Hydrographic survey – Page 5 – NOAA Teacher at Sea Blog

July 1, 2018

Eric Koser: Hydrography 101 – and the Tools to Make it Happen, June 28, 2018

NOAA Teacher at Sea

Eric Koser

Aboard NOAA Ship Rainier

June 22 – July 9, 2018

Mission: Lisianski Strait Survey

Geographic Area: Southeast Alaska

Date: June 28, 2018: 0900 HRS

Weather Data From the Bridge
Lat: 57°52.59′ Long: 133°38.7′
Skies: Broken
Wind 1 kt at variable
Visibility 10+ miles
Seas: calm
Water temp: 5.6°C

Science and Technology Log

Long Line Boat — A typical longline fishing boat. The fishing lines get spread out behind the boat from the large booms on either side.

The ultimate focus of Rainier is to assure accurate navigational charts are available to all mariners. This task is critical to the safety of many industries. About 80% of all the overseas trade in the US (by weight) is moved over water. Here in SE Alaska, it appears the largest industry is commercial fishing. Many boats fish both with nets and long lines to catch halibut, rockfish, cod, and several varieties of salmon.

Another major industry here is certainly tourism. As we conduct our work, we often see very large cruise ships. It’s an interesting juxtaposition to be in a narrow inlet surrounded by mountains, ice, and wildlife and then come across a large ship. We passed the brand new ship Norwegian Bliss around 11 PM on our transit to Tracy Arm. This ship is 1,082 feet long, carries a crew of 2,100 people and has a guest capacity of 4,004 people! The safe navigation of all of these vessels depends upon the accuracy of charts produced by NOAA.

The cruise ship Norwegian Bliss as we passed her port to port in the evening.

The freely available charts offered by NOAA are created with three essential steps. First, the bulk of the depth data in this area is measured with MBES (Multi-Beam Echo Sounder). This creates a three-dimensional digital image of the bottom.

Secondly, important features to navigation that are shallow are best identified by our launches which travel along the shorelines and inspect for rocks, ledges, and other potential dangers. The locations of features are identified by GPS location and charted digitally by hydrographers on each launch.

Thirdly, bottom samples are collected by launch crews to confirm the type of material present on the bottom.

The MBES systems aboard Rainier and the launches come from Kongsberg Maritime. Two transducers (devices that transmit and receive) work in tandem. The transducer that is oriented front to back sends out an array of sound signals in a wide beam. The width of the beam on the sea floor depends directly on the depth – deeper water allows the beam to spread farther before reflecting. The transducer that is oriented side to side in the water receives a narrow swath of the ‘pings’ of sound that were transmitted. The time it takes any ping to get to the bottom and reflect back to the ship is recorded. The greater the time, the larger the depth.

MBES on a launch — This shows the position of the MBES on the bottom of one of several launches.

This is the pair of MBES transducers on a launch, looking from the bow towards the stern.

Hydro Sonar — This image, courtesy of NOAA, depicts an MBSS beam below the ship and the mapped results off the stern.

A couple of issues provide challenges to this technique. One, the speed of sound in water depends on several factors. The salinity (concentration of salt in the water), the conductivity (how easily electricity passes through the water), and the temperature each fluctuate as the depth changes and affect the speed of the sound waves. As hydrographers receive data, the system has to account for these changes in speed to produce an accurate depth measurement. One way to do this is with a static CTD sensor. This device is lowered from the launches all the way to the bottom as it measures the speed of sound in the water. It provides a set of three charts as the depth changes which are used to adjust the time data from the MBES accordingly. There is also a version of the CTD, called a MVP (Moving Vehicle Profiler or ‘fish’), that can be pulled behind Rainier as we are moving and take dynamic data.

Here is a NOAA article on hydrographic surveying. Here is further explanation of MBSS.

Deploying Depth Profiler — Here the crew lowers the profiler “fish” into the water.

Speed Profiler Data — These three plots represent the speed of sound, temperature, and salinity (from left to right) vs. depth (on the vertical axis).

A second issue is GPS signal drift. Over time, the location information can shift slightly. To account for this potential problem, the scientists place a HORCON (Horizontal Control) station onshore in the area where they are mapping. I described this tool in my previous post.

