Mission: Mapping CINMS Geographical area of cruise: Channel Islands, California Date: May 8, 2016 Weather Data from the Bridge:
Science and Technology Log
Seafloor in the CINMS
In previous posts, I’ve discussed the ME70 multibeam sonar on board Shimada. You’d think that I’ve told you all there is to know about the wondrous data this piece of equipment provides, but oh, no, dear readers, I’ve merely scraped the surface of that proverbial iceberg. In this post, I will explain how the raw data from the ME70 is used to create important seafloor maps. Heck, I’ll even throw in a shipwreck! Everyone loves shipwrecks.
Nichia Huxtable, Diana Watters, ME70, and EK60; aboard Shimada
Back to the multibeam. As you may remember, the ME70 uses many beams of sonar to capture a 60 degree image of the water column. It collects A LOT of data, one survey line at a time. Lots of data are good, right? Well, if you want to map the bottom of the ocean, you don’t need ALL the data collected by the ME70, you just need some of it. Take, for example, fish. You don’t want big balls of fish obscuring your view of the seafloor, you just want the seafloor! Leave the schools of fish for Fabio.
Mapping maven Kayla Johnson
The person you need to make your seafloor map is Kayla Johnson. First, she sends the raw data to a program called MatLab. This nifty software separates the bottom data from all the other stuff in the water column and packages it in something called a .gsf file. Next, this .gsf file goes to this huge processing program called CARIS HIPS, where it is converted into an something called HDCS data.
You’d think that all you’d need to make an accurate seafloor map would be data from the multibeam, but it is actually much more complicated than that (of course you knew that! just look at how long this blog post is). Think about it: while you’re running your survey lines and collecting data, the ocean and, therefore, the ship are MOVING. The ship is heaving, rolling, and pitching, it’s travelling in different directions depending on the survey line, the tides are coming in and out, the temperature and salinity of the water varies, etc. etc. All of these variables affect the data collected by the ME70 and, hence, must be accounted for in the CARIS software. Remember how I said it was HUGE? This is why.
Cross-section of the topography found in the CINMS
Everyone still with me? Ok, let’s continue processing this data so that Kayla can make our beautiful map. Next up, she’s going to have to load data into CARIS from the POS. POSMV (POSition of Marine Vehicles) is a software interface used on the ship that collects real-time data on where we are in relation to the water (heave, pitch, and roll). She’s also going to load into CARIS the local tide information, since the ship will be closer to the seafloor at low tide than at high. Not including tidal change is a good way to get a messed-up map! Once the POSMV and tide files are loaded into CARIS, they are applied to the survey line.
Completed map around San Miguel Island
Next, Kayla has to compute the TPU (Total Propagated Uncertainty). I could spend the next four paragraphs explaining what it is and how it’s computed, but I really don’t feel like writing it and you probably wouldn’t want to read it. Let’s just say that nothing in life is 100% certain, so the TPU accounts for those little uncertainties.
Since the data was collected using multiple beams at a wide angle, there will be beams returning bad data, especially at the edges of the collection zone. Sometime a bad data point could be a fish, but most often bad data happens when there is an abrupt change in seafloor elevation and the beams can’t find the bottom. So, Kayla will need to manually clean out these bad data points in order to get a clean picture of the seafloor.
These data need a haircut!
Cleaned data
Almost done! Last, Kayla makes the surface. All the data points are gridded to a certain resolution based on depth (lots of explanation skipped here…you’re welcome), with the end result being a pretty, pretty picture of the bottom of the seafloor. Phew, we made it! These seafloor maps are incredibly important and have numerous applications, including fisheries management, nautical charting, and searching for missing airplanes and shipwrecks (see! I told you there would be a shipwreck!). I’ll be getting into the importance of this mapping cruise to the Channel Islands Marine Sanctuary in my final post, so stay tuned.
Shipwreck in Buzzard’s Bay, MA image courtesy of NOAA Ship Thomas Jefferson
U-boat image courtesy of NOAA Ship Thomas Jefferson
Endnote: A word about XBTs
Deploying an XBT off Shimada
Before all your data are processed, you need to know how fast the sound waves are travelling through the water. When sound is moving through water, changes in temperature and salinity can bend the wave, altering your data. An XBT is an expendable bathythermograph that is sent overboard every four hours. It transmits temperature and salinity readings throughout its quick trip to the ocean bottom, allowing the computer to make data adjustments, as needed.
