Novel use of cavity ring-down spectroscopy to investigate aquatic carbon cycling from microbial to ecosystem scales

Environ Sci Technol. 2013 Nov 19;47(22):12938-45. doi: 10.1021/es4027776. Epub 2013 Nov 1.

Abstract

Development of cavity ring-down spectroscopy (CRDS) has enabled real-time monitoring of carbon stable isotope ratios of carbon dioxide and methane in air. Here we demonstrate that CRDS can be adapted to assess aquatic carbon cycling processes from microbial to ecosystem scales. We first measured in situ isotopologue concentrations of dissolved CO2 ((12)CO2 and (13)CO2) and CH4 ((12)CH4 and (13)CH4) with CRDS via a closed loop gas equilibration device during a survey along an estuary and during a 40 h time series in a mangrove creek (ecosystem scale). A similar system was also connected to an in situ benthic chamber in a seagrass bed (community scale). Finally, a pulse-chase isotope enrichment experiment was conducted by measuring real-time release of (13)CO2 after addition of (13)C enriched phytoplankton to exposed intertidal sediments (microbial scale). Miller-Tans plots revealed complex transformation pathways and distinct isotopic source values of CO2 and CH4. Calculations of δ(13)C-DIC based on CRDS measured δ(13)C-CO2 and published fractionation factors were in excellent agreement with measured δ(13)C-DIC using isotope ratio mass spectroscopy (IRMS). The portable CRDS instrumentation used here can obtain real-time, high precision, continuous greenhouse gas data in lakes, rivers, estuaries and marine waters with less effort than conventional laboratory-based techniques.

Publication types

  • Research Support, Non-U.S. Gov't

MeSH terms

  • Aquatic Organisms / metabolism*
  • Australia
  • Bacteria / metabolism*
  • Carbon Cycle*
  • Carbon Dioxide / analysis
  • Carbon Isotopes
  • Ecosystem*
  • Estuaries
  • Linear Models
  • Mass Spectrometry
  • Methane / analysis
  • Phytoplankton / metabolism
  • Spectrum Analysis / methods*
  • Time Factors

Substances

  • Carbon Isotopes
  • Carbon Dioxide
  • Methane