Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Ocean Discovery
USGS Leads Research Expedition to Deep-sea Escanaba Trough
Watch short videos about the expedition, and read deep-dive stories about hydrothermal systems, marine geology, and critical minerals.
Humans know more about the physical and chemical properties of outer space than about planet Earth’s deep ocean regions. Just like space travel, exploring the often hard-to-reach submarine areas requires innovative approaches and technologies. USGS and partners are driving technology, to explore and discover new ocean environments and habitats that we know very little about.
Exploring the Ocean World
The ocean covers more than 70 percent of our planet, yet more than 80 percent of the marine environment remains unexplored and unmapped. This enormous gap in our understanding is narrowing, thanks in part to innovative approaches and techniques and exploration conducted by the USGS and its partners. Like space explorers, USGS deep-sea scientists are motivated by a desire to explore an unknown world, a world that has rarely – if ever – been seen by human eyes.
Research vessels or ships designed for scientific research, are small communities of scientists. On board the ship, geologists, biologists, microbiologists, geneticists, geospatial analysts, and engineers travel to the distant parts of the ocean, where they stay and work together, often for weeks at a time. While at sea, the interdisciplinary team weaves together seafloor imagery and maps; collects biological, hydrological, and geological samples; and other types of environmental data to help tell the story of what life is like at the bottom of the ocean. Each expedition brings our scientists face-to-face with something new, and with each discovery of a new deep-sea creature or feature, such as an 86-mile-long coral reef off the coast of Charleston, South Carolina, USGS researchers continue to push scientific limits as they dive deeper into the oceanic frontier.
To help explore these hard-to-reach parts of the ocean, USGS scientists use underwater robots like remotely operated vehicles (ROVs), automated underwater vehicles (AUVs), or human occupied vehicles (HOVs). These underwater vehicles let us discover and explore remarkable geological features, as topographically complex as features on land, and deep-sea ecosystems teeming with biodiversity. The USGS works with academic, industry and other private and federal partners to advance our technological capabilities. Learn more about USGS deep sea research.
Thanks to these underwater vehicles, USGS scientists can investigate deepwater ecosystems such as hydrothermal vents, canyons, and cold seeps, working to characterize the microbial and benthic communities they support. USGS scientists identify, characterize, and quantify environmental microbial communities, which are critical components of healthy marine ecosystems. They also conduct research to understand community and food web structure, biodiversity, and habitat connectivity of marine benthic ecosystems, which involves examining the small animals that live in or on the seafloor. By providing a baseline understanding of these never-explored habitats, USGS science helps inform issues, such as the management of resource use and energy production.
We know that some of these areas are physically and biologically well-connected to land areas as well as to each other through areas of specialized research. Many explorative research efforts are collaborative and multidisciplinary in nature, developing holistic understanding of the ocean, from geologic structure and hazards, geochemistry and the unique mineralogic and biological communities that have developed in these environments. Scientists believe that life on Earth began more than 3.5 billion years ago in the ocean. The linkages between these remote areas and human populations and activities may not be as far removed as we think.
Innovative Technology
Exploring new places often requires new ways of doing things. New equipment, methods and capabilities are needed to access and study these hard-to-reach these locations, to obtain samples, and to ensure that these samples are preserved so they are useful at land surface. The USGS has worked with many partners to design specific new tools and capabilities so that we can learn as much as we can with each visit to these remote areas. This extensive network has allowed the USGS to tap into innovative technologies, for example, benthic landers for long-term data collection in the Atlantic Ocean and Gulf of Mexico and methane gas bubble collectors in the Pacific Ocean.
Publications
Realizing the potential of eDNA biodiversity monitoring tools in the marine environment with application to offshore renewable energy
The U.S. Geological Survey (USGS) researches the biological diversity and distribution of species to support management, conservation, and resource use decisions. USGS scientists advance detection and monitoring technologies to assess changes in fish and wildlife populations, biodiversity, and the health of ecosystems. The United States is planning to install 30 gigawatts of offshore marine and wi
Accurate bathymetric maps from underwater digital imagery without ground control
Windows to the deep 2018: Exploration of the southeast US Continental margin
Deep search: Deep sea exploration to advance research on coral/canyon/cold seep habitats
Discovering the deep: Exploring remote Pacific marine protected areas
Science
EXPRESS: Expanding Pacific Research and Exploration of Submerged Systems
USGS Role in DEEP SEARCH: Deep Sea Exploration to Advance Research on Coral, Canyon, and Cold-seep Habitats
DISCOVRE: Diversity, Systematics and Connectivity of Vulnerable Reef Ecosystems
U.S. Geological Survey Gas Hydrates Project
The Mid-Atlantic Resource Imaging Experiment (MATRIX)
Multimedia
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
News
A new strategy to help unleash USGS eDNA capabilities
Deep Dive: Whence Comes the Name “Escanaba”?
