Using Pyrolysis Molecular Beam Mass Spectrometry to Characterize Soil Organic Carbon in Native Prairie Soils

Authors: MAGRINI, K - NREL, BOULDER, CO; Follett, Ronald; KIMBLE, J - NRCS, RETIRED; DAVIS, M - NREL, BOULDER, CO; Pruessner, Elizabeth

Submitted to: Soil Science
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 4/25/2007
Publication Date: 9/1/2007
Citation: Magrini, K., Follett, R.F., Kimble, J., Davis, M., Pruessner, E.G. 2007. Using Pyrolysis Molecular Beam Mass Spectrometry to Characterize Soil Organic Carbon in Native Prairie Soils. Soil Science. Vol. 172:659-672.

Interpretive Summary: This study characterizes soil organic carbon (SOC) with pyrolysis molecular beam mass spectrometry (py-MBMS) to determine correlations between the mass spectra and associated soil characterization data. Soil carbon chemistry and forms of SOC, including soil microbial biomass C, particulate organic matter C, and mineral associated C were assessed by multivariate statistical analyses to discover existing correlations and the potential to develope estimative models. Soil samples were well-characterized native prairie soils from the western U.S. Corn Belt and Great Plains located within 8 states (CO, NE, IA, ND, MT, TX, MO, and MN). Estimative correlations were found for samples collected across this large geographic region (at or greater than 0.90). SOC calendar age derived from radiocarbon-14 dating could be estimated for ustollic soils from MT, NE, and CO. These soils also contained deeper and younger aeolian layers, whose ages were correctly estimated with this technique.

Technical Abstract: The objective of this study was to characterize soil organic carbon (SOC) with pyrolysis molecular beam mass spectrometry (py-MBMS) and then to determine correlations between the mass spectra and associated soil characterization data. Both soil carbon chemistry and the organic forms in which SOC is sequestered (soil microbial biomass (SMBC), particulate organic matter carbon (POM C), and mineral associated carbon (Cmin C)) were assessed by multivariate statistical analyses to discover existing correlations and if they could be developed into estimative models. The sample set consisted of well-characterized soils collected from native prairie sites in the western U.S. Corn Belt and Great Plains: eleven sites located within eight mid-western states (CO, NE, IA, ND, MT, TX, MO, and MN). Sample characterization parameters included site, depth, % SOC, POM C, Cmin C, SMBC, and SOC calendar age (determined from 14C age). Estimative correlations were found for samples collected across this large geographic region (at or greater than 0.90) for SOC, POM C, Cmin C, and SMBC. SOC calendar age derived from radiocarbon-14 dating could be estimated for ustollic soils from MT, NE, and CO. These soils also contained deeper and younger aeolian layers, whose ages were correctly estimated with this technique. Py-MBMS analysis additionally showed that soils developed from water-sorted sediments on a tilled-floor lake plain (lacustrine soils) were significantly different from the other samples.