safety drills – Page 3 – NOAA Teacher at Sea Blog

March 20, 2016August 21, 2021

Mary Cook: My First Day at Sea! March 19, 2016

NOAA Teacher at Sea
Mary Cook
Onboard R/V Norseman II
March 18-30, 2016

Mission: Deepwater Ecosystems of Glacier Bay National Park
Geographical Area of Cruise: Glacier Bay, Alaska
Date: Saturday, March 19, 2016
Time: 8:28pm

Weather Data from the Bridge
Temperature: 38°F
Pressure: 1013 millibars
Speed: 0.2 knots
Location: N59° 01.607’, W136° 10.159’
Weather Conditions: Intermittent light rain

Science Blog
Before the Norseman II left port, the Boatswain conducted all the required ship safety drills with us: fire drill, man overboard, and abandon ship. This is where we learned to don the emergency flotation suit, gathered at the Muster Station for roll call, and went over procedures in case of an emergency. These drills are taken very seriously.

What is a muster station?

Safety first! Hard hat and life vest must be worn when on deck.

Ms. Cook in “Gumby” suit

Where’s Qanuk? Hanging out on the Jacob’s Ladder (emergency rope ladder)

We left the port of Auke Bay just north of Juneau at around 10 pm Friday night and steamed into Glacier Bay to arrive at Bartlett Cove this morning at 9 am. We disembarked to attend a required safety orientation for Glacier Bay National Park. Ranger Greg informed us that he had recently seen 4 humpback whales headed into the Bay! Also, that orca live in the Bay year round. Many of the channels are ice-free now because it is warmer than usual for this time of year.

After the brief stop at Bartlett Cove, we steamed into the East Arm of Glacier Bay toward White Thunder Ridge. Many of us were on deck with binoculars looking for wildlife and enjoying the scenic snow-capped mountains. We saw birds, otters, moose and mountain goats!

Chief Scientist Dr. Waller conducts science meeting

While en route, Chief Scientist Dr. Rhian Waller conducted a science meeting reviewing the purpose and plans for the cruise, which is to explore, collect samples and data on the presence and emergence of Primnoa pacifica in Glacier Bay. Primnoa pacifica is commonly called Red Tree Coral. NOAA’s Dr. Bob Stone, who first pursued collecting data on the Red Tree Coral in Glacier Bay back in 2004, is working on this expedition. Other than Bob’s documentation, the Primnoa pacifica of Glacier Bay, Alaska is a mystery.

Two dives were conducted below the steep incline of White Thunder Ridge. The divers got into their dry suits, reviewed their plans on how to communicate and collect samples underwater, and then boarded the little boat called a RHIB (rigid-hull inflatable boat). They returned to Bob’s old spot and dove about 72 feet down for sample collection. The dive took about 30 minutes and when they returned with samples, we began processing each one.

Dr. Stone prepares to dive

The black line is the ship’s track. It looks like we went in circles because that’s what we did!The ship was waiting at a distance on the divers to return.

Primnoa pacifica sample red tree coral

Samples for genetic studies

The Primnoa samples will be assessed for three different things: genetics, isotopes, and reproduction. The genetic fingerprints will be useful in determining the generational spreading pattern of the Red Tree Coral in Glacier Bay. The isotopes will aid in understanding what they eat and their place in the food web. The reproduction assessments will identify sex and level of maturity. An interesting observation is that Primnoa pacifica is one of the first corals to seed newly exposed rock faces when glaciers recede. Bob estimates that the tallest of these coral are about 40 years old because that is when the glacier receded past this point. Using that fact, he also calculates their growth rate to be about 2 centimeters per year.

Tonight, the ROV Kraken 2 will be deployed in order to explore deep depths for the presence of the Red Tree Coral. ROV means remotely operated vehicle. More on that tomorrow!

