Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Christopher G. Smith, Ph.D.
As a coastal geologist, my research focuses on the transport, transformation, and deposition of particulate and dissolved constituents within the coastal realm and how system processes will respond to large-scale environmental forcings (e.g., climate change).
Coastal systems provide a dynamic interface between terrestrial and marine realms; anthropogenic activity and natural processes occurring within terrestrial ecosystems can have a significant impact to the coastal zone and adjacent marine system. Augmentation of coastal systems is inevitable from a human perspective as nearly half of the population of the United States reside within coastal counties. Understanding modern processes (sedimentologic, hydrologic, and geochemical) occurring along this terrestrial-marine continuum is critical in predicting the response associated with natural and anthropogenic perturbations.
My research interests generally fall into two categories: 1) fluid exchange (e.g., surface water – groundwater exchange, submarine and coastal groundwater discharge) and 2) fine-grained sediment dynamics, specifically in marsh and estuarine environments. Linking these two seemingly disparate research topics are naturally-occurring (e.g., U-Th series) and anthropogenically-introduced/spiked (e.g., 137Cs) radionuclides. Particle reactive radionuclides (e.g., 7Be, 234Th, 210Pb, 210Po, and 137Cs) provide excellent tracers to quantify sediment deposition and re-mobilization over time-scales of months to decades. Examining the final sedimentary product in the context of the temporal framework and associated transient changes also provide a breadth of knowledge to environmental conditions that persisted in recent past and the outcome that may be expected if similar conditions persist in the present or future. Alternatively, the more conservative behavior of radon and radium isotopes have proven these as excellent tracers to quantify groundwater discharge in both fresh and marine environments.
Over the last three decades, groundwater discharge to the coastal zone has received increasing recognition as a substantial material vector, influencing water quality and nutrient fluxes. Quantification of fresh and marine groundwater end-members and the processes that drive the exchange (e.g., seasonal recharge cycles, hurricanes and tropical cyclones) are critical to assess the overall importance of coastal groundwater and has been at the forefront of my research.
Professional Experience
2010-Present: Research Geologist, USGS, St. Petersburg Coastal and Marine Science Center
2008 - 2010: USGS Mendenhall Fellow, St. Petersburg Coastal and Marine Science Center
Education and Certifications
PhD - Oceanography & Coastal Science (Geological conc) (2008) from Louisiana State University (Geaux Tigers!)
MS - Geology (2004) from East Carolina University
BS - Geology (2001) from East Carolina University (NC)
Science and Products
Submarine Groundwater Discharge
Estuarine and MaRsh Geology Research Project
Alabama Barrier Island Restoration Assessment
Hurricane Sandy Response- Linking the Delmarva Peninsula's Geologic Framework to Coastal Vulnerability
Sea-level and Storm Impacts on Estuarine Environments and Shorelines (SSIEES)
Alabama Barrier Island Restoration Study
Improving Our Ability to Forecast Tidal Marsh Response to Sea Level Rise
Single-beam Bathymetry Data Collected in 2022 From Point Aux Chenes Bay, Mississippi
Modeling the Effects of Interior Headland Restoration on Estuarine Sediment Transport Processes in a Marine-Dominant Estuary: Delft3D Model Output
Geochemical and fallout radionuclide data for sediment source fingerprinting studies of the Loutsenhizer Arroyo and Sunflower Drain watersheds in western Colorado
Radioanalytical Measurements on Samples From Submarine, Karstic Carbonate Features Along the West Florida Shelf