Did You Know?
Hey, you’ve made it to the bottom of this post! If you are interested in seafloor mapping, have I got an institute of higher learning for you. The College of Charleston has a program called BEAMS, which trains future ocean surveyors and includes a course called Bathymetric Mappings. Three of the hip young scientists on board have taken this course and it seems to be pretty amazing. If you love sailing the high seas AND data processing, you might want to check it out.
NOAA Teacher at Sea Cristina Veresan Aboard NOAA Ship Oscar Dyson July 28 – August 16, 2015
Mission: Walleye Pollock Acoustic-Trawl survey Geographical area of cruise: Gulf of Alaska Date: Wednesday, August 13, 2015
Data from the Bridge: Latitude: 59° 18.31’N
Longitude: 141° 36.22’W
Sky: Overcast
Visibility: 10 miles
Wind Direction: 358
Wind speed: 8 knots
Sea Wave Height: < 1 feet
Swell Wave: 2-3 feet
Sea Water Temperature: 16.2°C
Dry Temperature: 15°C
Science and Technology Log
When my shift begins at 4am, I often get to participate in a few “camera drops” before the sun comes up and we begin sailing our transect lines looking for fish. We are conducting the “camera drops” on a grid of 5 km squares provided by the Alaska Fisheries Science Center bottom trawl survey that shows whether the seafloor across the Gulf of Alaska is “trawlable” or “untrawlable” based on several criteria to that survey. The DropCam footage, used in conjunction with a multi-beam echosounder, helps verify the “trawlability” designation and also helps identify and measure fish seen with the echosounder.
The Drop Camera being deployed
The DropCam is made up of strobe lights and two cameras, one color and one black and white, contained in a steel frame. The cameras shoot in stereo, calibrated so scientists can get measurements from rocks, fish, and anything else on the images. When the ship is stopped, the DropCam can be deployed on a hydrowire by the deck crew and Survey Tech. In the Chem Lab, the wire can be moved up and down by a joystick connected to a winch on deck while the DropCam images are being viewed on a computer monitor. The ship drifts with the current so the camera moves over the seafloor at about a knot, but you still have to “drive” with the joystick to move it up and down, keeping close to the bottom while avoiding obstacles. The bottom time is 15 minutes for each drop. It’s fun to watch the footage in real-time, and often we see really cool creatures as we explore the ocean floor! The images from the DropCam are later analyzed to identify and length fish species, count number of individual fish, and classify substrate type.
Emily “drives” the camera from the Chem Lab as the sun begins to riseDropCam images (clockwise from top left) a skate, brittle stars, a cruising halibut, two rockfish in rocky habitat
Technology enables scientists to collect physical oceanographic data as well. The Expendable Bathythermograph (XBT) is a probe that is dropped from a ship and measures the temperature as it falls through the water column. The depth is calculated by a known fall rate. A very thin copper wire transmits the data to the ship where it is recorded in real-time for later analysis. You launch the probe from a hand-held plastic launcher tube; after pulling out the pin, the probe slides out the tube. We also use a Conductivity Temperature Depth (CTD) aboard the Oscar Dyson; a CTD is an electronic device used by oceanographers to measure salinity through conductivity, as well as temperature and pressure. The CTD’s sensors are mounted on a steel frame and can also include sensors for oxygen, fluorescence and collecting bottles for water samples. However, to deploy a CTD, the ship must be stopped and the heavy CTD carousel lowered on a hydrowire. The hand-held XBT does not require the ship to slow down or otherwise interfere with normal operations. We launch XBT’s twice a day on our survey to monitor water temperatures for use with the multi beam echosounder.
Cristina launching the XBT probe Photo by Alyssa PourmonirSurvey Tech Alyssa servicing the CTD carousel
Shipmate Spotlight: An Interview with Ensign Benjamin Kaiser
Ensign Benjamin Kaiser, NOAA Corps
Tell me a little more about the NOAA Corps? We facilitate NOAA scientific operations aboard NOAA vessels like hydrographic work making charts, fisheries data collection, and oceanographic research.