Escanaba Trough Expedition: Updates From Sea
Realizing the potential of eDNA biodiversity monitoring tools in the marine environment with application to offshore renewable energy
The U.S. Geological Survey (USGS) researches the biological diversity and distribution of species to support management, conservation, and resource use decisions. USGS scientists advance detection and monitoring technologies to assess changes in fish and wildlife populations, biodiversity, and the health of ecosystems. The United States is planning to install 30 gigawatts of offshore marine and wi
Accurate bathymetric maps from underwater digital imagery without ground control
Windows to the deep 2018: Exploration of the southeast US Continental margin
Deep search: Deep sea exploration to advance research on coral/canyon/cold seep habitats
Discovering the deep: Exploring remote Pacific marine protected areas
Learn more about USGS deep sea research.
EXPRESS: Expanding Pacific Research and Exploration of Submerged Systems
USGS Role in DEEP SEARCH: Deep Sea Exploration to Advance Research on Coral, Canyon, and Cold-seep Habitats
DISCOVRE: Diversity, Systematics and Connectivity of Vulnerable Reef Ecosystems
U.S. Geological Survey Gas Hydrates Project
The Mid-Atlantic Resource Imaging Experiment (MATRIX)
IMMeRSS-- Interagency Mission for Methane Research on Seafloor Seeps
Expanding Pacific Exploration and Research: Overview of the EXPRESS research campaign
A multi-agency team is mapping uncharted waters and exploring deep-sea ecosystems off the west coast of the United States.
Oceans cover 71% of the Earth's surface, yet little is known about these vast underwater worlds. Less than 20% have been explored. A global initiative seeks to change that, by pledging to complete detailed mapping of one-hundred percent of the seafloor by the year 2030..
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
Oceanographic instrumentation is ready for deployment off of Fire Island to measure how the offshore bathymetry (shown in background map) influences coastal response.
Oceanographic instrumentation is ready for deployment off of Fire Island to measure how the offshore bathymetry (shown in background map) influences coastal response.
Seafloor geology map from a 2017 journal article by Johnson and others, published in Coastal and Ocean Management. Shaded digital elevation model (DEM) showing submarine landslides and sites of potential f
Seafloor geology map from a 2017 journal article by Johnson and others, published in Coastal and Ocean Management. Shaded digital elevation model (DEM) showing submarine landslides and sites of potential f
ROV/submersible used to sample the deep-sea canyon
ROV/submersible used to sample the deep-sea canyon
The submersible Delta is launched on a dive to document bottom communities with a video camera and to collect coral specimens.
The submersible Delta is launched on a dive to document bottom communities with a video camera and to collect coral specimens.
Dr. Christina Kellogg emerges from the submersible Delta after collecting coral samples in the Aleutian Islands in 2004.
Dr. Christina Kellogg emerges from the submersible Delta after collecting coral samples in the Aleutian Islands in 2004.
Bathymetry of the coastal ocean offshore of the New York metropolitan region
Bathymetry of the coastal ocean offshore of the New York metropolitan region
Dr. Christina Kellogg, USGS DISCOVRE's microbiologist, begins a dive in the Johnson-Sea-Link submersible to study deep-sea coral. The submersible can reach depths of 900 meters and has a manipulator arm and suction tool for collecting samples.
Dr. Christina Kellogg, USGS DISCOVRE's microbiologist, begins a dive in the Johnson-Sea-Link submersible to study deep-sea coral. The submersible can reach depths of 900 meters and has a manipulator arm and suction tool for collecting samples.
Humans know more about the physical and chemical properties of outer space than about planet Earth’s deep ocean regions. Just like space travel, exploring the often hard-to-reach submarine areas requires innovative approaches and technologies. USGS and partners are driving technology, to explore and discover new ocean environments and habitats that we know very little about.
Exploring the Ocean World
The ocean covers more than 70 percent of our planet, yet more than 80 percent of the marine environment remains unexplored and unmapped. This enormous gap in our understanding is narrowing, thanks in part to innovative approaches and techniques and exploration conducted by the USGS and its partners. Like space explorers, USGS deep-sea scientists are motivated by a desire to explore an unknown world, a world that has rarely – if ever – been seen by human eyes.