Relict karstic features, often referred to as blue holes, are common features along continental shelves that are underlain by carbonate rich sediments and/or rocks. Several of these features occur along the west-Florida shelf within the Gulf of Mexico, including the two mentioned in this data product: Amberjack Hole and Green Banana Sink (hereafter referred to as Green Banana). Scientists from U.S
Radiochemical Data From Sediment Cores Collected on Deer Island, Mississippi
Sediment and Radiochemical Characteristics from Shore-Perpendicular Estuarine and Marsh Transects in the Grand Bay National Estuarine Research Reserve, Mississippi
Surficial and Downcore Sedimentological and Foraminiferal Microfossil Data From St. Marks National Wildlife Refuge, Florida
Sediment Core Microfossil Data Collected from the Coastal Marsh of Grand Bay National Estuarine Research Reserve, Mississippi, USA
Single-Beam Bathymetry Data Collected in March 2021 from Grand Bay and Point Aux Chenes Bay, Mississippi/Alabama
Sedimentologic Data from Point aux Chenes Marsh and Estuary, Mississippi
Multibeam Bathymetry Data Collected in 2019 from Grand Bay and Point Aux Chenes Bay Alabama/Mississippi
Sediment Radiochemical Data from Georgia, Massachusetts and Virginia Coastal Marshes
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds examines a submarine groundwater well on the seafloor before hooking up the well to a pump on the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds examines a submarine groundwater well on the seafloor before hooking up the well to a pump on the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds next to a submarine groundwater well on the seafloor. Tubing was hooked up the well to pump groundwater to the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds next to a submarine groundwater well on the seafloor. Tubing was hooked up the well to pump groundwater to the surface to ensure the wells are working properly and producing groundwater.
Identifying and constraining marsh-type transitions in response to increasing erosion over the past century
Modeling the effects of interior headland restoration on estuarine sediment transport processes in a marine-dominant estuary
Source contributions to suspended sediment and particulate selenium export from the Loutsenhizer Arroyo and Sunflower Drain watersheds in Colorado
Mode and provenance of sediment deposition on a transgressive marsh
Reconciling models and measurements of marsh vulnerability to sea level rise
Lateral shoreline erosion and shore-proximal sediment deposition on a coastal marsh from seasonal, storm and decadal measurements
Impacts of sediment removal from and placement in coastal barrier island systems
Executive SummaryOn June 24, 2019, Congressman Raul Grijalva of Arizona, Chair of the House Committee on Natural Resources, sent a letter to the directors of the U.S. Fish and Wildlife Service and the U.S. Geological Survey to request their assistance in answering questions regarding coastal sediment resource management within the Coastal Barrier Resources System as defined by the Coastal Barrier
Emerging dominance of Paratrochammina simplissima (Cushman and McCulloch) in the northern Gulf of Mexico following hydrologic and geomorphic changes
Gulf of Mexico blue hole harbors high levels of novel microbial lineages
Using multiple environmental proxies and hydrodynamic modeling to investigate Late Holocene climate and coastal change within a large Gulf of Mexico estuarine system (Mobile Bay, Alabama, USA)
Council Monitoring and Assessment Program (CMAP): Inventory of existing water quality and habitat monitoring, and mapping metadata for Gulf of Mexico Programs
Temperature mediates secondary dormancy in resting cysts of Pyrodinium bahamense (Dinophyceae)
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.