What do you do up on the bridge? I am a Junior Officer of the Deck (JOOD), so when I am on the bridge driving the ship, I am accompanied by an Officer of the Deck (OOD). I am on my way to becoming an OOD. For that you need 120 days at sea, a detailed workbook completed, and the Commanding Officer’s approval.
What education or training is required for your position? I have an undergraduate degree in Marine Science from Boston University. My training for NOAA Corps was 19 weeks at the Coast Guard Academy in New London, Connecticut– essentially going through Coast Guard Officer Candidate School.
What motivated you to join the NOAA Corps? A friend of mine was an observer on a fisheries boat, and she told me about the NOAA Corps. When I was in high school and college, I didn’t know it was an option. We’re a small service, so recruiting is limited; there’s approximately 320 officers in the NOAA Corps.
What do you enjoy the most about your work? I love not being in an office all the time. In the NOAA Corps, the expectation is two years at sea and then a land assignment. The flexibility appeals to me because I don’t want to be pigeonholed into one thing. There are so many opportunities to learn new skills. Like, this year I got advanced dive training for Nitrox and dry suit. I don’t have any regrets about this career path.
What is the most challenging part of your work? There’s a steep learning curve. At this stage, I have to be like a sponge and take everything in and there’s so much to learn. That, and just getting used to shipboard life. It is difficult to find time to work out and the days are long.
What are your duties aboard the Oscar Dyson? I am on duty 12pm to midnight, rotating between working on the bridge and other duties. I am the ship’s Safety Officer, so I help make sure the vessel is safely operating and coordinate drills with the Commanding Officer. I am also the Training Officer, so I have to arrange the officers’ and crew members’ training schedules. I am also in charge of morale/wellness, ship’s store, keys, radios, and inspections, to name a few.
When did you know you wanted to pursue a marine career? I grew up in Rhode Island and was an ocean kid. I loved sailing and swimming, and I always knew I would have an ocean-related career.
How would a student who wanted to join the NOAA Corps need to prepare?
Students would need an undergraduate degree from a college or university, preferably in a STEM field. Students could also graduate from a Maritime Academy. When they go to Officer Candidate School, they need to be prepared for a tough first week with people yelling at them. Then there’s long days of working out, nautical science class, drill work, homework, and lights out by 10pm!
What are your hobbies? I enjoy rock climbing, competitive swimming, hiking, and sailing.
What do you miss most while working at sea? There’s no rock climbing!
What is your favorite marine creature? Sailfish because they are fast and cool.
Inside the Oscar Dyson: The Chem Lab
This lab is called the Chem Lab (short for Chemical). For our survey, we don’t have that many chemicals, but it is a dry lab with counters for workspace when needed. This room is adjacent to the wet lab through a watertight door, so in between trawls, Emily and I spend a lot of time here. In the Chem Lab, we charge batteries for the CamTrawl and the DropCam. There are also two computer stations for downloading data, AutoLength analysis, and any other work (like blogging!). There is a window port to the Hero Deck, where the CTD and DropCam are deployed from. In the fume hood, we store Methot net samples in bottles of formalin. There is a microscope for viewing samples. Note the rolling chairs have their wheels removed and there are tie-downs on cases so they are safer at sea. Major cribbage tournaments are also played in this room!
Personal Log
It has been so calm on this cruise, but I have to say that I was looking forward to some bigger waves! Well, Sunday night to yesterday afternoon we experienced some rain and rough seas due to a nearby storm. For a while the ship would do big rolling motions and then a quick lurchy crash. Sea waves were about 2 feet in height, but the swell waves were over 5 feet at times. When I was moving about the ship, I’d have to keep a hand on a rail or something else secured. In the wet lab while I was working, I would lean against the counter and keep my feet spread apart for better balance.
Seas picked up and the ship was rocking and rolling!
Remember the Methot net? It is the smaller net used to catch macroplankton. We deployed one this week and once it came out of the water, it was rinsed and the codend was unscrewed. When we got the codend into the wet lab, we realized it was exclusively krill!