Research vessels or ships designed for scientific research, are small communities of scientists. On board the ship, geologists, biologists, microbiologists, geneticists, geospatial analysts, and engineers travel to the distant parts of the ocean, where they stay and work together, often for weeks at a time. While at sea, the interdisciplinary team weaves together seafloor imagery and maps; collects biological, hydrological, and geological samples; and other types of environmental data to help tell the story of what life is like at the bottom of the ocean. Each expedition brings our scientists face-to-face with something new, and with each discovery of a new deep-sea creature or feature, such as an 86-mile-long coral reef off the coast of Charleston, South Carolina, USGS researchers continue to push scientific limits as they dive deeper into the oceanic frontier.
To help explore these hard-to-reach parts of the ocean, USGS scientists use underwater robots like remotely operated vehicles (ROVs), automated underwater vehicles (AUVs), or human occupied vehicles (HOVs). These underwater vehicles let us discover and explore remarkable geological features, as topographically complex as features on land, and deep-sea ecosystems teeming with biodiversity. The USGS works with academic, industry and other private and federal partners to advance our technological capabilities. Learn more about USGS deep sea research.
Thanks to these underwater vehicles, USGS scientists can investigate deepwater ecosystems such as hydrothermal vents, canyons, and cold seeps, working to characterize the microbial and benthic communities they support. USGS scientists identify, characterize, and quantify environmental microbial communities, which are critical components of healthy marine ecosystems. They also conduct research to understand community and food web structure, biodiversity, and habitat connectivity of marine benthic ecosystems, which involves examining the small animals that live in or on the seafloor. By providing a baseline understanding of these never-explored habitats, USGS science helps inform issues, such as the management of resource use and energy production.
We know that some of these areas are physically and biologically well-connected to land areas as well as to each other through areas of specialized research. Many explorative research efforts are collaborative and multidisciplinary in nature, developing holistic understanding of the ocean, from geologic structure and hazards, geochemistry and the unique mineralogic and biological communities that have developed in these environments. Scientists believe that life on Earth began more than 3.5 billion years ago in the ocean. The linkages between these remote areas and human populations and activities may not be as far removed as we think.
Innovative Technology
Exploring new places often requires new ways of doing things. New equipment, methods and capabilities are needed to access and study these hard-to-reach these locations, to obtain samples, and to ensure that these samples are preserved so they are useful at land surface. The USGS has worked with many partners to design specific new tools and capabilities so that we can learn as much as we can with each visit to these remote areas. This extensive network has allowed the USGS to tap into innovative technologies, for example, benthic landers for long-term data collection in the Atlantic Ocean and Gulf of Mexico and methane gas bubble collectors in the Pacific Ocean.
Publications
Realizing the potential of eDNA biodiversity monitoring tools in the marine environment with application to offshore renewable energy
The U.S. Geological Survey (USGS) researches the biological diversity and distribution of species to support management, conservation, and resource use decisions. USGS scientists advance detection and monitoring technologies to assess changes in fish and wildlife populations, biodiversity, and the health of ecosystems. The United States is planning to install 30 gigawatts of offshore marine and wi
Accurate bathymetric maps from underwater digital imagery without ground control
Windows to the deep 2018: Exploration of the southeast US Continental margin
Deep search: Deep sea exploration to advance research on coral/canyon/cold seep habitats
Discovering the deep: Exploring remote Pacific marine protected areas
Science
EXPRESS: Expanding Pacific Research and Exploration of Submerged Systems
USGS Role in DEEP SEARCH: Deep Sea Exploration to Advance Research on Coral, Canyon, and Cold-seep Habitats
DISCOVRE: Diversity, Systematics and Connectivity of Vulnerable Reef Ecosystems
U.S. Geological Survey Gas Hydrates Project
The Mid-Atlantic Resource Imaging Experiment (MATRIX)
Multimedia
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
News
A new strategy to help unleash USGS eDNA capabilities
Deep Dive: Whence Comes the Name “Escanaba”?
Escanaba Trough Expedition: Updates From Sea
Realizing the potential of eDNA biodiversity monitoring tools in the marine environment with application to offshore renewable energy
The U.S. Geological Survey (USGS) researches the biological diversity and distribution of species to support management, conservation, and resource use decisions. USGS scientists advance detection and monitoring technologies to assess changes in fish and wildlife populations, biodiversity, and the health of ecosystems. The United States is planning to install 30 gigawatts of offshore marine and wi
Accurate bathymetric maps from underwater digital imagery without ground control
Windows to the deep 2018: Exploration of the southeast US Continental margin
Deep search: Deep sea exploration to advance research on coral/canyon/cold seep habitats
Discovering the deep: Exploring remote Pacific marine protected areas
Learn more about USGS deep sea research.