Another interesting technology that is currently being developed is called “backscatter” mapping. Here scientists look not only at the time it takes the sound waves to bounce back to the transducer, but also at the quality of the return signal. Different materials on the seafloor reflect the sound differently – hard surfaces like rocks have a sound signature that is much different than soft surfaces like silt or plants. NOAA is continually improving the tools they use to learn!

Here is an example of the chart that we are updating in Tracy Arm.

Personal Log

I had a chance to take the helm yesterday! It’s interesting how sensitive the steering on this large vessel really is. The rudders are able to turn from “amidships” or their center position, up to about 35° to either side. But while traveling at about 8 knots, we tend to use a maximum of about 5° of rudder to alter the ship’s direction. While at the helm, we keep close track of the heading (compass bearing) of the ship as indicated by the gyro compass and magnetic compass on board. Then we provide steering input to hold the ship to the course ordered by the CONN. I had the chance to help steer around several icebergs as we transited into Tracy Arm. Careful attention to detail – and willingness to promptly follow commands make for success!

I also took an opportunity to head out in a kayak from the ship where we are anchored! Two of my new colleagues and I paddled across this bay and had a great chance to look very closely at pieces of ice. The ice is really beautiful and forms many interesting shapes. The quiet of the bay – hearing only the distant waterfalls, birds, and our paddling was beautiful!

Iceberg — This piece of ice drifted through Tracy Arm from the glacier. It was temporarily ‘grounded’ on the bottom by the receding tide.

It’s crazy to consider the ice we were seeing may have been formed thousands of years ago in the glacier – and it just now melting as it floats away.

Did You Know?

President Thomas Jefferson signed a mandate in 1807 ordering a survey of the nation’s coasts. This fundamental task is always ongoing, with 95,000 miles of US Coastline.

About 90% of any floating piece of ice will be submerged below the salt water. Because the density of frozen fresh water just slightly less than salt water, the ice floats very low in the water! Read more here!

Who is Onboard?

I’d like you to meet HST (Hydrographic Survey Technician), Amanda Finn! Ms. Finn has been with NOAA since last September – and started working aboard NOAA Ship Rainier in October of 2017. As an HST, Amanda works with the team of hydrographers to collect MBES data from either the ship or any of the launches. Amanda graduated from the University of Connecticut in 2016 with a bachelor of science degree in GeoSciences and a minor in Oceanography. At the end of her college experience, she knew that seafloor mapping was her passion but wasn’t sure how to make that into a job. But it all came together when she found NOAA through a friend of a friend!

HST Amanda Finn with recently acquired depth data for Lisinaski Inlet!

Amanda was performing at her first harp concert (another skill!) when she met a relation of a hydrographer who works on a NOAA ship! Based on her experience, her advice to students is: “When things don’t seem to be going the way you want, take time to focus on something else you like instead. In good time, things will work out!”

One positive challenge Amanda shares working here on a hydro ship is developing an understanding of systems integration. Many different pieces must come together to create the finished charts. The people aboard Rainier make the experience very positive! The passion for seeking the unknown is the drive to continue!

June 29, 2018June 29, 2018

Brandy Hill: Chat with Chief Engineer and My First Tuna Catch, June 28, 2018

NOAA Teacher at Sea

Brandy Hill

Aboard NOAA ship Thomas Jefferson

June 25, 2018 – July 6, 2018

Mission: Hydrographic Survey- Approaches to Houston

Geographic Area of Cruise: Gulf of Mexico

Date: June 28, 2018

Weather Data from the Bridge

Latitude: 28° 50.7’ N

Longitude: 093° 34.4’ W

Visibility: 10+ nm

Sky Condition: 4/8

Wind: 12 kts

Temperature:

Sea Water: 29.6° C

Air: 29.3° C

Science and Technology Log

This afternoon I spent an hour with Chief Marine Engineer, Thom Cleary. As promised, he gave me a tour of the Engine Room. Thom arrived on the Thomas Jefferson in 2011 and has worked not only on maintaining operations, but greatly improving them. When asked about his favorite ship mechanism, he responded with one that is not his favorite but of which he is most proud. The Thomas Jefferson, along with most other ships, typically used to rid greywater and sewage by offloading into the ocean. The EPA states that ships must be at least one nautical mile from land or people in the water and three nautical miles from aquaculture (2018). With hydrographic survey operations taking place in “no discharge” areas (close to shore), this could complicate and/or slow down the Thomas Jefferson’s progress.