The Methot net is deployed by the Survey Tech and deck crew members#krillfordays
Krill are small crustaceans that are found in all the world’s oceans. Krill eat plant plankton (phytoplankton), so they are near the bottom of many marine food chains and fed on by creatures varying from fish like pollock to baleen whales like humpbacks. They are not so small that you need a microscope to see them, but they are tiny. We took a subsample and preserved it and then another subsample to count individuals…there were over 800 krill in just that one scoop! Luckily, we had them spread out on a board and made piles of ten so we did not lose count. It was tedious work moving individual krill with the forceps! I much prefer counting big things.
I love it when there is diversity among the catch from the AWT trawls. And, we caught some very memorable and unique fish this week. First was a beautiful Shortraker Rockfish (Sebastes borealis). Remember, like the Pacific Ocean Perch, its eyes bulge when its brought up from depth. The Shortraker Rockfish is an open-water, demersal species and can be one of the longest lived of all fish. There have been huge individuals caught in Alaskan waters that are over 100 years old. This fish was not particularly big for a Shortraker, but I was impressed at its size. It was probably my age.
Holding a Shortraker Rockfish. Photo by Emily CollinsSmooth Lumpsucker fish: so ugly it’s cute?! Photo by Mackenzie Wilson
We also caught a Smooth Lumpsucker (Aptocyclus ventricosus). It was inflated because it was brought up from depth, a form of barotrauma. This scaleless fish got its name for being shaped like a “lump” and having an adhesive disc-shaped “sucker.” The “sucker,” modified pelvic fins, are located ventrally and used to adhere to substrate. These pelagic fish are exclusively found in cold waters of the Arctic, North Atlantic, and North Pacific. The lumpsucker fish, and its roe (eggs) are considered delicacies in Iceland and some other countries.
You can see the “sucker” on the bottom of its body. Photo by Mackenzie Wilson
Pollock are pretty slimy and they have tiny scales, so when we process them, everything gets covered with a kind of speckled grey ooze. However, when we trawled the other day and got a haul that was almost entirely Pacific herring (Clupea pallasii), I was amazed at their scales. For small fish, the herring had scales that were quite large and glistened like silvery sequins. The herring’s backs are an iridescent greenish-blue, and they have silver sides and bellies. The silver color comes from embedded guanine crystals, leading to an effective camouflage phenomenon in open water.
As this last week comes to a close, I am not ready to say goodbye…
NOAA Teacher at Sea Vincent Colombo Aboard NOAA Ship Oscar Dyson June 11 – 30, 2015
Mission: Annual Pollock Survey Geographical Area of Cruise: The Gulf of Alaska Date: June 15, 2015
Weather Data from the Bridge:
Wind Speed: 4.52 knots
Sea Temperature: 8.5 degrees C
Air Temperature: 6.4 degrees C
Air Pressure: 1034.33 mb
A United States Coast Guard Sikorsky MH-60 Jayhawk flying over the deck of the Oscar Dyson
Science and Technology Log:
Are you a morning person? How about a night owl? Well if you said yes to the first question, then Alaska during the summer is your place to be. Currently where we are right now, the sun officially rises at 5:08 and sets at 23:12 (that’s 11:12 pm for those of you not used to 24 hour format). But, do not think that it means it turns dark by any means. Sunrise and Sunset are when the sun is officially seen, or disappears on the horizon respectively. So far in my time spent here in Alaska, I have only seen it dark for about one hour.
The 23.5 degree tilt of the Earth exaggerates the effect of the sun during the time around a solstice
The reason why is easily explained, seasons. Students in Delaware learn about seasons in 8th grade, and again if they take Physics or Astronomy in high school. The tilt of the earth causes the northern hemisphere to be more exposed to the sun for longer periods of time. Thus the concept of day and night is greatly changed.
In order to fully grasp this concept, you must also understand why it never gets dark either. The term we use is twilight, or the time between darkness and sunrise in the morning, and sunset and complete darkness in the evening. Twilight is also defined as when there is light outside, but the sun is below the horizon.
There are 3 types of twilight: civil, nautical, and astronomical.
