NOAA Teacher at Sea Blog

June 14, 2019June 14, 2019

Jill Bartolotta: ROV, CTD, OMG, June 10, 2019

NOAA Teacher at Sea

Jill Bartolotta

Aboard NOAA Ship Okeanos Explorer

May 30 – June 14, 2019

Mission: Mapping/Exploring the U.S. Southeastern Continental Margin and Blake Plateau

Geographic Area of Cruise: U.S. Southeastern Continental Margin, Blake Plateau

Date: June 10, 2019

Weather Data:

Latitude: 29°04.9’ N

Longitude: 079°53.2’ W

Wave Height: 1-2 feet

Wind Speed: 11 knots

Wind Direction: 241

Visibility: 10

Air Temperature: 26.7° C

Barometric Pressure: 1017.9

Sky: Clear

Science and Technology Log

As part of this mapping mission we are identifying places that may be of interest for an ROV (remotely operated vehicle) dive. So far a few locations have shown promise. The first is most likely an area with a dense mass of deep sea mound building coral and the other an area where the temperature dropped very quickly over a short period of time. But before I talk about these two areas of interest I would like to introduce you to some more equipment aboard.

CTD

CTD stands for conductivity, temperature, and depth. A CTD is sent down into the water column to collect information on depth, temperature, salinity, turbidity, and dissolved oxygen. Some CTDs have a sediment core on them so you can collect sediment sample. There is also a sonar on the bottom of the CTD on Okeanos Explorer that is used to detect how close the equipment is to the bottom of the ocean. You want to make sure you avoid hitting the bottom and damaging the equipment.

Sidney and CTD — General Vessel Assistant Sidney Dunn assisting with CTD launch. Photo Credit: Charlie Wilkins SST Okeanos Explorer

Yesterday we used a CTD because the XBTs launched overnight showed a water temperature change of about 4°C over a few meters change in depth. This is a HUGE change! So it required further exploration and this is why we sent a CTD down in the same area. The CTD confirmed what the XBTs were showing and also provided interesting data on the dissolved oxygen available in this much colder water. It sounds like this area may be one of the ROV sites on the next leg of the mission.

Deep water canyon-like feature with cold water and high oxygen levels. Photo Credit: NOAA OER

ROV

ROV stands for remotely operated vehicle. Okeanos Explorer has a dual-body system meaning there are two pieces of equipment that rely on each other when they dive. The duo is called Deep Discoverer (D2) and Seirios. They are designed, built, and operated by NOAA Office of Ocean Exploration and Research (OER) and Global Foundation for Ocean Exploration (GFOE). Together they are able to dive to depths of 6,000 meters. D2 and Seirios are connected to the ship and controlled from the Mission Control room aboard the ship. Electricity from the ship is used to power the pair. A typical dive is 8-10 hours with 2 hours of prep time before and after the dive.

Seirios and D2 getting ready for a dive. Photo Credit: Art Howard, GFOE

Seirios lights up D2, takes pictures, provides an aerial view of D2, and contains a CTD. D2 weighs 9,000 pounds and is equipped with all types of sampling equipment, including:

Lights to illuminate the dark deep
High definition cameras that all allow for video or still frame photos
An arm with a claw to grab samples, such as rock or coral
Suction tube to bring soft specimens to the surface
Rock box to hold rock specimens
Specimen box to hold living specimens (many organisms do not handle the pressure changes well as they are brought to the surface so this box is sealed so the water temperature stays cold which helps the specimens adjust as they come to the surface)

ROV D2 labeled — D2 with some of her specimen collection parts labeled.

My favorite fact about D2 is how her operators keep her from imploding at deep depths where pressure is very strong and crushes items from the surface. Mineral oil is used to fill air spaces in the tubing and electric panel systems. By removing the air and replacing it with oil, you are reducing the amount of pressure these items feel. Thus, preventing them from getting crushed.

ROV Brain — D2’s “brain” is shown behind the metal bars. The bars are there for extra protection. The panel boxes and tubes are filled with a yellow colored liquid. This liquid is the mineral oil that is used to reduce the pressure the boxes and tubes feel as D2 descends to the ocean floor.