Realizing the inefficiency and in an effort to improve, Thom investigated other options. It was decided that a fuel storage tank would be converted to hold more wastewater. After a long wait period, the new method was installed. Within the first season 38,000 gallons of sewage was stored and discharged to a shore treatment facility. Today, the tanks have gone almost two months without release into the Gulf of Mexico. This improvement has allowed hydrographic operations to continue without interruption, conserves fuel, and increases efficiency.

Renovations to the Thomas Jefferson did not stop there. Originally constructed in 1991, the ship has room for many other improvements. Thom and team advocated for all natural lubricants (rather than petroleum), switched all light fixtures to LEDs, and adjusted the ballast system. In 2016 the roughly 122,000 gallon ballast system changed from using sea to municipal water. This now allows the ship to move from multiple coastal waters without concern for carrying invasive species in the ballast tanks. In addition, the new waste water tank was strategically placed in the center of the ship to help with stability.

Ballast diagram showing invasive species risk. (CC)

Thom is an innovator and self-described incorrigible tinkerer. Many of these changes would not have been made without his (and team’s) desire and advocacy to make things better. When I asked if these upgrades were standard on ships, he mentioned that the Thomas Jefferson is a trailblazer.

Chief Engineer Thom Cleary and the desalination/ reverse osmosis system. The RO typically operates at 650 psi (with 900psi maximum potential) and pushes sea water through a membrane creating potable water for the ship.

Personal Log

CO (Commanding Officer) authorized a launch on one of the boats. After some mishaps with a fuse, the crew performed multiple safety checks and we were cleared to go. Mission: collect survey data near a stationary platform. CO’s comfort level to obstructions with the main ship is a half-mile, so having the smaller launch boats is helpful when surveying areas like this.

Launch Boat Approach — The launch boat crew from left to right: Lt. Klemm, Kevin Brown, Pat Osborn, and Brandy Hill (below deck).

SurveyNearPlatform — Survey area near the stationary platform. The ship to the left is a supply vessel.

While cruising out to the survey area, I spoke with Pat Osborn, part of the Thomas Jefferson’s deck crew and our survey line driver for the day. Pat has two years of training and was explaining that he is still learning parts of his job. (Everyone on the ship wears multiple hats.) He spoke highly of his job and appreciated the multi-dimensional relationship between CO and the crew. Pat explained that CO is not expected to be an expert in all areas of the ship- there are safety checks (such as preparing for the launch) where the CO asks lead crew members to evaluate and sign-off prior to action. Every mission I’ve observed and attended has proceeded in this manner. It is a highly respectful and safe environment.

AllisonLaunchApproach — Chief Survey Technician, Allison Stone, awaiting launch boat arrival.

Launch Return to Ship — Patrick Osborn approaching ship Thomas Jefferson with the launch boat.

KevinDeployingCTD — Kevin Brown lowers the CTD while the boat is stationary. A CTD captures the salinity, temperature, depth, and concentration of particles in the water column. This information is used for analyzing the survey data. On the ship, this information is collected using an MVP which allows the ship to stay in motion.

As soon as we had the survey equipment set up and running, survey technician Kevin Brown brought out a fishing pole. I hadn’t realized that we could fish while out on the boat! We proceeded to catch and release about 10 tuna (likely False Albacore and Bonito). Kevin reeled in two, then passed the pole to me. I couldn’t believe how hard it was to real in a fish. I was reading that they can stay on the line and swim up to 40 mph!

Brandy reeling — Brandy Hill’s active line power stance.

Brandy Hill and her first fishing boat catch, False Albacore.

Peaks

+ Witnessed hard work and precision paying off- the launch boat survey data had an error of 0.0006 meters. The data is highly accurate!

