Carbon stocks and sequestration potentials of agricultural soils in the federal state of Baden-Wurttemberg, SW Germany

Soil organic carbon (SOC) inventories are important tools for studying the effects of land‐use and climate change and evaluating climate‐change policies. A detailed inventory of SOC in the agricultural soils of the federal state of Baden‐Württemberg was therefore prepared based on the highest‐resolu...

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Bibliographic Details
Published in:Journal of plant nutrition and soil science 2005-04, Vol.168 (2), p.202-211
Main Author: Neufeldt, H
Format: Article
Language:English
Subjects:
agricultural soils
Agronomy. Soil science and plant productions
Biological and medical sciences
C sequestration
carbon sequestration
ecological restoration
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
GHG mitigation
IPCC inventory
no-tillage
no-tillage agriculture
organic soils
peatland restoration
peatlands
soil organic carbon stocks
soil organic matter
Soil science
Soil-plant relationships. Soil fertility
Soil-plant relationships. Soil fertility. Fertilization. Amendments
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Summary:Soil organic carbon (SOC) inventories are important tools for studying the effects of land‐use and climate change and evaluating climate‐change policies. A detailed inventory of SOC in the agricultural soils of the federal state of Baden‐Württemberg was therefore prepared based on the highest‐resolution geo‐referenced soil, land‐use, and climate data (BÜK200 inventory). In order to estimate the quality of different approaches, C inventories of the region were also prepared based on data from the National Inventory Report (UBA, 2003) and by applying the IPCC (1997) method to the two data sets. Finally, the BÜK200 inventory was used to estimate potentials of no‐tillage agriculture (NT) and peatland restoration to contribute to C sequestration and greenhouse‐gas (GHG)‐emission mitigation since both measures are discussed in this context. Scenario assumptions were change to NT on 40% of the cropland and restoration of 50% of cultivated peatlands within 20 years. On average, grasslands contained 9.5 kg C m–2 to 0.3 m depth as compared to only 6.0 kg C m–2 under cropland, indicating strong land‐use effects. The SOC content depended strongly on waterlogging and elevation, thus reflecting reduced C mineralization under aquic moisture regimes and low temperatures. Comparison of the BÜK200 inventory with the approach used for UBA (2003) showed high inconsistencies due to map resolution and SOC contents, whereas the IPCC method led to fairly good agreements. Results on the simulated effects of NT and peatland restoration suggested that 5%–14% of total agricultural GHG emissions could be abated with NT whereas peat restoration appeared to have a minor mitigation potential (0.2%–2.7%) because the total area of cultivated organic soils was too small to have larger impact. Kohlenstoffvorräte und ‐sequestrierungspotenziale landwirtschaftlicher Böden in Baden‐Württemberg Kohlenstoffinventare sind ein wichtiges Instrument, um die Einflüsse von Landnutzung und Klimawandel zu studieren und Klimaschutzpolitiken zu beurteilen. Daher wurde ein detailliertes C‐Inventar landwirtschaftlicher Böden Baden‐Württembergs auf der Basis georeferenzierter Boden‐, Landnutzungs‐ und Klimadaten mit der höchsten verfügbaren Auflösung erstellt (BÜK200‐Inventar). Um die Qualität verschiedener Inventaransätze zu beurteilen, wurden zusätzlich C‐Inventare der Region auf der Basis der Daten des Nationalen Inventarberichts (UBA, 2003) sowie durch Verwendung der IPCC‐Methode (IPCC, 1997) erstellt. Sch
ISSN:1436-8730
1522-2624
DOI:10.1002/jpln.200421441