Science and Products
Submarine Groundwater Discharge
Estuarine and MaRsh Geology Research Project
Alabama Barrier Island Restoration Assessment
Hurricane Sandy Response- Linking the Delmarva Peninsula's Geologic Framework to Coastal Vulnerability
Sea-level and Storm Impacts on Estuarine Environments and Shorelines (SSIEES)
Alabama Barrier Island Restoration Study
Improving Our Ability to Forecast Tidal Marsh Response to Sea Level Rise
Single-beam Bathymetry Data Collected in 2022 From Point Aux Chenes Bay, Mississippi
Modeling the Effects of Interior Headland Restoration on Estuarine Sediment Transport Processes in a Marine-Dominant Estuary: Delft3D Model Output
Geochemical and fallout radionuclide data for sediment source fingerprinting studies of the Loutsenhizer Arroyo and Sunflower Drain watersheds in western Colorado
Radioanalytical Measurements on Samples From Submarine, Karstic Carbonate Features Along the West Florida Shelf
Relict karstic features, often referred to as blue holes, are common features along continental shelves that are underlain by carbonate rich sediments and/or rocks. Several of these features occur along the west-Florida shelf within the Gulf of Mexico, including the two mentioned in this data product: Amberjack Hole and Green Banana Sink (hereafter referred to as Green Banana). Scientists from U.S
Radiochemical Data From Sediment Cores Collected on Deer Island, Mississippi
Sediment and Radiochemical Characteristics from Shore-Perpendicular Estuarine and Marsh Transects in the Grand Bay National Estuarine Research Reserve, Mississippi
Surficial and Downcore Sedimentological and Foraminiferal Microfossil Data From St. Marks National Wildlife Refuge, Florida
Sediment Core Microfossil Data Collected from the Coastal Marsh of Grand Bay National Estuarine Research Reserve, Mississippi, USA
Single-Beam Bathymetry Data Collected in March 2021 from Grand Bay and Point Aux Chenes Bay, Mississippi/Alabama
Sedimentologic Data from Point aux Chenes Marsh and Estuary, Mississippi
Multibeam Bathymetry Data Collected in 2019 from Grand Bay and Point Aux Chenes Bay Alabama/Mississippi
Sediment Radiochemical Data from Georgia, Massachusetts and Virginia Coastal Marshes
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
A team from the USGS St. Petersburg Coastal and Marine Science Center heads out into the Gulf of Mexico to check on a set of recently installed groundwater wells. These types of wells allow scientists to monitor submarine groundwater through time and quantify the flux of groundwater from Florida’s aquifer into the coastal waters of the west Florida Shelf.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
Dr. Christopher G. Smith pumps water from a submarine groundwater well on the seafloor through tubing to the R/V Halimeda and uses an instrument called a YSI to measure salinity and ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds examines a submarine groundwater well on the seafloor before hooking up the well to a pump on the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds examines a submarine groundwater well on the seafloor before hooking up the well to a pump on the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds next to a submarine groundwater well on the seafloor. Tubing was hooked up the well to pump groundwater to the surface to ensure the wells are working properly and producing groundwater.
USGS scientific diver BJ Reynolds next to a submarine groundwater well on the seafloor. Tubing was hooked up the well to pump groundwater to the surface to ensure the wells are working properly and producing groundwater.
Identifying and constraining marsh-type transitions in response to increasing erosion over the past century
Modeling the effects of interior headland restoration on estuarine sediment transport processes in a marine-dominant estuary
Source contributions to suspended sediment and particulate selenium export from the Loutsenhizer Arroyo and Sunflower Drain watersheds in Colorado
Mode and provenance of sediment deposition on a transgressive marsh
Reconciling models and measurements of marsh vulnerability to sea level rise
Lateral shoreline erosion and shore-proximal sediment deposition on a coastal marsh from seasonal, storm and decadal measurements
Impacts of sediment removal from and placement in coastal barrier island systems
Executive SummaryOn June 24, 2019, Congressman Raul Grijalva of Arizona, Chair of the House Committee on Natural Resources, sent a letter to the directors of the U.S. Fish and Wildlife Service and the U.S. Geological Survey to request their assistance in answering questions regarding coastal sediment resource management within the Coastal Barrier Resources System as defined by the Coastal Barrier
Emerging dominance of Paratrochammina simplissima (Cushman and McCulloch) in the northern Gulf of Mexico following hydrologic and geomorphic changes
Gulf of Mexico blue hole harbors high levels of novel microbial lineages
Using multiple environmental proxies and hydrodynamic modeling to investigate Late Holocene climate and coastal change within a large Gulf of Mexico estuarine system (Mobile Bay, Alabama, USA)
Council Monitoring and Assessment Program (CMAP): Inventory of existing water quality and habitat monitoring, and mapping metadata for Gulf of Mexico Programs
Temperature mediates secondary dormancy in resting cysts of Pyrodinium bahamense (Dinophyceae)
Non-USGS Publications**
**Disclaimer: The views expressed in Non-USGS publications are those of the author and do not represent the views of the USGS, Department of the Interior, or the U.S. Government.