+ Drove “the survey line” on the launch boat. (More of an explanation coming soon.)

+ Reeled in a beautiful, tough fish.

Note: After the seasickness subsided, I’ve decided to leave out the “Valleys” category. I’m having a great time.

June 29, 2018

Vickie Obenchain: Starting a Hydrographic Survey, June 28, 2018

NOAA Teacher at Sea

Victoria Obenchain

Aboard NOAA Ship Fairweather

June 26 – July 6, 2018

Mission: Arctic Access Hydrographic Survey

Geographic Area of Cruise: Northwest Alaska

Date: June 28th, 2018

Weather from the Bridge

Latitude: 54^o 25.5’ N
Longitude: 134^o13.7’ W
Wind Speed: 13 Knots
Wind Direction: South, Southwest
Temperature: 12.2^oC
Visibility: 10 nautical miles
Wave Height: 1 foot
Current Sky Conditions: Overcast

Science and Technology Log

This morning I spent some time on the bridge with the officers. NOAA Ship Fairweather is manned day and night with men and women making sure we are safely on course. While the ship is equipped with GPS, the ship is also full of experienced mariners who plot our position on paper nautical charts to help guarantee the technology is working correctly and helps the officers orient themselves with the area. Every 15 minutes, an officer plots our position either by using GPS coordinates, radar returns, or fixed land triangulation using an alidade. This last mode of determining our coordinates, at least to me, is the most difficult. You must use 3 fixed land points on either side of the ship, determine their direction using the compass on the alidade and then using sliding protractors plot our triangulated position on the chart. Both Executive Officer (XO) Michael Gonsalves and ENS Cabot Zucker have been incredibly helpful in teaching me these different plotting techniques.

XO Gonsalves in the foreground and ENS Zucker in the back plotting our course.

Today we are headed to the Queen Charlotte-Fairweather Fault System. This is a strike slip fault line extending 746 miles off shore of Vancouver Island to the Fairweather range in southeast Alaska. USGS has partnered with NOAA Ship Fairweather to help to create part of a comprehensive map of one of the fastest moving underwater tectonic plates in the world, moving of a slip rate of 2 inches a year. Over the next 24 hours they will survey the area using multibeam sonar to help complete the mapping which as taken almost 4 years to complete.

To start this, the survey team had to deploy a Moving Vessel Profiler (MVP) into the water. The MVP follows behind the ship and by detecting water temperature and salinity of the water, the MVP can then determine the speed of sound in water needed to accurately detect the sea floor. With this knowledge the survey team can correctly calibrate their sonar to map the sea floor. Below you will see Sam Candio and Simon Swart of the survey team deploying the MVP.

MVP, Moving Vessel Profiler

Sam and Simon deploying the MVP

Survey technicians Sam Candio and Simon Swart view the MVP controls

Next blog will cover the amazing people working with the sonar, all times of day and night to make the sea floor maps! (Stay tuned!!)

______________________________________________________________________________

Another short term visitor on this ship is a college student from Loyola University Chicago, Paul Campion, who is on board doing an internship with NOAA. Each year NOAA accepts approximately 130 college sophomores into their two-year-long Hollings internship program to give students an opportunity to take part in research, gain job experience and see what NOAA does. While on board, Paul has been working with the survey team to learn how they do their work, as well as create his own project. Paul has been looking at the electronic navigational charts (ENC) used today by most mariners which show the depth of the sea floor. As NOAA Ship Fairweather surveys an area, these ENC’s can then be updated with more accurate and up to date data. While some areas may remain the same, some areas may show changes or even characteristics which may not have been mapped prior and need to be highlighted. Paul has been working to help create an efficient way to show where the ENCs are different to the new NOAA Ship Fairweather data and may need to be altered or updated.

Personal Log

Since we are out in the sea, and do not have neighboring island chains around us, the boat has been tossed around a bit more and is definitely rolling around in the waves. Luckily, I have not been sick… yet. I have been taking sea sickness pills, and making sure I get plenty of fresh air, but the boat is definitely more difficult to work in. You find yourself moving both with the boat’s inertia and then having to fight against it to move. Walking uses walls and railings, sitting requires holding on to the closest counter top or nailed down object and to get into rooms you need to shove doors away from you to open them, yet hold on so they don’t swing completely away from you and slam the opposite wall. It is kind of challenging and yet amusing.

