Biogeochemistry Group Active
Hydrologic technicians deploying a flow sensor on a shoal in San Francisco Bay to investigate phytoplankton production and nutrient transformations.
A view from the office: USGS scientists heading out to deploy sensors for sediment nutrient storage and release in Rodeo Lagoon.
USGS laboratory technician filtering for chlorophyll-a.
Scientists aboard research vessel Aiken conduct water-quality mapping in support of wastewater-derived nutrients project.
The Biogeochemistry (BGC) Group uses an interdisciplinary approach to address surface water quality issues and food web dynamics throughout California, particularly in the Sacramento-San Joaquin Delta and San Francisco Bay.
Study areas include:
- Drivers of phytoplankton community composition and abundance and harmful algal bloom-related toxins
- Long-term continuous monitoring of numerous water quality constituents, phytoplankton, phytoplankton community structure, dissolved organic carbon and nitrogen as well as other constituents important to aquatic systems
- Changes in wastewater-derived nutrients and effects on phytoplankton community structure
- Effects of flow and water residence time on nutrient cycling and phytoplankton
- The impacts of invasive aquatic vegetation on water quality, water residence time, and native phytoplankton
- Assessing the role of wetlands in the Delta with respect to such topics as mercury, nutrients, drinking water quality and phytoplankton production
- Assessing the potential of tidal wetlands to mitigate land subsidence and sequester carbon
- Supporting improved water quality management through development of new sensors, analyses and techniques such as direct residence time measurements, custom sensor technologies, wide-area high-speed mapping surveys, remote sensing calibration and validation and other related activities
The BGC Group specializes in the application of in-situ optical sensors that monitor short- and long-term water quality trends. These sensors measure a host of biogeochemical parameters and capture continuous temporal trends – including those that may go undetected through traditional discrete sampling. The BGC Group also employs novel high-resolution boat-based mapping surveys, conducting intensive sampling for a diverse variety of biogeochemical parameters throughout the Bay-Delta.
These studies and data will help resource managers assess response to management actions and predict how the Bay-Delta will respond to future changes. The high frequency, real-time data can act as an early warning system for unanticipated, short-lived, or rapidly changing conditions, such as those due to spills, harmful algal blooms, and altered water-quality resulting from storms or levee breaches. The BGC group additionally specialize in the creation of novel data dissemination techniques in effort to ease open data acquisition, ultimately aiming to advance Bay-Delta science.
Additional Biogeochemistry Group staff include:
- Malanyon Adams
- Dulci Avouris
- Tom Bergamaschi
- Tim Baxter
- Heidi Bockisch
- Bryan Bonham
- Jake Brinkman
- Dylan Burau
- Jordy Conneely
- Ayelet Delascagigas
- Patrick Dellwo
- Nicholas Framsted
- Tommy (Hieu) Ly
- Andrea Jaegge
- Nathan Jumps
- Colin Keating
- Anne Le
- Ariana Maestas
- Kat Mai Cone
- Schuyler Nardelli
- Erica Nejad
- Dianna Oros
- Emily Richardson
- Tara Schraga
- Jesse Schroeder
- Jennifer Soto-Perez
- Corrine Sanford
- Crystal Sturgeon
- Maura Uebner
Below are other science projects associated with this project.
Below are multimedia items associated with this project.
Below are publications associated with this project.
Fluorescence-based proxies for lignin in freshwater dissolved organic matter
Assessing the sources and magnitude of diurnal nitrate variability in the San Joaquin River (California) with an in situ optical nitrate sensor and dual nitrate isotopes
High-frequency in situ optical measurements during a storm event: Assessing relationships between dissolved organic matter, sediment concentrations, and hydrologic processes
Quantifying fluxes and characterizing compositional changes of dissolved organic matter in aquatic systems in situ using combined acoustic and optical measurements
Assessing the contribution of wetlands and subsided islands to dissolved organic matter and disinfection byproduct precursors in the Sacramento-San Joaquin River Delta: A geochemical approach
Environmental occurrence and shallow ground water detection of the antibiotic monensin from dairy farms
Assessing contribution of DOC from sediments to a drinking-water reservoir using optical profiling
The role of hydrologic regimes on dissolved organic carbon composition in an agricultural watershed
Land management impacts on dairy-derived dissolved organic carbon in ground water
Below are data or web applications associated with this project.
