Stable soil organic matter (SOM) is an inherent property but also a requirement for soil ecosystem functioning. Microbial activity is a major driver of carbon turnover and SOM formation, but the extent to which stable SOM is formed is modulated by boundary conditions like redox state and mineral composition. Advancement in our understanding of SOM stabilization mechanisms is currently limited by the ability to directly assess the molecular composition of the mineral associated fraction and to determine the molecular structures of SOM, which are ultimately decisive factors for the carbon sequestration in soils. New analytical concepts and methods for chemical high resolution analyses are thus urgently needed. Structure-specific and surface-sensitive FT-ICR MS methods opens up an entirely new perspective to study microbial utilization of substrates and energy-use channels, map transformation pathways, decipher structure-energy relationships in complex SOM, explore the formation and stability of mineral-associated OM, and finally to understand SOM stabilization on a holistic level. To this end, we will employ 1) online-LC-FT-ICR MS to obtain physico-chemical information and LC-tandem MS methods to get meaningful compositional and structural information even for the most complex SOM, 2) functional group enumeration via isotope tagging to study the prevalence of structural moieties on a molecular level even when tandem MS fails to resolve compound classes, and 3) direct LDI-FT-ICR MS for the surface analysis of the organic matter after sorption to minerals. We will apply these tools to microbial microcosm experiments with different substrates and redox conditions, representing variable energy-use channels, to illuminate energy and matter dissipation on a molecular level.The overarching goal of this proposal is to promote the understanding of complex soil organic matter turnover from a bulk and molecular formula level to a structural level. This new level of SOM understanding, together with the project partners in the SPP SoilSystems will allow an integrative and comprehensive assessment and modeling of the energy-use channels and boundary condition limitations of OM turnover in soils. The proposal will contribute to the central Hypothesis of the SPP SoilSystems via long-term assessment of the energy-use channels and Gibbs energy dissipation of substrates during microcosm experiments, unmasking structural drivers of OM stabilization via the microbial pump, and deciphering the effect of redox and mineral boundary-conditions on the matter use and stabilization of carbon.

DFG Programme Priority Programmes

Subproject of SPP 2322:  Systems ecology of soils – Energy Discharge Modulated by Microbiome and Boundary Conditions (SoilSystems)

Co-Investigators Professor Dr. Robert Mikutta; Professor Dr.-Ing. Thorsten Reemtsma; Dr. Marion Schrumpf