Kraken 2 Remotely Operated Vehicle (ROV)

Personal Blog
I must say it is a pleasure to be aboard the Norseman II with such enthusiastic scientists and crew. The atmosphere on the ship is one of anticipation and this is how I imagine the early explorers of Glacier Bay must have felt. Rhian, our Chief Scientist, described this expedition as exploratory in nature. I’ve always dreamed of being an explorer and now I get to watch some real explorers in action! These guys and gals have done so many cool things like study life in Antarctica, map uncharted territory, design and build new equipment, and travel to the deep ocean in the Alvin submersible. I am so thankful that they are excited to be a part of the NOAA Teacher at Sea program and share with our students in Scammon Bay and beyond. I’ve enjoyed listening as they brainstorm ways to use our eagle mascot, Qanuk, to engage young people in real science and exploration.

So, as I call it a day, I’d like to congratulate our Scammon Bay Lady Eagles who become the Class 1A Alaska State Champions today! Go Eagles! I’m so proud of both our boys and girls teams and their coaches. They’ve worked hard, played smart and represented our community with dignity and respect.
Good night…..

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May 31, 2015August 21, 2021

DJ Kast, NOAA Ship Henry B. Bigelow, May 31, 2015

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 31, 2015

NOAA Ship Henry B. Bigelow

“National Oceanic and Atmospheric Administration (NOAA) Ship Henry B. Bigelow is the second of five new fisheries survey ships to be built by NOAA. The ship is named after Henry Bryant Bigelow (1879-1967), a Harvard-educated zoologist whose work helped lay the scholarly foundation for oceanography as a scientific discipline. He was an internationally known expert on the Gulf of Maine and its sea life, and on the world’s jellyfish, corals, and fishes” (NOAA NEFSC).

http://www.nefsc.noaa.gov/Bigelow/pdfs/bigelow_scientist_poster.pdf

Henry B. Bigelow and his goat Buck. PHOTO BY: — Henry B. Bigelow and the WHOI Mascot goat Buck. Photo by: NEFSC NOAA

Legacy of the name:

Henry B. Bigelow (1879–1967) was an American oceanographer and marine biologist. Bigelow described numerous new species to science, 110 of which are recognized today according to the World Register of Marine Species. In addition, some 26 species and two genera (Bigelowina, stomatopods in family Nannosquillidae, and Bigelowiella, protists in family Chlorarachniophyte) are named after him. The Henry Bryant Bigelow Medal in Oceanography is awarded by the Woods Hole Oceanographic Research Institute to honor “those who make significant inquiries into the phenomena of the sea”. Bigelow was the first recipient of the medal in 1960. He was honored by the naming of NOAA Ship Henry B. Bigelow.

Mission of the ship:

“NOAA ship Henry B. Bigelow will support NOAA’s mission to protect, restore, and manage the use of living marine, coastal, and ocean resources through ecosystem-based management. Its primary objective will be to study, monitor, and collect data on a wide range of sea life and ocean conditions, primarily in U.S. waters from Maine to North Carolina. The region includes Georges Bank, one of the world’s best known and most productive marine areas. The region is also home to the nation’s top-valued port, oldest commercial fisheries, and rare large whales and sea turtles. Data are used by a range of scientists who study variation in ocean conditions and sea life in order to better inform the nation’s decisions about both using and sustaining the ocean’s bounty.

“Henry B. Bigelow will also observe weather, sea state, and other environmental conditions, conduct habitat assessments, and survey marine mammal and marine bird populations. Henry B. Bigelow is a state-of-the-art research ship with multiple science mission capabilities. Foremost among these capabilities is the ship’s “quiet” hull, a design feature that minimizes sound made by the ship underwater. This allows scientists to use hydroacoustic methods for surveying marine life, and significantly reduces changes in the natural behavior of animals owing to the ship noise. In addition, the vessel can collect a variety of oceanographic data while marine life surveys are underway, resulting in both richer and more efficiently collected data.” (NOAA NEFSC)

Ship Details:

The ship! Photo from: http://www.nefsc.noaa.gov/Bigelow/pdfs/bigelow_sci_systems.pdf