After lunch today, I went to take a shower. I was given some good advice since I had not done this when the boat was in open water. These words of advice included: Use the walls, kind of squat down to lower your center of gravity, don’t take a razor with you (nothing good will come of that), and if the soap drops be especially careful! All things I took to heart and I am glad to report I am clean, unscratched and ready for another day.

June 27, 2018July 17, 2018

Taylor Planz: Welcome to my Adventure! June 27, 2018

NOAA Teacher at Sea

Taylor Planz

Aboard NOAA Ship Fairweather

July 9 – 20, 2018

Mission: Arctic Access Hydrographic Survey

Geographic Area of Cruise: Point Hope, Alaska

Date: June 27, 2018

Weather Data from the House

Lat: 33.4146° N Long: 82.3126° W
Air Temperature: 23.3° C
Wind Speed: 6.1 Knots
Wind Direction: West
Conditions: Mostly Cloudy, 69% humidity

Personal Log

Welcome to my blog! My name is Taylor Planz, and I am so honored to be a Teacher at Sea this season! My passions in life besides education are my family, my cats, the mountains, and, of course, the ocean! In college I studied Oceanography and conducted undergraduate research in Chemical Oceanography where I explored phosphate dynamics in estuarine sediments. I went on multiple afternoon research cruises as part of my undergraduate degree, but I have never been on a ship overnight before now. I married my husband Derrick in 2014 on the beach, a childhood dream of mine. We got married on the Gulf of Mexico in Destin, Florida.

My husband Derrick and I got married on the Gulf of Mexico in 2014.

In the fall I will be teaching Physical Science and Forensic Science to juniors and seniors at Harlem High School in rural Harlem, GA. In the past, I taught middle school science and this year will be my first year in a high school classroom. I am excited to teach a new age group this fall as there are many big decisions students must make during these critical high school years. I hope that my experience with NOAA Teacher at Sea will inspire at least one student to pursue science, and maybe even ocean science, as a career! There is so much out there to be explored in the ocean, atmosphere, landscape, and even space!

Alaska is about to be the 34th state I have visited in my life! I never really understood how far away it was until my flights for this trip were booked. After departing Atlanta, Georgia, I will land briefly in Portland, Oregon and then Anchorage, Alaska before arriving in Nome, Alaska. From there, I will board NOAA Ship Fairweather for Point Hope. The flights and layovers alone will take 16 hours! It is quite amazing how far the United States stretches!

Flight Map — My trip from Atlanta, Georgia to Nome, Alaska will span 3 flights and 16 hours.

NOAA Ship Fairweather will be my home for 12 days next month where I will help conduct a hydrographic survey of the Point Hope region in northwestern Alaska. We will be so far north that we may cross the Arctic Circle! Only 30% of this region’s ocean floor has ever been surveyed, and those surveys need updating because they took place in the 1960s. Updated and new surveys will be vital for the continued safe navigation of the ever-increasing maritime traffic, especially because the size of the vessels navigating the local waters continues to grow.

Science and Technology Log

Most of the blog posts I write onboard NOAA Ship Fairweather will tie back to physical science, so today I would like to discuss some earth science! Point Hope, AK is located at 68.3478° N latitude and 166.8081° W longitude. As you may know, Earth is divided into 90° of latitude per hemisphere, so 68° is pretty far north! In comparison, Harlem, GA is located at 33.4146° N latitude and 82.3126° W longitude.

What is significant about a region’s latitude? Latitude affects many things including sunlight distribution, seasons, and climate. For most of us in the United States, we know that summer days are long and winter days are short (in reference to hours of sunlight per 24 hour day). In Alaska the effect is much more dramatic! Parts of Alaska experience 24 hours of daylight around the summer solstice in June and 24 hours of darkness around the winter solstice in December. Not only are the daylight hours much different than what most of us experience, the concentration of sunlight that reaches Alaska is different too.