D2 provides amazing imagery of what is happening below the surface. Like I said earlier, one of the areas of interest is mound-building coral. The mapping imagery below shows features that appear to be mound building coral and have shown to be true on previous dives in the area in 2018.

bathymetry features — Multibeam bathymetry collected on this cruise that shows features which are similar to mound building coral that are known to be in the area. Photo Credit: NOAA OER

Mound-Building Coral

Mound-building coral (Lophelia pertusa) are a deep water coral occurring at depths of 200-1000 meters. They form large colonies and serve as habitat for many deep-water fish and other invertebrates. Unlike corals in tropical waters which are near the surface, Lophelia pertusa do not have the symbiotic relationship with algae. Therefore, they must actively feed to gain energy.

Personal Log

We saw whales today!!!! They went right past the ship on our port side and then went on their way. We weren’t able to see them too well, but based on their coloring, low profile in the water, and dorsal fin we think them to be pilot whales, most likely short-finned pilot whales. Pilot whales are highly social and intelligent whales.

There was also the most amazing lightening show last night. The bolts were going vertically and horizontally through the sky. I think what I will miss most about being at sea is being able to see the storms far off in the distance.

Did You Know?

You can build your own ROV, maybe with your high school science or robotics club, and enter it in competitions.

High school ROV competition at The Ohio State University.

References

Mound Building Coral: NOAA, 2010, https://oceanexplorer.noaa.gov/explorations/10lophelia/background/biology/biology.html

Pilot Whales: American Cetacean Society, 2018, https://www.acsonline.org/pilot-whale

June 14, 2019

Lona Hall: Land and Sea, June 12, 2019

NOAA Teacher at Sea

Lona Hall

Aboard NOAA Ship Rainier

June 3 – 14, 2019

Mission: Kodiak Island Hydrographic Survey

Geographic Area of Cruise: Kodiak Island, Alaska

Date: June 12, 2019

Time: 1541 hours

Location: Saltery Cove, Kodiak Island

Weather from the Bridge:

Latitude: 57°29.1009’ N

Longitude: 152°44.0031’ W

Wind Speed: 9.0 knots

Wind Direction: N (10 degrees)

Air Temperature: 12.78° Celsius

Water Temperature: 8.89° Celsius

Lona in immersion suit — All dressed up (in an immersion suit) and no place to go

Science and Technology Log

You may be wondering what role technology plays in a hydrographic survey. I have already written about how modern survey operations rely on the use of multibeam sonar. What I have not described, and am still coming to understand myself, is how complex the processing of sonar data is, involving different types of hardware and software.

For example, when the sonar transducer sends out a pulse, most of the sound leaves and eventually comes back to the boat at an angle. When sound or light waves move at an angle from one substance into another, or through a substance with varying density, they bend. You have probably observed this before and not realized it. A plastic drinking straw in a glass of water will appear broken through the glass. That is because the light waves traveling from the straw to your eye bend as they travel.

The bending of a wave is called refraction. Sound waves refract, too, and this refraction can cause some issues with our survey data. Thanks to technology, there are ways to solve this problem. The sonar itself uses the sound velocity profile from our CTD casts in real time to adjust the data as we collect it. Later on during post processing, some of the data may need to be corrected again, using the CTD cast profiles most appropriate for that area at that general time. Corrections that would be difficult and time-consuming if done by hand are simplified with the use of technology.

Another interesting project in which I’ve been privileged to participate this week was setting up a base station at Shark Point in Ugak Bay. You have most likely heard of the Global Positioning System, and you may know that GPS works by identifying your location on Earth’s surface relative to the known locations of satellites in orbit. (For a great, kid-friendly explanation of GPS, I encourage students to check out this website.) But what happens if the satellites aren’t quite where we think they are? That’s where a base station, or ground station, becomes useful. Base stations, like the temporary one that we installed at Shark Point, are designed to improve the precision of positioning data, including the data used in the ship’s daily survey operations.