Take a virtual Ship Tour here! : http://www.nefsc.noaa.gov/Bigelow/shiptour.html

Levels: 2 (staterooms, gym, laundry), 1 (Mess Hall), 01 (Lounge), 02, Bridge, Flying Bridge

Side view of the NOAA Henry B. Bigelow. Photo by: http://upload.wikimedia.org/wikipedia/commons/e/e7/NOAA_RV_Henry_B._Bigelow_--_side_plan.gif — Side view of the NOAA Henry B. Bigelow. Photo by: http://upload.wikimedia.org/wikipedia/commons/e/e7/NOAA_RV_Henry_B._Bigelow_–_side_plan.gif

Most of the main deck is reserved for mission functions. The aft working deck provides 145 sq m of open space for fishing and other over-the-side operations, with an additional 33 sq m of deck space at the Side Sampling Station. Space and support connections are provided for a laboratory van on the aft working deck.

Large, easily reconfigurable laboratories are designed to accommodate the varied needs of individual scientific cruises:

Fish/Wet Laboratory 56 sq m (602 sq ft)
Chemistry Laboratory 27 sq m (290 sq ft)
Dry Laboratory 14 sq m (150 sq ft)
Hydrographic Laboratory 9 sq m (96 sq ft)
Scientific Freezer 19 sq m (204 sq ft)
Preservation Alcove 5 sq m (54 sq ft)
Acoustic/Computer Laboratory 46 sq m (495 sq ft)

“Underwater radiated noise has been shown to influence fish behavior, and sonar self-noise can limit the effectiveness of hydroacoustic surveys and other functions. The International Council for Exploration of the Seas (ICES) has established a standard for ships’ underwater radiated noise in order to effectively employ hydroacoustic stock assessment techniques. Henry B. Bigelow has been designed and constructed to meet this ICES noise standard. This reduced noise signature will improve NOAA’s ability to accurately assess fish stocks and to compare standardized data with the international fisheries scientific community. Examples are the propulsion motors, which are specially constructed and balanced to reduce noise and vibration, and the diesel generators, which are mounted on double isolated raft systems. The hull form and highly skewed, five-bladed propeller were carefully designed and tested using U.S. Navy quieting techniques. Pumps, motors, ventilation and piping systems are all designed for low noise, with some critical systems resiliently mounted in the ship. Hull structure is treated in critical areas with special acoustic damping tiles. Airborne noise has been reduced throughout the ship for personnel safety and comfort.” http://www.omao.noaa.gov/publications/bigelow_final.pdf

To summarize that, this ship is so quiet I cannot tell when we are slowing down to 2 knots for bongo or going 11 knots to steam to the next station. It’s amazing.

Bridge:

The bridge is equipped with numerous dedicated systems including:

Hydrographic ES60 SONAR system, and ME70 multibeam system
Dynamic positioning and auto pilot system
X- and S-band Sperry Bridge Master RADARs
Transas ECDIS Navigation system
DGPS receiver
GMDSS communications suite including weather fax, satellite telephone, MF/HF and VHF radios
MTN internet communications system
SCS remote console and master clock display
Doppler speed log and depth sounder
Sperry primary and secondary gyro compass

Nearly all of these systems are solely controlled from the bridge, allowing scientific and operational systems to be totally independent. All scientific and fishing systems can be monitored from the bridge via remote consoles or SCS interfaces.

Laura Gibson charting on the navigational chart. Photo by DJ Kast

Multi-beam bottom sounder. Photo by DJ Kast

Gibson letting me steer the ship. That is fear in my eyes. Photo by Laura Gibson

Starboard steering Console that lets you control the ship while the bongos or CTDs are deployed from the side sampling station. Photo by DJ Kast

Radar with four contacts! Photo by DJ Kast

LT Gibson checking on operations in the bridge. Photo by DJ Kast

Control and status indicator of watertight doors. Photo by DJ Kast

Navigation Light switches. Photo by DJ Kast

Cool Events on the Ship

Care Package Delivery:

The XO's friend that is "Rowing for Peace" to Turkey. The XO delivered ice cream, ship hats, and a pineapple. Photo by DJ Kast — The CO’s friend that is “Rowing for Peace” to Turkey. The CO delivered ice cream, ship hats, and a pineapple. Photo by DJ Kast

Emergency Drills:

The Bigelow values safety and to make sure that everyone knows what to do in an emergency they do quiet a few surprise drills to keep everybody on their toes.