No matter which hemisphere you live in, as your latitude increases away from the equator (0° latitude) the amount of sunlight that reaches you decreases. The sun has to travel a longer distance through more of Earth’s atmosphere to reach you. As the light travels, it becomes more diffuse and less of it reaches its final destination: the Earth’s surface. The less direct sunlight makes those places feel cooler throughout the year than places like Ecuador, which is close to the equator and gets direct sunlight year round. Regions closer to the equator also do not get the long summer days and long winter nights because their daylight hours average around 12 hours per day year round.

It’s a common misconception to think that Earth is closer to the Sun in the summer and farther in the winter. If this were true, summer would start in June all over the world! Instead, the Earth’s tilt (at 23.5°) determines which hemisphere is pointing towards the Sun and that hemisphere experiences summer while the other experiences winter. As latitude increases, the seasonal effect becomes more dramatic. In other words, the difference between summer and winter is more and more noticeable. That is why warm, tropical places near the equator stay warm and tropical year round.

With all of this important science to consider, my 12 days in Alaska will definitely be an adjustment! I purchased an eye mask to help me to get restful sleep while the sun shines around me close to 24 hours per day. In addition, I will be packing plenty of layers to stay warm during the cool days and cold nights. In Georgia, most summer days reach temperatures in the mid-90s with high humidity. In contrast, Alaskan days on the water will reach 50s-60s on average.

Did You Know?

NOAA Ship Fairweather was built in Jacksonville, Florida in the mid-1960s, and its home port today is on the opposite side of the country in Ketchikan, Alaska.

Question of the Day

How many hours of daylight did you experience in your home state during the summer solstice on June 21? Nome, Alaska had 21 hours and 21 minutes of daylight!

June 27, 2018

Brandy Hill: Warm Initiation to Life at Sea: June 26, 2018

NOAA Teacher at Sea

Brandy Hill

Aboard NOAA Ship Thomas Jefferson

June 25 – July 6, 2018

Mission: Hydrographic Survey- Approaches to Houston

Geographic Area of Cruise: Gulf of Mexico

Date: June 26, 2018

Weather Data from the Bridge

Latitude: 28° 59.9′ N

Longitude: 093° 50.4′ W

Visibility: 10+ nm

Sky Condition: 2/8 (2 out of 8 parts have cloud cover)

Wind: 170°, 8 knots (kts)

Temperature: Sea water: 29.8 ° C, Air: 28.8 ° C

Science and Technology Log

Upon early evening arrival to Corpus Christi, TX, I was greeted by ENS Taylor Krabiel with a friendly sign at the airport arrival gate. We made a short drive to the port in Corpus Christi and boarded NOAA Ship Thomas Jefferson.

TJ Starboard View — Starboard view of the Thomas Jefferson while docked in Corpus Christi.

ENS Krabiel provided a quick and thorough tour of the Thomas Jefferson including the well-stocked mess (including a fresh salad and fruit bar, ice cream freezer and espresso machine), gym, complementary laundry facilities, all offices and staterooms, the plot (survey) room, and multiple outdoor decks. He was also patient as I repeatedly lost direction of the stairwell, multiple decks (floors) and doors. It is evident that ENS Krabiel has experience as a teacher because his enthusiasm about the ship, projects, personnel, and patience with newcomers seems to come naturally.

One fact he shared about the ship is that the Thomas Jefferson makes its own water through reverse osmosis. This means that all hands (everyone aboard the ship) generally do not need to worry about water rationing. I hope to take a tour and find out more about this process during the next couple of weeks.

2012-2018 Puretec Industrial Water — Reverse osmosis diagram. (Puretech Industrial Water 2012-2018)

He also mentioned that the U.S. via NOAA is one of the only countries that provide nautical chart data at no cost to the public. Private parties may use these accessible charts and make their own modifications.

The CO, Commanding Officer, of the ship and I discussed various careers aboard the Thomas Jefferson. CO explained that ship personnel in blue uniforms are hired through NOAA Corps and follow military rankings while professional mariners include the survey team, engineers, stewards, and deck department. There are also electronics technicians who are hired as civil servants. I found it astonishing that some crew members have been with the Thomas Jefferson since NOAA acquired the ship in 2003. I was able to have my first breakfast aboard the ship with Puddin’ Gilliam, Junior Engineer, who has been with the ship since then.

