar map of the wind speed and direction during the 6 weeks at sea. Eventually these and other data can be merged and compared.

What about those blind men examining the elephant? The first had grabbed the leg, the second had grabbed the tail and the third had grabbed the trunk. None of them of course had a complete picture of the elephant. During NEAQS-ITCT, hundreds of people are examining an elephant this summer. Individually they cannot give us a clear picture of the elephant. The elephant is air pollution. The more parts that can be accurately examined the better the picture. Instead of a trunk, tail and leg to observe, the scientist are examining the many kinds of chemicals in the pollution, the particles in the air, the movement of the pollution and the movement of the air. Different methods can be used to insure accuracy. Once each part of the elephant has been thoroughly examined and understood and all of the blind men evaluate their observations maybe they will have at least a partial picture of the elephant.

Question of the Day

What does LIDAR stand for?

How much of a second is a nanosecond?

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Kirk Beckendorf, July 8, 2004

NOAA Teacher at Sea
Kirk Beckendorf
Onboard NOAA Ship Ronald H. Brown
July 4 – 23, 2004

Mission: New England Air Quality Study (NEAQS)
Geographical Area: Northwest Atlantic Ocean
Date: July 8, 2004

Weather Data from the Bridge
Time 9:08 AM ET
Latitude- 42 28.14 N
Longitude- 67 47.02 W
Water Temperature 7 C
Wind Direction at surface East
Wind Speed at surface <5 MPH
Wind Direction at 1 Kilometer- West
Wind Speed at 1 Kilometer <5 MPH
Wind Direction at 2 Kilometers West
Wind Speed at 2 Kilometer 5 MPH
Cloud cover and type Fog

Daily Log

What should we do if someone fell overboard or if we had to abandon ship?

Today we are just off the southern coast of Nova Scotia, Canada. It has been foggy all day so we cannot see very far past the ship’s railing. If anyone fell overboard it would be extremely difficult to find them. With the water temperature at 7 degrees C a person would be hypothermic very soon if they were in the water.

I helped Anne again with today’s ozonesonde. The launch did not go as smoothly as yesterday’s. Before releasing the balloon the computer was not receiving a signal from the sonde. After Anne checked out a number of things that could be wrong we attached a different radiosonde, which is the part that sends the signal to the computer. With that change the problem was immediately solved. The sonde detected three layers of ozone pollution and of course the good ozone layer.

The ship’s crew keeps a written record of all ships sighted from the bridge. Today I typed the information into a computer spreadsheet. The scientists will then be able to compare these contacts to their pollution data.

Safety is a major concern on the ship. At school we have fire drills, here on the BROWN we have Abandon Ship and Man Overboard drills. Today when we heard the Abandon Ship alarm (6 short blasts from the whistle followed by one long blast), we rushed to our stateroom (bedroom), grabbed our life jacket, long pants, long sleeve shirt, hat and survival suit. If this were a real emergency we need to have clothes that will protect us from the weather and sun while we are floating in a life raft. We then rushed to our preassigned meeting areas on deck. One of the ship’s crew called roll. Afterwards we practiced putting on our bright red survival suits. The suits are designed to help keep us warm, floating and easy to see.

When the Man Overboard alarm was sounded (three long blasts from the ships whistle) the scientists and myself met in the main science lab to get a head count. Meanwhile as part of the drill, the crew had thrown a “dummy” overboard. They quickly launched one of the small boats and sped away to rescue the “man overboard”. The dummy was rescued quickly. If someone were to fall overboard while the ship is moving and no one realized they were missing, it would be very difficult to find and rescue them since we would not know how far away to look.

Questions of the Day

What is the maximum amount of ozone pollution an area can have without being in violation of the Environmental Protection Agency (EPA) standards?

What is the temperature of the water in degrees F here off the coast of Nova Scotia?

What is the bridge of a ship?

What does hypothermic mean?