Door sign with information on where to go for each person during each of the type of drills that occur on the ship. Photo by DJ Kast — Station card with information on where to go for each person during each of the type of drills that occur on the ship. Photo by DJ Kast

The first one was a Fire Drill and an Abandon Ship Drill on Wednesday May 20th, 2015.

Photo of me in a survival suit after the abandon ship drill was announced. Photo by Megan Switzer

Practicing the PLT gun (Pneumatic Line Throwing Gun): This is a gun that is used to help rescue people who have fallen overboard and it is also used to pass lines to other boats. It has a projectile connected to a long line that can travel far distance and connect an overboard victim to the boat.

Here is a video of it being shot:

A picture of me preparing the PLT gun for launch. Photo by Dennis Carey

Hydrophoning Acoustic Buoys!

While we were on the southern part of Georges Bank, the boat used a Hydrophone and geometry to pick up an Autonomous Multi-Channel Acoustic Recorder (AMAR) mooring in Lydonia Canyon. The ship sent signals to it with the hydrophone and the signals it received back were indications of where to send the boat next.

The application of the Pythagoreon Theorum in terms of acoustic sound distances to the buoy to help during retrieval. Oh the applications of MATH! Photo by DJ Kast — The application of the Pythagorean Theorem in terms of acoustic sound distances to the buoy to help during retrieval. Oh, the applications of MATH! Photo by DJ Kast

Geoff Shook sending out messages on the hydrophone. Photo by DJ Kast — Geoff Shook preparing to send out messages on the hydrophone to not only find it but also cause it to release to the surface since it was hundreds of meters down. Photo by DJ Kast

Successful retrieval of the acoustic buoy. Photo by DJ Kast

The back of the shirt that the crew and chief Scientist Jerry gave me. Photo by DJ Kast — The back of the shirt that the crew and chief Scientist Jerry Prezioso gave me. I’m having everyone sign it so that I can hang it up when I get home. Photo by DJ Kast

All of the crew have been absolutely amazing and have definitely made this the trip of a lifetime. Thank you all so much. -DJ

Last selfie of the trip. Photo by DJ Kast

May 27, 2015August 21, 2021

Heidi Wigman: Drill, Baby, Drill! May 26, 2015

NOAA Teacher at Sea
Heidi Wigman
Aboard NOAA Ship Pisces
May 27 – June 10, 2015

Mission: Reef Fish Surveys on the U.S. Continental Shelf
Geographical area of cruise: currently @ 30°22.081’N 088°33.789’W (Pascagoula, MS)
Date: May 26, 2015

Weather Data from Bridge: 82°, wind SW @ 10 knots , 90% precipitation, waves 3-5 @ 3 sec.

Science and Technology Log

We are 3 hours from raising anchor, untying from the dock, and heading out to sea. Being aboard the Pisces for 2 days before departure turned out to be a blessing: getting to map out the lay of the 206′ labyrinth, hanging out with the crew, and even getting in a couple of runs around Pascagoula (even in the extreme humidity).

Yesterday was a day of dewatering drills, in case of lower-level compartment flooding. We used the diesel and the electric pumps to run through set-up in the event of a flood in the engine compartment. As the resident TAS, I don’t think that I would necessarily be relied upon to place gear in an emergency, but nevertheless, I wasn’t going to sit out and miss all of the fun.

Today we are running through a series of drills: fire, man overboard, and abandon ship. Each of these events has a series of alerts that indicate what the emergency is, and all hands are to report to their designated muster areas – in the case of an abandon ship, that would be the life rafts. Each of these drills also requires everyone to bring their immersion suits and PFD (Personal Flotation Device), and in my case, to don the suit.