Civil twilight occurs when the Sun is between 0 degrees and 6 degrees below the horizon. In the morning, civil twilight begins when the Sun is 6 degrees below the horizon and ends at sunrise. In the evening, it begins at sunset and ends when the Sun reaches 6 degrees below the horizon. Typically civil twilight begins and ends one half hour before or after sunrise or sunset. Most outdoorsmen know this as the 1/2 hour before and after rule. If you’re a deer hunter, civil twilight signifies legal shooting time has begun or ended.
Nautical twilight occurs when the geometrical center of the Sun is between 6 degrees and 12 degrees below the horizon. Nautical twilight is usually an hour before and after sunset. This twilight period is less bright than civil twilight and artificial light is generally required for activities.The term, nautical twilight, dates back to the time when sailors used the stars to navigate the seas. During this time, observers on Earth can easily see most stars. Although not completely dark outside, one could safely get around.
Last is Astronomical twilight, and this occurs when the Sun is between 12 degrees and 18 degrees below the horizon. In the morning, the sky is completely dark before the onset of the astronomical twilight, and in the evening, the sky becomes completely dark at the end of astronomical twilight. This is typically an hour and a half before or after sunrise or sunset respectively.
During the summer months, especially around the Summer Solstice, the North and South Poles experience several days with no complete darkness at all. Currently our civil, nautical, and astronomical twilights are exaggerated, only leaving about an hour of actual darkness.
My next scientific topic I would like to discuss is the system the vessel Oscar Dyson uses called Dynamic Positioning. When we were calibrating the acoustic equipment in my last post, the ship did not move more than 0.3 meters in any direction.
Dynamic positioning diagram
The ship uses GPS systems to hold it in one single place for a period of time. Using a minimum of three satellites and triangulation, the ship’s position is able to be maintained. The ship uses its main engines as well as bow thrusters to keep it steady in one position. I was also introduced to some new vocabulary:
surge: moving the ship forward or back (astern)
sway: moving the ship starboard (right) or left (port)
heave: moving the ship up or down
roll: the rotation about surge axis
pitch: the rotation about sway axis
yaw: the rotation about heave axis
How a ship is able to maintain its position
Not only can the ship stay in one position, I also learned that it can stay in one position over a column of water, which is vital for a research ship like the Oscar Dyson when conducting research one specific area of the ocean.
A view of the dynamic positioning monitor from the bridgeA view of the current state of the rudder of the ship. It changes as the dynamic positioning controls the shipThe bow thruster control on the bridge of the ship
Personal Log:
It took us almost three days to reach where the scientific study was to begin. For those of you who know me, it is hard for me to stay in one place for an extended period of time. Luckily the ship has an abundance of DVDs to watch, Direct TV and a fantastic galley (aka kitchen) to make it feel more like home. I can honestly say the food is some of the best I have ever eaten.
Luckily (knocking on wood), our ship has not hit any rough seas. It has taken a day or so to get used to the rocking, just make sure you have a free hand to grab hold of something when moving about.
Underway, I got to deploy the first An Expendable Bathy Thermograph or XBT for short. You can find out more by going to this NOAA website: XBT uses
Getting briefed on use of the sensor. Notice I am harnessed in.Deploying the sensor
According to our Executive Officer, LT Carl Rhodes, we will be seeing some AMAZING Alaskan geography including volcanoes. Check back for some awesome photos.
NOAA Teacher at Sea Dieuwertje “DJ” Kast Aboard NOAA Ship Henry B. Bigelow May 19– June 3, 2015
Mission: Ecosystem Monitoring Survey
Geographical area of cruise: East Coast Date: May 18, 2015 (Pre-cruise)
Personal Log
Chris Melrose picked me up from the hotel and really helped me get a grasp of life aboard a research vessel. I learned all about Narragansett Bay and the lab here in Rhode Island.
I then met Jerry Prezioso, the Chief Scientist for the voyage, who gave me a great tour of the Narragansett Bay Lab. I learned what an XBT (expendable bathythermograph) was and how it measures temperature at various depths.
XBT Photo by: DJ Kast
I learned how a Niskin bottle works and how many Niskin bottles lined up in a circle to make a piece of equipment called a rosette. The Niskin bottle is like a hollow tube with a mechanism that closes the tube at a specific depth that will then bring a water sample indicative of that depth. They apparently cost $400 each. I am already making plans on how to make a DYI one for the classroom.