Below are news stories associated with this project.
Below are partners associated with this project.
- Overview
The Biogeochemistry (BGC) Group uses an interdisciplinary approach to address surface water quality issues and food web dynamics throughout California, particularly in the Sacramento-San Joaquin Delta and San Francisco Bay.
Study areas include:
- Drivers of phytoplankton community composition and abundance and harmful algal bloom-related toxins
- Long-term continuous monitoring of numerous water quality constituents, phytoplankton, phytoplankton community structure, dissolved organic carbon and nitrogen as well as other constituents important to aquatic systems
- Changes in wastewater-derived nutrients and effects on phytoplankton community structure
- Effects of flow and water residence time on nutrient cycling and phytoplankton
- The impacts of invasive aquatic vegetation on water quality, water residence time, and native phytoplankton
- Assessing the role of wetlands in the Delta with respect to such topics as mercury, nutrients, drinking water quality and phytoplankton production
- Assessing the potential of tidal wetlands to mitigate land subsidence and sequester carbon
- Supporting improved water quality management through development of new sensors, analyses and techniques such as direct residence time measurements, custom sensor technologies, wide-area high-speed mapping surveys, remote sensing calibration and validation and other related activities
The BGC Group specializes in the application of in-situ optical sensors that monitor short- and long-term water quality trends. These sensors measure a host of biogeochemical parameters and capture continuous temporal trends – including those that may go undetected through traditional discrete sampling. The BGC Group also employs novel high-resolution boat-based mapping surveys, conducting intensive sampling for a diverse variety of biogeochemical parameters throughout the Bay-Delta.
These studies and data will help resource managers assess response to management actions and predict how the Bay-Delta will respond to future changes. The high frequency, real-time data can act as an early warning system for unanticipated, short-lived, or rapidly changing conditions, such as those due to spills, harmful algal blooms, and altered water-quality resulting from storms or levee breaches. The BGC group additionally specialize in the creation of novel data dissemination techniques in effort to ease open data acquisition, ultimately aiming to advance Bay-Delta science.
Additional Biogeochemistry Group staff include:
- Malanyon Adams
- Dulci Avouris
- Tom Bergamaschi
- Tim Baxter
- Heidi Bockisch
- Bryan Bonham
- Jake Brinkman
- Dylan Burau
- Jordy Conneely
- Ayelet Delascagigas
- Patrick Dellwo
- Nicholas Framsted
- Tommy (Hieu) Ly
- Andrea Jaegge
- Nathan Jumps
- Colin Keating
- Anne Le
- Ariana Maestas
- Kat Mai Cone
- Schuyler Nardelli
- Erica Nejad
- Dianna Oros
- Emily Richardson
- Tara Schraga
- Jesse Schroeder
- Jennifer Soto-Perez
- Corrine Sanford
- Crystal Sturgeon
- Maura Uebner
- Science
Below are other science projects associated with this project.
Filter Total Items: 18 - Multimedia
Below are multimedia items associated with this project.
- Publications
Below are publications associated with this project.