Another training that we did today was to learn how to use the Ocenco EEBD (Emergency Escape Breathing Device) – basically a cool re-breather that fits in a pouch and provides about 10 minutes of fresh oxygen. This would generally be used in case of a fire, not if you are submerged.

So, with all of the drills and trainings, I feel ready for any major disaster that we may encounter while at sea. Thanks NOAA Corps for making sure that I am safe and in good hands!

FRB - Fast-Rescue Boat — FRB – Fast-Rescue Boat

Oscar – waiting to be the star in the man-overboard drill

Bright safety orange so you won’t miss it

June 9, 2014August 21, 2021

Carol Schnaiter, Our Second Day at Sea, June 8, 2014

NOAA Teacher at Sea

Carol Schnaiter

Aboard NOAA Ship Oregon II

June 6 – 21, 2014

Mission: SEAMAP Summer Groundfish Survey Gulf of Mexico

June 8, 2014

Science and Technology Log

The Oregon II set sail on June 6th and will reach the first station sometime Monday, June 9th, in the evening.

While on the way there the scientists and crew are preparing the equipment and testing everything to make sure it is ready to use when we arrive. One item tested was the CTD (Conductivity, Temperature, Depth) item. The white round frame protects the delicate, expensive piece of gear that you can see at the bottom of the frame. It allows the equipment to safely travel down without hitting the side of the ship nor the bottom of the ocean. Near the top you see the water sampling tubes.

Test run of equipment for titrations — Kim and Andre prepare the CTD.

These tubes are opened up and when they enter the water they are triggered to close and collect water from the depth that the science team has predetermined.

The deck crew uses a crane to help lift it over the side of the ship and then it drops down and collects water. This was a test to make sure everything was working and the CTD was dropped down and collected water in three tubes.

When it came back on deck, Kim Johnson, the Lead Scientist, took three containers of water from one tube. In the lab she used the Winkler Test, to determine the concentration of dissolved oxygen in the water samples. This is called doing titrations and they will be conducted once a day or more often if something goes wrong.

Can you think of why scientists would need to test this? They are trying to determine the level of oxygen in the water to see if it is high or low. If it is low or not there at all, scientist call it a “Dead Zone” because everything needs oxygen to live.

Kim Johnson took the three samples to the lab and added chemicals to test the water. It took some time to conduct the test, but Kim explained everything to Robin Gropp (he is an intern on the ship) and to me.

The results that were done by hand were compared to the results collected by the computer and they matched! The oxygen level in the first test were good. This means the equipment will be ready to use!

Sargassum seaweed — Photo I took from the ship

In the Gulf of Mexico there is a lot of floating seaweed called Sargassum. To learn more about this, go to the attached url. In short, this seaweed is brown and floats on top of the water. It has been used as a herb in some areas. It is interesting to see the brown seaweed floating by the ship. http://oceanservice.noaa.gov/facts/sargassosea.html

Do you notice how blue the water is? What makes the water look so blue? According to the NOAA Ocean Facts:

“The ocean is blue because water absorbs colors in the red part of the light spectrum. Like a filter, this leaves behind colors in the blue part of the light spectrum for us to see.
The ocean may also take on green, red, or other hues as light bounces off of floating sediments and particles in the water.
Most of the ocean, however, is completely dark. Hardly any light penetrates deeper than 200 meters (656 feet), and no light penetrates deeper than 1,000 meters (3,280 feet ).”

Pretty neat to see how light and color work together!

Personal Log

The water went from murky brown when we left Mississippi due to the boat activity and the rivers that drain down into the Gulf, to this blue that is hard to describe. I am trying to absorb everything that the scientist are discussing and hoping that when we start working everything will make more sense to me! There is so much to learn!

