Use of Stable Isotopes for Advanced Studies of Environmental and Soil Biogeochemical Processes *REVISED WORKLOAD*

Knowledge:

• Terminology, notations and analysis in stable isotope work
• Isotope fractionation; kinetic and equilibrium reactions; natural abundance and tracers; mixing models
• Stable isotope analysis of bulk soil, soil elements and gases
• Abundance and characteristics of elements/compounds that undergo isotopic fractionation in soil environment
• Understanding the cycling of Carbon and Nitrogen in soils (C and N-cycles; stocks; atmosphere)
• Methods to determine different C and N fractions
• Conceptual understanding of different soil organic matter pools
• Analytical methods to study soil processes in-situ in the rhizosphere and detritusphere
• Linking soil physical structure to plant and microbial activity

Skills:

• Apply correct scientific terms and definitions
• Apply and solve algebraic equations involving isotopic two- and three-end mixing models
• Identify and describe prerequisites for applications of stable isotope techniques in terrestrial settings (H, C, N, O, S)
• Identify and describe key processes that can be investigated by isotope techniques.
• Identify and apply methods to determine different C and N pools in soils
• Apply methods to determine C and N in differently stabilized soil fractions and calculate C and N distribution and stocks

Competences:

• Formulate proposals to identify and solve complex geographical problems and questions related to impacts on soil functionality and Earth systems (climate change, land use, management)
• Evaluate and discuss demands and prerequisites for accurate isotopic analysis in various sample materials
• Evaluate and discuss experimental and analytical approaches to study soils as a complex system
• Evaluate, discuss and explain scientific publications to fellow students and scientists