EXPRESS: Expanding Pacific Research and Exploration of Submerged Systems
USGS Role in DEEP SEARCH: Deep Sea Exploration to Advance Research on Coral, Canyon, and Cold-seep Habitats
DISCOVRE: Diversity, Systematics and Connectivity of Vulnerable Reef Ecosystems
U.S. Geological Survey Gas Hydrates Project
The Mid-Atlantic Resource Imaging Experiment (MATRIX)
IMMeRSS-- Interagency Mission for Methane Research on Seafloor Seeps
Expanding Pacific Exploration and Research: Overview of the EXPRESS research campaign
A multi-agency team is mapping uncharted waters and exploring deep-sea ecosystems off the west coast of the United States.
Oceans cover 71% of the Earth's surface, yet little is known about these vast underwater worlds. Less than 20% have been explored. A global initiative seeks to change that, by pledging to complete detailed mapping of one-hundred percent of the seafloor by the year 2030..
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Seafloor features such as sulfide mounds and chimneys are prominent evidence of hydrothermal activity. These features, whether active or dormant, are just the tip of the iceberg, so to speak; much of the “plumbing” of hydrothermal systems exists beneath the seafloor surface.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
Critical to scientific operations aboard the Escanaba Trough expedition is the submersible robots Sentry and Jason. Owned and operated by the Woods Hole Oceanographic Institute (WHOI), these robots allow researchers to observe seafloor features and collect data from depths seldom visited by humans.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
For scientists aboard the Escanaba Trough expedition, obtaining sediment cores or deep-sea biological and geological samples after a Jason dive is only the beginning.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
Embarking on a three-week deep-sea research expedition requires a lot of preparation. For this expedition to Escanaba Trough, U.S. Geological Survey scientists and partners spend the first few days in port, building their laboratory space aboard the research vessel Thomas G. Thompson.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
These 3D perspective views of the seafloor bathymetry from multibeam sonar offshore of South Carolina show numerous grooves carved by drifting icebergs. As iceberg keels plow into the seafloor, they dig deep grooves that push aside boulders and piles of sand and mud along their tracks.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
Remotely operated vehicle Deep Discoverer surveys a large boulder covered in bamboo corals during the 2021 North Atlantic Stepping Stones expedition. Bamboo corals were locally abundant on these large boulders and more spread out throughout different hard-bottom habitats.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist for this expedition, unloads several push cores taken from the sediment at the ocean floor by ROV SuBastian.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
ROV SuBastian arrives at the landing site of one of the UNC landers. The ROV will reposition the lander so it is nearer to a methane seep so it can begin its experiment.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
USGS scientist Amanda Demopoulos, lead scientist on this cruise, helps unload the collections from a Grays Canyon dive by ROV SuBastian.
Oceanographic instrumentation is ready for deployment off of Fire Island to measure how the offshore bathymetry (shown in background map) influences coastal response.
Oceanographic instrumentation is ready for deployment off of Fire Island to measure how the offshore bathymetry (shown in background map) influences coastal response.
Seafloor geology map from a 2017 journal article by Johnson and others, published in Coastal and Ocean Management. Shaded digital elevation model (DEM) showing submarine landslides and sites of potential f
Seafloor geology map from a 2017 journal article by Johnson and others, published in Coastal and Ocean Management. Shaded digital elevation model (DEM) showing submarine landslides and sites of potential f
ROV/submersible used to sample the deep-sea canyon
ROV/submersible used to sample the deep-sea canyon
The submersible Delta is launched on a dive to document bottom communities with a video camera and to collect coral specimens.
The submersible Delta is launched on a dive to document bottom communities with a video camera and to collect coral specimens.
Dr. Christina Kellogg emerges from the submersible Delta after collecting coral samples in the Aleutian Islands in 2004.
Dr. Christina Kellogg emerges from the submersible Delta after collecting coral samples in the Aleutian Islands in 2004.
Bathymetry of the coastal ocean offshore of the New York metropolitan region
Bathymetry of the coastal ocean offshore of the New York metropolitan region
Dr. Christina Kellogg, USGS DISCOVRE's microbiologist, begins a dive in the Johnson-Sea-Link submersible to study deep-sea coral. The submersible can reach depths of 900 meters and has a manipulator arm and suction tool for collecting samples.
Dr. Christina Kellogg, USGS DISCOVRE's microbiologist, begins a dive in the Johnson-Sea-Link submersible to study deep-sea coral. The submersible can reach depths of 900 meters and has a manipulator arm and suction tool for collecting samples.