Today we had safety drills; a fire drill (yes, we practice fire drills even on the ship, you can’t call 911 at sea after all) and abandon ship drill. During the abandon ship drill everyone had to bring long pants, long-sleeve shirt, hat, life preserver and immersion suit. Here is a picture of me in my immersion suit. This suit will float and keep me warm if we need to leave the ship.

Wearing my immersion suit! Photo taken by Kim Johnson

Today the ships’ divers went into the water to check the hulll of the ship and the water temperature was 82 degrees. It would have been refreshing to be in the water, but this is a working ship and safety comes first!

The food onboard the ship is delicious and I am sure I will need to walk many steps after this trip. The cooks offer two or three choices at every meal and the snack area is open 24 hours…not a good thing for me!

While on deck I saw my first flying fish today. I thought it was a bird flying close to the water, but it was not! Amazing how far they can fly over the water.

When I look out from the front of the ship, I see water, water, and more water. There are a few oil rigs in the distance and once in a while a ship passes by, but mostly beautiful blue water!

Last night I saw my first sea sunset and since I will be working the midnight to noon shift starting soon, it maybe the last sunset…but I will get to see some AWESOME sunrises!

2014-06-07 Sunset! — Glad I had my camera with me!

Enjoy the sunset!

Mrs. Carol Schnaiter

May 19, 2013August 11, 2021

Emilisa Saunders: Finding the rhythm aboard the Oregon II, May18, 2013

NOAA Teacher at Sea

Emilisa Saunders

Aboard NOAA ship Oregon II

May 14, 2013 – May 30 2013

Mission: SEAMAP Spring Plankton Survey

Geographical Area of Cruise: Gulf of Mexico

Date: May 18, 2013

Weather Data: Wind Speed: 13.94 knots; Surface water temperature: 25.4; Air temperature: 26.4; Relative humidity: 87%; Barometric pressure: 1,015.33 mb

Science and Technology Log:

For the scientists on board the Oregon II, each shift follows roughly the same routine. When we start our shift, we check in at the dry lab to see how much time we have until the next sampling station. These stations are points on the map of the Gulf of Mexico; they were chosen to provide the best coverage of the Gulf waters. Our ETA, or estimated time of arrival, is determined by how fast the ship is moving, which is influenced by wind and currents, which you can see in the map below. A monitor mounted in the dry lab shows us a feed of the route mapping system that is used by the crew on the Bridge to drive the ship. This system allows us to see where we are, where we are headed, and what our ETA is for the next station. We also get warnings from the Bridge at one hour, at thirty minutes, and at ten minutes before arrival.

Gulf Currents — The currents in the Gulf of Mexico, plus our planned route. Image courtesy of NOAA.

At the 10-minute mark, we put on our protective gear – more on that later in this post – and bring the cod ends up to the bow of the boat, where we attach them to the ends of the appropriate nets. Then, we drop the Bongo nets, the regular Neuston net, the Sub-surface Neuston net, and the CTD into the water, in that order. These all go down one at a time, and each one is pulled out and the samples collected before the next net goes in.

Towing the Neuston net on the night shift

The idea of dropping a net into the water probably sounds pretty simple, but it is actually a multiple-step process that requires excellent teamwork and communication amongst several of the ship’s teams. The scientists ready the nets by attaching cod ends and making note of the data that tracks the flow of water through the net. Because the nets are large and heavy, and because of the strong pressure of the water flowing through the nets, they are lifted into the water using winches that are operated by the ship’s crew. The crew members operate the machinery, and guide the nets over the side of the ship. While this is happening, the crew members communicate by radio with the Bridge, providing them with information about the angle of the cable that is attached to the net, so that the Bridge can maintain the a speed that will keep the net at the correct angle. At the same time, a scientist in the dry lab monitors how deep the net is and communicates with the deck crew about when to raise and lower the nets. This communication takes place mostly over walkie-talkies, which means that clear and precise instructions and feedback are very important.