Niskin Bottle Photo by: DJ KastThis is a Rosette with 12 niskin bottles. Photo by: DJ Kast
With Jerry, I also met Ruth Briggs who works for the Narragansett Bay Apex Predators division and she showed me the shark tags that she has citizen scientists put onto sharks on the base of their dorsal (top) fin that they catch. When the sharks are caught again, the information she requests is sent back to her and includes species, size, sex, location to shore, and weight. She even let me borrow a decommissioned tag to show to my students in California.
Decommissioned shark tag from the Narragansett Bay Apex Predators Division Photo by: DJ Kast
I saw a drifter buoy that I will be decorating with all of my programs (USC, JEP, YSP and NAI) logos.
Jerry also sent me the map of all the stations that we will be visiting on our ship and at each station we are projected to measure salinity, depth, temperature, nutrients and plankton! I am so excited! We are expected to go as far south as North Carolina and as far north as the Bay of Fundy in Canada (International Waters!!!).
TAS and the NOAA Ship Arrival
My stateroom is amazing! My roommate and I even have our own head (bathroom) in our room with sink, shower and all. There are two beds in a bunk bed format, and since I showed up about 6 hours before the other scientists I chose the bottom bunk and the cabinet I wanted for my stuff. I unpacked (and gladly didn’t over pack) and managed to fit it all in the closet that was given to us. I feel so fortunate to have such amazing accommodations like this.
Important People who Keep the Ship Afloat and on Course
Today I met the Operations Officer, Laura, who showed me the ropes and introduced me to people on the ship at dinner at the bowling alley on the naval base here in Newport, RI. She also showed me the buoy yard filled with lots of different buoys that indicate different paths of travel and safe/unsafe waters for ships coming into port.
I entered a yard of buoys on the Newport Naval Base and here I am for a size comparison. They are HUGE!Here is a look at what happens when a buoy is freshly painted and when its being fouled by marine organisms and algae (RUST!) Photo by: DJ Kast
Important Ship Personnel CO: Commanding Officer
XO: Executive Officer
CME: Chief Marine Officer
OO or Ops: Operations Officer= Laura
NO: Navigational Officer or Nav= Eric
CB: Chief Boson or Deck Boss= Adrian
AB: Able Seaman or a Deckhand = Roger
Meal Schedule
I also learned about food times (Very important).
7AM- 8 AM or 0700-0800 hours= Breakfast
11- 12 PM or 1100-1200 hours= Lunch
5- 6 PM or 1700-1800 hours = Dinner
Roommate in Stateroom 2-22
DJ Kast on the Gangway Photo by: DJ KastHere I am boarding the NOAA Henry B. Bigelow Photo by: DJ Kast
I met my amazing roommate Megan and she is a master’s student at the University of Maine. We will sadly have opposite schedules for most of the trip because I will be on the 12 PM- 12 AM shift and she will be on the 12 AM- 12 PM shift. We have a lot of things in common including our love of the ocean, geology and Harry Potter. She will be looking at dissolved nutrients in the water and she will be monitoring the instruments that measure conductivity, temperature and depth or (CTD) and requesting water samples while at various stations.
NOAA Teacher at Sea Theresa Paulsen NOAA Ship Okeanos Explorer March 16 – April 3, 2015
Mission: Caribbean Exploration (Mapping) Geographical Area: Puerto Rico Trench Date: March 24, 2015
Weather from the Bridge: Scattered Clouds, 26.6˚C, Wind 10kts from 100˚, Waves 1-2ft, swells 2-3ft
Science and Technology Log
Now that the interns have been trained in data collection and processing, it was my turn to learn.
Mapping Intern Chelsea Wegner taught me how to launch an XBT and how to process the data gathered by the multibeam sonar. It is a fairly simple procedure that requires diligent record keeping in logs. I processed four “lines.” A line is about one hour of data collection, or shorter. Two of my lines were shorter because the sonar had to be turned off due to a whale sighting! This is bad for data collecting, but AWESOME for me! Again, I missed it with the camera, though.
My Mapping Instructors: Intern, Chelsea Wegner; Expedition Coordinator, Meme Lobecker; and Mapping Watch Lead, Jason Meyer.