Filter Total Items: 69Fluorescence-based proxies for lignin in freshwater dissolved organic matter
Lignin phenols have proven to be powerful biomarkers in environmental studies; however, the complexity of lignin analysis limits the number of samples and thus spatial and temporal resolution in any given study. In contrast, spectrophotometric characterization of dissolved organic matter (DOM) is rapid, noninvasive, relatively inexpensive, requires small sample volumes, and can even be measured inAuthorsPeter J. Hernes, Brian A. Bergamaschi, Robert S. Eckard, Robert G.M. SpencerAssessing the sources and magnitude of diurnal nitrate variability in the San Joaquin River (California) with an in situ optical nitrate sensor and dual nitrate isotopes
1. We investigated diurnal nitrate (NO3−) concentration variability in the San Joaquin River using an in situ optical NO3− sensor and discrete sampling during a 5‐day summer period characterized by high algal productivity. Dual NO3− isotopes (δ15NNO3 and δ18ONO3) and dissolved oxygen isotopes (δ18ODO) were measured over 2 days to assess NO3− sources and biogeochemical controls over diurnal time‐scAuthorsBrian A. Pellerin, Bryan D. Downing, Carol Kendall, Randy A. Dahlgren, Tamara E.C. Kraus, John Franco Saraceno, Robert G. M. Spencer, Brian A. BergamaschiHigh-frequency in situ optical measurements during a storm event: Assessing relationships between dissolved organic matter, sediment concentrations, and hydrologic processes
Dissolved organic matter (DOM) dynamics during storm events has received considerable attention in forested watersheds, but the extent to which storms impart rapid changes in DOM concentration and composition in highly disturbed agricultural watersheds remains poorly understood. In this study, we used identical in situ optical sensors for DOM fluorescence (FDOM) with and without filtration to contAuthorsJohn Franco Saraceno, Brian A. Pellerin, Bryan D. Downing, Emmanuel Boss, Philip A. M. Bachand, Brian A. BergamaschiQuantifying fluxes and characterizing compositional changes of dissolved organic matter in aquatic systems in situ using combined acoustic and optical measurements
Studying the dynamics and geochemical behavior of dissolved and particulate organic material is difficult because concentration and composition may rapidly change in response to aperiodic as well as periodic physical and biological forcing. Here we describe a method useful for quantifying fluxes and analyzing dissolved organic matter (DOM) dynamics. The method uses coupled optical and acoustic meaAuthorsB.D. Downing, E. Boss, B.A. Bergamaschi, J.A. Fleck, M. A. Lionberger, N. K. Ganju, D. H. Schoellhamer, R. FujiiAssessing the contribution of wetlands and subsided islands to dissolved organic matter and disinfection byproduct precursors in the Sacramento-San Joaquin River Delta: A geochemical approach
This study assesses how rivers, wetlands, island drains and open water habitats within the Sacramento-San Joaquin River Delta affect dissolved organic matter (DOM) content and composition, and disinfection byproduct (DBP) formation. Eleven sites representative of these habitats were sampled on six dates to encompass seasonal variability. Using a suite of qualitative analyses, including specific DBAuthorsT.E.C. Kraus, B.A. Bergamaschi, P.J. Hernes, R.G.M. Spencer, R. Stepanauskas, C. Kendall, R.F. Losee, R. FujiiEnvironmental occurrence and shallow ground water detection of the antibiotic monensin from dairy farms
Pharmaceuticals used in animal feeding operations have been detected in various environmental settings. There is a growing concern about the impact on terrestrial and aquatic organisms and the development of antibiotic-resistant strains of microorganisms. Pharmaceutical use in milking cows is relatively limited compared with other livestock operations, except for the ionophore monensin, which is gAuthorsN. Watanabe, T.H. Harter, B.A. BergamaschiAssessing contribution of DOC from sediments to a drinking-water reservoir using optical profiling
Understanding the sources of dissolved organic carbon (DOC) in drinking-water reservoirs is an important management issue because DOC may form disinfection by-products, interfere with disinfection, or increase treatment costs. DOC may be derived from a host of sources-algal production of DOC in the reservoir, marginal production of DOC from mucks and vascular plants at the margins, and sediments iAuthorsBryan D. Downing, Brian A. Bergamaschi, David G. Evans, Emmanuel BossThe role of hydrologic regimes on dissolved organic carbon composition in an agricultural watershed
Willow Slough, a seasonally irrigated agricultural watershed in the Sacramento River valley, California, was sampled weekly in 2006 in order to investigate seasonal concentrations and compositions of dissolved organic carbon (DOC). Average DOC concentrations nearly doubled from winter baseflow (2.75 mg L-1) to summer irrigation (5.14 mg L-1), while a concomitant increase in carbon-normalized vanilAuthorsP.J. Hernes, R.G.M. Spencer, R.Y. Dyda, B.A. Pellerin, P.A.M. Bachand, B.A. BergamaschiLand management impacts on dairy-derived dissolved organic carbon in ground water
Dairy operations have the potential to elevate dissolved organic carbon (DOC) levels in ground water, where it may interact with organic and inorganic contaminants, fuel denitrification, and may present problems for drinking water treatment. Total and percent bioavailable DOC and total and carbon-specific trihalomethane (THM) formation potential (TTHMFP and STHMFP, respectively) were determined foAuthorsJ.C. Chomycia, P.J. Hernes, T. Harter, B.A. Bergamaschi - Web Tools
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