Operating the winches — Crewmember Reggie operating the winch, while crewmember Chris measures the angle of the cable

When each net is pulled back out of the water after roughly 5-10 minutes, we use a hose to spray any little creatures who might be clinging to the net, down into the cod end. At stations where we run the MOCNESS, we head to the stern of the ship, where the huge MOCNESS unit rests on a frame. Lowering the MOCNESS takes a strong team effort, since it is so large. After we retrieve each net, we detach the cod ends and bring them to the stern, where a station is set up for us to preserve the specimens. I’ll go into more detail about the process of preserving plankton samples in a later post.

Hosing down the nets — Alonzo, hosing down the Bongo nets before bringing them aboard.

We’ve had a couple of nights of collecting now, and so far it has been completely fascinating. I’m in awe of the variety of organisms that we’ve come across. The scientists on my shift, Glenn and Alonzo, are super knowledgeable and have been very helpful in explaining to me what we are finding in the nets. Although this is a Bluefin Tuna study, we collect and preserve any plankton that ends up in the nets, which can include copepods, myctophids, jellies, filefish larvae and eel larvae, to name a few. When we get the samples back to shore, they will be sent to a lab in Poland, where the species will be sorted and counted; then, the tuna larvae will be sent back to labs in Mississippi or Florida for further study and sometimes genetic testing.

My favorite creature find so far has been the pyrosome. While a pyrosome looks like a single, strange creature, it is actually a colony of tiny creatures called zooids that live together in a tube-shaped structure called a tunic. The tunic feels similar to cartilage, like the upper part of your ear. Pyrosomes are filter feeders, which means they draw in water from one opening, eat the phytoplankton that passes through, and push out the clean water from the other end. So far on the night shift, we’ve found two pyrosomes about four inches in length and one that was about a foot long; the day crew found one that filled two five-gallon buckets!

Alonzo and the pyrosome — Alonzo holding the pyrosome

Challenge Yourself:

Hello, Nature Exchange Traders! Pick one of the of the zooplankton listed in bold above, and research some facts about it: Where does it live? What does it eat? What eats it? Write down what you find out and bring it in to the Nature Exchange for bonus points. Be sure to tell them Emmi sent you!

Gumby Suit — In the Gumby suit, practicing the Abandon Ship drill. Photo by Glenn Zapfe

Personal Log:

Safety is the top priority on board the Oregon II. We wouldn’t be able to accomplish any of our scientific goals if people got hurt and equipment got damaged. We started our first day at sea with three safety drills: the Man Overboard drill, the Abandon Ship drill and the Escape Hatch drill. For Man Overboard, everyone on board gathered, or mustered, at specific locations; for the Science team, our location was at the stern, or back of the ship. Aft is another word for the back. From there, we all scanned the water for the imaginary person while members of the crew lowered a rescue boat into the water and circled the Oregon II to practice the rescue.

For the Abandon Ship drill, we all grabbed our floatation devices and survival suits from our staterooms and mustered toward the bow, or front of the ship. I got to practice putting on the survival suit, which is affectionately called a Gumby suit. In the unlikely event that we would ever have to abandon ship, the suit would help us float and stay relatively warm and dry; it also includes a whistle and a strobe light so that aircraft overhead can see us in the water.

For the Escape Hatch drill, we all gathered below deck where our staterooms are, and climbed a ladder, where crew members helped pull us up onto the weather deck (the area of the ship exposed to weather) on the bow of the ship. This is meant to show us how to escape dangers such as fire or flood below deck.

Safety gear on; ready for station! Photo by Glenn Zapfe

But safety isn’t just practiced during drills; it’s pretty much a way of life on the ship. Whenever winches or other machinery are in operation, we all have to wear hard hats and life jackets; that means that we wear them every time we reach a station and drop the nets. We are also all required to wear closed-toed and closed-heeled shoes at all times, unless we’re sleeping or showering. Another small safety trick that is helpful is the idea of, “keep one hand for yourself and one hand for the ship.” That means we carry gear in one hand and leave one free to hold onto the swaying ship. This has been really useful for me as I get used to the ship’s movements.

Until next time, everyone – don’t forget to track the Oregon II here: NOAA Ship Tracker