Setting up the power source for the base station

Setting up the Base Station involved several steps. First, a crew of six people were carried on RA-7, the ship’s small skiff, to the safest sandy area near Shark Point. It was a wet and windy trip over on the boat, but that was only the beginning! Then, we carried the gear we needed, including two tripods, two antennae (one FreeWave antenna to connect with the ship and a Trimble GPS antenna), a few flexible solar panels, two car batteries, a computer, and tools, through the brush and brambles and up as close to the benchmark as we could reasonably get. A benchmark is a physical marker (in this case, a small bronze disk) installed in a location with a known elevation above mean sea level. For more information about the different kinds of survey markers, click here.

Base station installers: damp, but not discouraged

Next we laid out a tarp, set up the antennae on their tripods, and hooked them up to their temporary power source. After ensuring that both antennae could communicate, one with the ship and the other with the satellites, we met back up with the boat to return to the ship. The base station that we set up will be retrieved in about a week, once it has served its purpose.

Career Focus – Commanding Officer (CO), NOAA Corps

CO Ben Evans at dinner — CO Ben Evans enjoying dinner with the other NOAA Corps officers

Meet Ben Evans. As the Commanding Officer of NOAA Ship Rainier, he is the leader, responsible for everything that takes place on board the ship as well as on the survey launches. Evans’ first responsibility is to the safety of the ship and its crew, ensuring that people are taking the appropriate steps to reduce the risks associated with working at sea. He also spends a good deal of his time teaching younger members of the crew, strategizing with the other officers the technical details of the mission, and interpreting survey data for presentation to the regional office.

Evans grew up in upstate New York on Lake Ontario. He knew that he wanted to work with water, but was unsure of what direction that might take him. At Williams College he majored in Physics and then continued his education at Woods Hole Oceanographic Institution, completing their 3-year Engineering Degree Program. While at WHOI, he learned about the NOAA Commissioned Officers Corps, and decided to apply. After four months of training, he received his first assignment as a Junior Officer aboard NOAA Ship Rude surveying the waters of the Northeast and Mid-Atlantic. Nearly two decades later, he is the Commanding Officer of his own ship in the fleet.

When asked what his favorite part of the job is, Evans smiled to himself and took a moment to reply. He then described the fulfillment that comes with knowing that he is a small piece of an extensive, ongoing project–a hydrographic tradition that began back in 1807 with the United States Survey of the Coast. He enjoys working with the young crew members of the ship, sharing in their successes and watching them grow so that together they may carry that tradition on into the future.

Danielle Koushel, NOAA Corps Junior Officer, tracks our location on the chart

Personal Log

For my last post, I would like to talk about some of the amazing marine life that I have seen on this trip. Seals, sea lions, and sea otters have shown themselves, sometimes in surprising places like the shipyard back in Seward. Humpback whales escorted us almost daily on the way to and from our small boat survey near Ugak Bay. One day, bald eagles held a meeting on the beach of Ugak Island, four of them standing in a circle on the sand, as two others flew overhead, perhaps flying out for coffee. Even the kelp, as dull as it might seem to some of my readers, undulated mysteriously at the surface of the water, reminding me of alien trees in a science fiction story.

Stepping up onto dry land beneath Shark Point, we were dreading (yet also hoping for) an encounter with the great Kodiak brown bear. Instead of bears, we saw a surprising number of spring flowers, dotting the slopes in clumps of blue, purple, and pink. I am sensitive to the smells of a new place, and the heady aroma of green things mixed with the salty ocean spray made our cold, wet trek a pleasure for me.

Word of the Day

Davit – a crane-like device used to move boats and other equipment on a ship

Speaking of Refraction…

Rainbows are caused by the refraction of light through the lower atmosphere

Thank you to NOAA Ship Rainier, the Teacher at Sea Program, and all of the other people who made this adventure possible. This was an experience that I will never forget, and I cannot wait to share it with my students back in Georgia!