It was interesting observing the plans for departure from Corpus Christi come together. I sat in on a safety brief discussing the strict plan of navigation. It takes roughly two hours to navigate through a narrow, 21-mile long channel out of the port. Coming too close to the sides of the channel could cause the ship to run aground, while coming too close to oncoming ships could cause additional damage. There are also several points of crossways where ships could be coming from a different direction. All of these variables require critical communication and a concise plan. Junior Officer, ENS Jacquelyn Putnam, lead the brief and displayed digital Mercator projections of the navigation plan. She claims that navigation is her favorite part of her job. In addition, it was decided that the assistance of a pilot (someone who boards the ship while docked and departs at the jetty) would provide ideal support in navigating the ship.

General Alarm — Several checks are completed prior to departure. This includes sounding all alarms (above), checking the ship whistle, and steering (not pictured).

During a project brief lead by FOO (Field Operations Officer) Lt. Anthony Klemm, I learned that the primary mission is to accurately complete the survey of a section of the Gulf of Mexico. The area was last surveyed in the 1930s. Already, the survey team has submitted updates including the removal of two wrecks or obstructions previously documented in the narrow fairway leading to Galveston. This inaccurate documentation of obstructions that were no longer present could have been causing ships to deviate from the fairway or move unnecessarily into the oncoming lane of traffic. In addition, the surveys done by NOAA Ship Thomas Jefferson allow for validation of surveys completed by other organizations such as BOEM (Bureau of Ocean Energy Management).

ENS Taylor Krabiel launches a towfish sonar device.

Basics of the survey process include launching two types of sonar which work together to provide in-depth views of the ocean floor. Sonar sends a sound wave at a speed around 1500 meters per second in salt water. Using this information and the time it takes for the sonar wave to return to the device, the distance can be calculated using Distance = Speed x Time. The sonar images generated are then processed, saved, and analyzed by the survey team. ENS Putnam mentioned that it is important to validate the data by using multiple scans, “buttoning-up” or finalizing, and re-surveying areas that generated poor data. At times, areas of interest (like a wreck) or areas of safety concern are further investigated by completing another scan on the main ship or by sending a launch (smaller boat).

Personal Log

While Tom Loftin, Chief Electronics Technician, was getting my computer set-up on the ship’s wifi, we heard a call for “All Hands on deck.” I looked at him and asked if that meant us. He replied, “Yep, let’s go!” We joined everyone on the ship to form an assembly line to assist with unpacking crates and passing food down into the mess. The crew would get excited about certain items like the ice cream and blueberries while questioning other generic items with nondescript labels.

Starting at the very beginning before we even left port, there has been no end to teamwork, positive morale, and camaraderie presented on the ship. I have discussed this with multiple crew members and all have said that teamwork and constant communication is critical. Several examples include: the departure from Corpus Christi, observing the survey and bridge communication while sonar is in the water, and the timely “Plan of the Day” email sent out by Lt. Charles Wisotzkey. ENS Putnam mentioned that nothing can be accomplished without a well-functioning team. She further stated that clearly defined roles and the importance of everyone’s job makes the team function well.

It has been a lot of fun to be around this crew. Everyone is kind and highly accommodating thus far. Outside the XO’s (executive officer) office is a sign that says, “Work hard and be nice to others.” I am excited to be here and to witness such a well-functioning team.

Bridge Departure View — Officers, crew, and pilot on the bridge while navigating the narrow channel to Galveston.

Peaks and Valleys

+ I enjoyed observing the departure process and launching the sonar devices.

+ I’ve seen over 30 dolphins scattered around the Gulf.

+I enjoy catching up with people during meal times. The food isn’t bad!

– I experienced my first bought of sea sickness immediately upon leaving the jetty. Seas were a bit rough (an estimated 8 feet) and I retired to my stateroom (bedroom) early without eating dinner.

– I accidentally locked myself out of the shared head (bathroom).