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.
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Escanaba Trough Expedition: Gravity Coring (AD)
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.
Image of the Week - Catfish Ponds in Mississippi
Mississippi leads the U.S. in catfish production. The blue tinted shapes in these Landsat images mark ponds where catfish are raised.
Mississippi leads the U.S. in catfish production. The blue tinted shapes in these Landsat images mark ponds where catfish are raised.
Re-greening a Dryland Watershed
The installation of thousands of rock detention structures in the Turkey Pen Watershed, of the Chiricahua Mountains in SE Arizona, provided a 30-year case study to consider low-tech and low-cost Natural Infrastructure in dryland watersheds.
The installation of thousands of rock detention structures in the Turkey Pen Watershed, of the Chiricahua Mountains in SE Arizona, provided a 30-year case study to consider low-tech and low-cost Natural Infrastructure in dryland watersheds.
Escanaba Trough Expedition: Part 2
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.
Escanaba Trough Expedition: Part 2 (AD)
Critical to scientific operations aboard the Escanaba Trough expedition are 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 are 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.
Escanaba Trough Expedition: Part 3
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.
Escanaba Trough Expedition: Part 3 (AD)
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.
Eyes on Earth Episode 76 – ECOSTRESS and Disease Risk
Eyes on Earth Episode 76 – ECOSTRESS and Disease RiskSpaceborne sensors orbit hundreds of miles over our heads. Even the most advanced among them struggle to capture high-resolution imagery of individual human beings. Mosquitos, of course, are far smaller than we are. Clearly, sensors on a satellite or space station can’t see them.
Eyes on Earth Episode 76 – ECOSTRESS and Disease Risk
Eyes on Earth Episode 76 – ECOSTRESS and Disease RiskSpaceborne sensors orbit hundreds of miles over our heads. Even the most advanced among them struggle to capture high-resolution imagery of individual human beings. Mosquitos, of course, are far smaller than we are. Clearly, sensors on a satellite or space station can’t see them.
The RAD (Resist-Accept-Direct) Climate Adaptation Framework
The RAD (Resist-Accept-Direct) Climate Adaptation FrameworkEcosystems are transforming under climate change, with substantial shifts in ecological processes (e.g. fire, landscape connectivity) and important ecosystem services (e.g. pollination, water filtration) occurring at unprecedented rates.
The RAD (Resist-Accept-Direct) Climate Adaptation Framework
The RAD (Resist-Accept-Direct) Climate Adaptation FrameworkEcosystems are transforming under climate change, with substantial shifts in ecological processes (e.g. fire, landscape connectivity) and important ecosystem services (e.g. pollination, water filtration) occurring at unprecedented rates.
Escanaba Trough Expedition: Introduction
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.
Escanaba Trough Expedition: Introduction (AD)
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.
Landers Rupture — Andy on significance of the Landers earthquake
Landers Rupture — Andy on significance of the Landers earthquakeUSGS seismologist Andrew Michael talks about the significance of the 1992 Landers earthquake.
Landers Rupture — Andy on significance of the Landers earthquake
Landers Rupture — Andy on significance of the Landers earthquakeUSGS seismologist Andrew Michael talks about the significance of the 1992 Landers earthquake.
Landers Rupture — Andy on using satellite data
USGS seismologist Andrew Michael talks about the remote location of the 1992 Landers earthquake and how researchers were able to use satellite data to better see the quake’s impacts.
USGS seismologist Andrew Michael talks about the remote location of the 1992 Landers earthquake and how researchers were able to use satellite data to better see the quake’s impacts.
Landers Rupture — Joan on little skull mountain
USGS seismologist Joan Gomberg recalls the earthquake on Little Skull Mountain related to the 1992 Landers earthquake.
USGS seismologist Joan Gomberg recalls the earthquake on Little Skull Mountain related to the 1992 Landers earthquake.
Landers Rupture — Jonathan Fieldwork
USGS geologist Jonathan Matti recalls fieldwork in the Mojave Desert soon after the 1992 Landers earthquake.
USGS geologist Jonathan Matti recalls fieldwork in the Mojave Desert soon after the 1992 Landers earthquake.
Landers Rupture — Ruth on impact to San Andreas
USGS seismologist Ruth Harris talks about how the 1992 Landers earthquake caused concern for the San Andreas fault.
USGS seismologist Ruth Harris talks about how the 1992 Landers earthquake caused concern for the San Andreas fault.
Landers Rupture — Scott on what it looked like
USGS field technician Scott Lydeen recalls what the aftermath of the 1992 Landers earthquake looked like.
USGS field technician Scott Lydeen recalls what the aftermath of the 1992 Landers earthquake looked like.
Landers Rupture — Sue on her role after the earthquake and seismic monitoring in Southern CA
Landers Rupture — Sue on her role after the earthquake and seismic monitoring in Southern CAUSGS seismologist Susan Hough talks about her role following the 1992 Landers earthquake and seismic monitoring stations in Southern California.
Landers Rupture — Sue on her role after the earthquake and seismic monitoring in Southern CA
Landers Rupture — Sue on her role after the earthquake and seismic monitoring in Southern CAUSGS seismologist Susan Hough talks about her role following the 1992 Landers earthquake and seismic monitoring stations in Southern California.
Landers Rupture — Sue on how monitoring networks evolved
Landers Rupture — Sue on how monitoring networks evolvedUSGS seismologist Susan Hough described the Southern California Seismic Network and how it was used for the 1992 Landers earthquake.
Landers Rupture — Sue on how monitoring networks evolved
Landers Rupture — Sue on how monitoring networks evolvedUSGS seismologist Susan Hough described the Southern California Seismic Network and how it was used for the 1992 Landers earthquake.
Landers Rupture — Sue on what it felt like
USGS seismologist Susan Hough recalls what the 1992 Landers earthquake felt like from Pasadena, CA.
USGS seismologist Susan Hough recalls what the 1992 Landers earthquake felt like from Pasadena, CA.
Landers Rupture — Sue on what we've learned since
USGS seismologist Susan Hough discusses what we’ve learned since the 1992 Landers earthquake.
USGS seismologist Susan Hough discusses what we’ve learned since the 1992 Landers earthquake.