June 13, 2019

Betsy Petrick: Hurry Up and Shape Up to Ship Out, June 13, 2019

NOAA Teacher at Sea

Betsy Petrick

Aboard R/V Point Sur

June 24 – July 3, 2019

Mission: Microbial Stowaways: Exploring Shipwreck Microbiomes in the deep Gulf of Mexico

Geographic Area: Gulf of Mexico

Date: June 13, 2019

Introduction

In just two weeks I will be shipping out of Gulfport, Mississippi on the University of Southern Mississippi Research Vessel Point Sur. As a NOAA Teacher at Sea, I will actually be a student again, learning all I can about ocean archaeology and deep-sea microbial biomes. I feel very lucky to have this opportunity to learn what it is like to live and work at sea! In particular, I am looking forward to seeing how archaeologists work at sea. My undergraduate degree was in archaeology and I worked in the desert of New Mexico and southern Colorado where we mapped with pencil and paper, and took samples with a shovel. Ocean archaeology will require more sophisticated technology and a different approach!

Let me give you a little background about myself. My husband and I live in a tiny town called Husum on the White Salmon River in Washington State. My family enjoys outdoor activities including rafting and kayaking. This year my daughter is working as a raft guide on the White Salmon. I know when the commercial raft trips are passing by because I can hear the tourists scream as their boats go over Husum Falls! My son is studying Engineering in college and is spending this summer in Spain learning Spanish and surfing. Unfortunately for my husband, summer is the busy time for construction. As a general contractor, he will be working hard.

Petrick family rafting — The whole family rafting the Deschutes River in Oregon, hmmm… quite a few years ago, but we still love it!

During the regular school year, I teach fourth grade math and science at the local intermediate school. One of our biggest science units each year is to raise salmon in the classroom and learn about the salmon life cycle, adaptations and the importance of protecting salmon habitat. In addition, this year we tackled a big project around plastic pollution in the oceans and how we can make a difference in our own community through education and action. My students are rightfully indignant about the condition of our oceans, and I have also become an ocean advocate since initiating this project.

Student salmon drawings — Kids made scientific drawings of salmon, and then painted and stuffed them. They swam around the classroom ceiling all year!

Scientists on the Point Sur have several goals. First of all, they will map two shipwrecks that have never been explored. Both are wooden-hulled historic shipwrecks that were identified during geophysical surveys related to oil and gas exploration. Archaeologists hope to determine how old the ships are, what their purpose was, and their nationality, to determine if they are eligible for listing on the National Register of Historic Places (NRHP). A third shipwreck we will visit is a steel-hulled, former luxury steam yacht that sank in 1944. It was previously mapped and some experiments were left there in 2014 which we will recover.

In addition to mapping, we will take samples of the sediments around the ships to see how shipwrecks shape the microbial environment. The Gulf of Mexico is a perfect place for this work because it is rich in shipwrecks. Shipwrecks create unique reef habitats that are attractive to organisms both large and small. I wonder what kinds of sea life we will discover living around the shipwrecks we visit?

The first question my students asked me was if I was going to scuba dive. While that would be exciting, it’s not allowed for Teachers at Sea! To gather information about the shipwrecks, we will deploy a remotely operated vehicle (ROV) called Odysseus (Pelagic Research Services, Inc.) . Odysseus will have a camera, a manipulator arm to gather samples, a tray to carry all the sampling gear and SONAR and lights. I think I will be content to watch its progress on the ship’s video screens.

School is almost out, and my fourth graders are chomping at the bit to get out if the classroom and begin their own summer adventures, but I hope they will follow my blog and keep me company while I am on board ship! Am I feeling a little intimidated? Absolutely! But also very excited to have the opportunity to participate in what is sure to be a great adventure.

