Project Details
FOR 918: Carbon Flow on Belowground Food Webs Assessed by Isotope Tracers
Subject Area
Agriculture, Forestry and Veterinary Medicine
Biology
Medicine
Biology
Medicine
Term
from 2008 to 2018
Project identifier
Deutsche Forschungsgemeinschaft (DFG) - Project number 40526089
The overall goal of the Research Unit is to understand the flow of carbon through biotic compartments within terrestrial ecosystems. Field experiments will be performed at an agricultural site located at Darmstadt with permanent C3 crop. The 13C signal will be introduced by cultivating the C4 plant Zea mays either as corn or fodder maize. Corn maize will introduce above- and belowground plant carbon (i.e. labile and recalcitrant resources), whereas with fodder maize carbon predominantly derives from rhizodeposits (i.e. labile resources). Carbon assimilation and partitioning in the major energy pathways based on roots, bacteria or fungi will be assessed, taking into consideration the factors as resource quality and availability as well as food web complexity. The Research Unit will apply isotope tracer methods for identification of key biota and quantification of the carbon flux in the trophic cascade. This includes the incorporation of 13C label into biomarkers such as lipids and nucleic acids. In addition, attention will be given to the overall carbon balance, i.e. turnover and losses in the soil system. Experimentally assessed biomass-fluxes (respiration and assimilation rates) and allometric functional responses (predator-prey interactions) within food web biota will complete the picture. The present study is unique in its aim to
(1) achieve a high resolution even at low trophic levels such as microorganisms and microfauna,
(2) link microbial and faunal food webs and
(3) use the trophic shift of stable isotopes in biomarker molecules to gain quantitative input data for modelling. This will result in the implementation of dynamic food web models based on empirical figures.
(1) achieve a high resolution even at low trophic levels such as microorganisms and microfauna,
(2) link microbial and faunal food webs and
(3) use the trophic shift of stable isotopes in biomarker molecules to gain quantitative input data for modelling. This will result in the implementation of dynamic food web models based on empirical figures.
DFG Programme
Research Units
Projects
- Carbon flux through the soil animal food web: meso- and macrofauna (Applicant Scheu, Stefan )
- Coordination (Applicants Rueß, Liliane ; Scheu, Stefan )
- Effects of resource quality and availability on soil microorganisms and their carbon assimilation (Applicant Kandeler, Ellen )
- Exploration and modeling of the transport of mobile organic substances in the topsoil-subsoil-aquifer continuum (Applicant Totsche, Kai Uwe )
- Identification of keystone prokaryotic food web members and links in belowground carbon turnover - SP MicLink (Applicant Lüders, Tillmann )
- Interactions between root C, microbial activity and turnover, and food web complexity (Applicant Kuzyakov, Yakov )
- Modelling quantitative carbon flows in soil food webs (Applicant Brose, Ulrich )
- Nematodes as link between microbial and faunal food web (Applicant Rueß, Liliane )
- Soil fungi as link between plant derived carbon and soil food webs (FunLink) (Applicant Wubet, Tesfaye )
- The bacterial energy channel: Protozoa-bacteria interrelationships as affected by root vicinity, organic matter and soil depth (Applicant Bonkowski, Michael )
Spokesperson
Professorin Dr. Liliane Rueß