I have also been given the task of using a sun photometer to measure direct sunlight over the ocean as part of the Maritime Aerosol Network, a component of AERONET, a NASA project through the Goddard Space Flight Center. Every two hours when the sun is shining and there are no clouds in the way of the sun, I use this tool to measure the amount of sunlight able to penetrate our atmosphere.
Using the Sun Photometer
I use a GPS to determine our location and transfer that information to the sun photometer. Then I scan the sunlight with the photometer for about 7 seconds and repeat 5 times within two minutes. Keeping the image of the sun in the target location on the photometer while standing on a rocking boat is harder than it may look!
The little bright light in the dark circle above my right hand is the image of the sun. It must remain in the center of the traget circle during a solar scan.
According to the Maritime Network, the photometer readings taken from ground level helps determine the Aerosol Optical Depth, meaning the fraction of the sun’s energy that is scattered or absorbed while it passes through the earth’s atmosphere. The reduction in energy is assumed to be caused by aerosols when the sunlight’s path to earth is free of clouds. Aerosols are solid or liquid particles suspended in the atmosphere. Sea-salt is a major contributor over the ocean as well as smoke and dust particles from land that are lifted and transported over the oceans. There are many stations over land that collect this data, but using ships is also important because the data is used to provide “ground truth” to satellite measurements over the entire earth, including the oceans. The data is also used in climate change research and aerosol distribution and transport modeling.
“This portrait of global aerosols was produced by a GEOS-5 simulation at a 10-kilometer resolution. Dust (red) is lifted from the surface, sea salt (blue) swirls inside cyclones, smoke (green) rises from fires, and sulfate particles (white) stream from volcanoes and fossil fuel emissions.” (NASA,Goddard website) Image credit: William Putman, NASA/Goddard
It is pretty cool to be part of such an interesting project! The people here are interesting too. I thought I’d highlight some of their stories in my next few blogs.
Career Profile of Intern Chelsea Wegner
Chelsea’s story is a great example for high school students. She graduated from a high school in Virginia that is similar in size to Ashland High School, where I teach. Her family enjoyed spending time near the ocean and had a library of books about ocean adventures. Her grandfather served in the Navy on Nuclear Submarines and liked to build models of ships.
Chelsea Wegner reading “My Father, the Captain: My Life with Jacque Cousteau” by Jean Michel Cousteau in her free time.
In high school, her career interests began to take shape in her Environmental Science in Oceanography class. She went to college at the University of Mary Washington in Virginia majoring in environmental science with particular interest in geology and river systems. She took advantage of a research opportunity studying sediment transport from rivers to the coast during her undergraduate career. She took sediment core samples and analyzed them to determine human impacts, contamination, and dated the sediment layers. She took more research courses that took her to the US Virgin Islands to conduct a reef survey, identifying and counting fish. She described that as a pivotal experience that led her toward her Masters Degree in Marine Science. Her Masters thesis project was a coastal processes study the potential effects of sea level rise on coral reefs and the corresponding coastline. She used the connections she had in the US Virgin Islands and in her university to fund and/or support her research.
After competing her Masters Chelsea applied for a marine science and policy fellowship, the Knauss Fellowship, which allowed her to work as an assistant to the Assistant Administrator of Oceanic and Atmospheric Research (OAR) within NOAA, Craig McLean, for one year. Through this fellowship, Chelsea traveled the world to places like Vietnam, the Philippines, New Zealand, and France getting a first-hand look at how science informs marine policy and vice versa.
Chelsea learned early on that experience matters most when trying to make yourself marketable. That is why she is here now serving as a mapping intern. She takes the opportunity to learn every piece of equipment and software available to her. She is a rising star in the world of science. After this voyage, she will begin her new job as a program analyst at OAR headquarters working in the international office handling engagements with other countries such as Indonesia and Japan. And she is only 28!
Did You Know?
At 10 AM this morning there was tsunami drill, LANTEX (Large Atlantic Tsunami Exercise) on the east coast from Canada all the way down to the Caribbean. So students in schools inside Tsunami-threatened areas likely participated in evacuation drills. The test is part of NOAA National Weather service Tsunami Warning Program. It helps governments test and evaluate their emergency protocols to improve preparedness in the event of an actual tsunami.