June 12, 2019

Lona Hall: Rockin’ at the NALL on Ugak, June 10, 2019

NOAA Teacher at Sea

Lona Hall

Aboard NOAA Ship Rainier

June 3 – 14, 2019

Mission: Kodiak Island Hydrographic Survey

Geographic Area of Cruise: Kodiak Island, Alaska

Date: June 10, 2019

Time: 1932 hours

Location: Saltery Cove, Kodiak Island

Weather from the Bridge:

Latitude: 57°29.1359’ N

Longitude: 152°44.0488’ W

Wind Speed: 17.2 knots

Wind Direction: N (353 degrees)

Air Temperature: 12.13° Celsius

Water Temperature: 9.44° Celsius

Lona on a launch vessel — Sitting in the sun on a launch, Rainier in the background

Science and Technology Log

For my second time out on a launch, I was assigned to a shoreline survey at Narrow Cape and around Ugak Island (see chart here). Survey Tech Audrey Jerauld explained the logistics of the shoreline survey. First, they try to confirm the presence of charted features (rocks) along the shore. (As you may remember from my last post, a rock is symbolized by an asterisk on the charts.) Then, they use the small boat’s lidar (LIght Detection And Ranging) to find the height of the rocks. Instead of using sound pulses, as with sonar, lidar uses pulses of laser light.

Point Cloud: Each dot represents a lidar “ping”, indicating the presence of features above the waterline

Once a rock was identified, Audrey photographed it and used the laser to find the height of the rock to add to the digital chart. The launch we used for the shoreline survey was RA-2, a jet boat with a shallow draft that allows better access to the shoreline. We still had to be careful not to get too close to the rocks (or to the breakers crashing into the rocks) at certain points around Ugak Island. The line parallel to the shore beyond which it is considered unsafe to survey is called the NALL (Navigable Area Limit Line). The NALL is determined by the crew, with many factors taken into account, such as shoreline features, marine organisms, and weather conditions. An area with many rocks or a dangerously rocky ledge might be designated as “foul” on the charts.

Amanda and Audrey discussing the locations of rocks along the shoreline

I must pause here to emphasize how seriously everyone’s safety is taken, both on the small boats and the ship itself. In addition to strict adherence to rules about the use of hard hats and Personal Flotation Devices in and around the launches, I have participated in several drills during my stay on the ship (Man Overboard, Fire and Emergency, and Abandon Ship), during which I was given specific roles and locations. At the bottom of each printed Plan of the Day there is always a line that states, “NEVER shall the safety of life or property be compromised for data acquisition.” Once more, I appreciate how NOAA prioritizes the wellbeing of the people working here. It reminds me of my school district’s position about ensuring the safety of our students. No institution can function properly where safety is not a fundamental concern.

Career Focus – Marine Engineer

Johnny Brewer joined the Navy in 1997. A native of Houston, Texas, many of his family members had served in the military, so it seemed natural for him to choose a similar path after high school. The Navy trained him as a marine engineer for a boiler ship. Nearly 15 years later he went into the Navy Reserve and transitioned to working for NOAA.

Working as an engineer requires mental and physical strength. The Engineering Department is responsible for maintaining and updating all of the many working parts of the ship–not just the engine, as you might think! The engineers are in charge of the complex electrical systems, plumbing, heating and cooling, potable water, sewage, and the launches used for daily survey operations. They fix everything that needs to be fixed, no matter how large or small the problem may be.

Johnny emphasized how important math is in his job. Engineers must have a deep understanding of geometry (calculating area, volume, density, etc.) and be able to convert measurements between the metric and American systems, since the ship’s elements are from different parts of the world. He also described how his job has given him opportunities to visit and even live in new places, such as Hawaii and Japan. Johnny said that when you stay in one place for too long you can become “stuck in a box,” unaware of the world of options waiting for you outside of the box. As a teacher, I hope that my students take this message to heart.

Personal Log

In my last post I introduced Kimrie Zentmeyer, our Acting Chief Steward. In our conversation, she compared the ship to a house, the walls of which you cannot leave or communicate beyond, except by the ship’s restricted wi-fi, while you are underway. I would like for my readers (especially my students) to imagine living like this, confined day in and day out to a single space, together with your work colleagues, without family or friends from home. How would you adjust to this lifestyle? Do you have what it takes to live and work on a ship? Before you answer, consider the views from your back porch!

Word of the Day

bulkhead – a wall dividing the compartments within the hull of a ship

Q & A

Are there other NOAA ships working in Alaska?

Yes! NOAA Ship Fairweather is Rainier’s sister-ship and is homeported in Ketchikan, Alaska. Also, the fisheries survey vessel, NOAA Ship Oscar Dyson is homeported in Kodiak, not far from where we are currently located.

What did you eat for dinner?

This evening I had sauteed scallops, steamed broccoli, and vegetable beef stew. And lemon meringue pie. And a cherry turnover. And ice cream.

June 11, 2019June 17, 2019

Jill Bartolotta: Careers at Sea, June 8, 2019

NOAA Teacher at Sea

Jill Bartolotta

Aboard NOAA Ship Okeanos Explorer

May 30 – June 14, 2019

Mission: Mapping/Exploring the U.S. Southeastern Continental Margin and Blake Plateau

Geographic Area of Cruise: U.S. Southeastern Continental Margin, Blake Plateau

Date: June 8, 2019

Weather Data:

Latitude: 30°30.7’ N

Longitude: 078°11.2’ W

Wave Height: 3 feet

Wind Speed: 13 knots

Wind Direction: 150

Visibility: 10 nm

Air Temperature: 26.6° C

Barometric Pressure: 1015.9

Sky: overcast

Science and Technology Log

Throughout my blogs you have been hearing an awful lot about NOAA. But what is NOAA? NOAA stands for the National Oceanic and Atmospheric Administration. NOAA informs the public all about environmental happenings from the deepest depths of the ocean floor all the way to the sun.

NOAA was formed in 1970 as a federal agency within the Department of Commerce. It was the result of bringing three previous federal agencies together, U.S. Coast and Geodetic Survey, Weather Bureau, and U.S. Commission of Fish and Fisheries. Through research, NOAA understands and predicts changes in climate, weather, oceans, and coasts. Through outreach and education, NOAA shares the research with end users and the public with the purpose of conserving and managing coastal and marine ecosystems and resources (NOAA, 2019. https://www.noaa.gov/our-mission-and-vision).

In order to accomplish its mission, NOAA hires a whole slew of people including Commissioned Officers, administrators, career scientists, research technicians, vessel operators, educators, etc. These people may work on land or out at sea. In this blog I will focus on some of the NOAA careers at sea.

NOAA Commissioned Officer Corps (NOAA Corps)

The NOAA Corps is a descendant of the US Coast and Geodetic survey, the oldest federal scientific agency dedicated to surveying the ocean coast. Today, officers of the NOAA Corps command NOAA’s fleet of survey and research vessels and aircraft.

In order to be eligible to apply for NOAA Corps one must have a four-year degree in a study area related to the scientific or technical mission of NOAA. There are many other eligibility requirements and you can check them out here. Once you meet the requirements, you apply to the program, and if accepted you will head to the Coast Guard Academy in New London, Connecticut where you will attend a 19-week basic officer training class. Once officers graduate, they are assigned to sea duty for two years. After sea duty, officers rotate to land duty for three years. And the pattern continues as long as the officers choose to remain in the NOAA Corps.

NOAA officers fill many roles on Okeanos Explorer. Their primary role is to safely navigate the ship. All officers stand two 4-hour watches. During these watches, they are responsible for navigating and driving the ship, taking weather, and handling the ship per the requirements needed for the science mission whether it be for a series of ROV dives, mapping project, or emerging technology cruise. When not on watch, officers are responsible for collateral duties. There are many collateral duties, some of which are described below:

Safety officer: responsible for the safety drills and equipment.
Navigations officer: maintains charts, loads routes, plots routes on paper charts, updates electronic chart, and creates inbound and outbound routes for ports of call.
MWR (Morale, Welfare and Recreation) officer: responsible for fun activities when at sea or in port. These activities have included ice cream socials, movie nights, and baseball games.
Public affairs officer: Responsible for giving ship tours to the public, maintain the ships social media presence, and performs public outreach.

There are also many officer ranks (follow the ranks of the US Navy) aboard the ship. The entry level rank is ensign or junior officer and the highest rank is admiral, allowing for 10 ranks in total. In addition to rank classes, there are varying positions. Ensigns or junior officers are recent graduates of basic officer training and on their first sea assignments. They are learning how to navigate and drive the ship, the tasks associated with standing watch, and learning about the other collateral duties. The operations officer is responsible for all mission operations while at sea and in port. They serve as the liaison between the science team and the commanding officer. If project instructions change, the Operations Officer is responsible for managing operations, understanding requests or change and then speaking with the commanding officer to approve the change. They are also responsible for all logistics when in port such as shore power, vehicles, trash, potable water, fuel, and sewer. The next highest position (second in command) is the Executive Officer who also coordinates with many of the port duties, and is supervisor of the varying departments on the ship. They are also responsible for all paperwork and pay. The highest duty on the ship is that of Commanding Officer. They are ultimately responsible for mission execution and for the safety of the ship and people aboard.

The NOAA Commissioned Officers aboard Okeanos Explorer. From left to right: Ensign Brian Caldwell, Lieutenant Steven Solari, Lieutenant Rosemary Abbitt, Ensign Kevin Tarazona, Commander Eric Johnson, Ensign Nico Osborn, Lieutenant Commander Kelly Fath, Lieutenant Commander Faith Knighton, and Commander Nicole Manning.

Professional Mariners

Professional mariners provide technical assistance needed to support operations while at sea. They support the ship in five different expertise areas: deck, engineering, steward, survey, and electronics. More information about the professional mariners and job posting information can be found here. Some have attended maritime school to receive training or licensure to work aboard a ship at sea. Others get their training while at sea, take required training courses, and complete onboard assessments. These mariners that work their way up to leadership positions are known as hawse-pipers (for example, the Chief Boatswain, Jerrod Hozendorf, many years ago was a General Vessel Assistant and has worked up to the Department Head of the Deck Department.)

Deck

Deck hands and able bodied seamen who attend maritime school or training where they learn how to support ship operations, including but not limited to maintenance of the ship’s exterior, maintenance and operation of the ship’s cranes (places ROV (remotely operated vehicle) or CTD (conductivity temperature depth) in the water) and winches (lowers ROV and CTD into the water), and conducts 24/7 watches to ensure the safe operation and navigation of the ship. Augmenters also rotate through the fleet, while others are permanent crew on a ship.

Engineering

The engineers aboard are responsible for the water treatment, air quality systems, and machines needed to make the ship move through the water. The also oversee the hydraulics of the cranes and winches. Engineers receive a four-year engineering degree at either a maritime academy or regular college. Depending on their degree, they will come aboard at different engineer expertise levels. Engineers move into higher level positions based on their days at sea and successful completion of licensing tests.

Stewards

The stewards on board are responsible for the preparation and management of the culinary services and the stateroom services such as bed linens. Tasks include meal planning, food purchasing and storage, food preparation, and oversight of the galley and mess.

Survey

Survey technicians are responsible for the operation of all survey equipment aboard the ship needed for mapping, CTD deployment, and ROV operations. Equipment includes echo sounders and meteorological and oceanographic sensors. They are also responsible for data quality control and processing, disseminating data to land data centers so it can be shared with the public, and working alongside the science team to assist with other data and equipment needs. A college degree is not required for survey technicians, but many of them have one in the fields of environmental or applied science.

Electronics

Electronic technicians are responsible for all electronics aboard such as the intercoms, radios, ship’s computers and internet access, sonars, telephones, electronic navigation and radar systems, and most importantly satellite TV! Chief Electronic Technicians rotate between land and sea, typically spending 2-3 months at sea.

survey and electronic technicians — Chief Electronic Technician Mike Peperato and Senior Survey Technician Charlie Wilkins pose with the CTD.

Personal Log

We saw dolphins today!!!! It was absolutely amazing. We believe them to be Atlantic Spotted Dolphins. Spotted you say? The one in the picture to the left is not spotted because it is less than one year old. They do not receive their spots until their first birthday. Spotted dolphins are very acrobatic. They enjoy jumping out of the water and surfing on the bow waves created by vessels. To date one of the best moments of the trip so far. Yay dolphins!!!!!

Did You Know?

Including all the NOAA officers and professional mariners aboard Okeanos Explorer, 12,000 people work for NOAA worldwide!