DOI: 10.1016/j.quascirev.2013.06.017
Scopus记录号: 2-s2.0-84880378677
论文题名: A new perspective on the δ13C signal preserved in speleothems using LC-IRMS analysis of bulk organic matter and compound specific stable isotope analysis
作者: Blyth A.J. ; Smith C.I. ; Drysdale R.N.
刊名: Quaternary Science Reviews
ISSN: 2773791
出版年: 2013
卷: 75 起始页码: 143
结束页码: 149
语种: 英语
英文关键词: δ13C
; LC-IRMS
; Organic carbon
; Soil
; Speleothem
; Vegetation
Scopus关键词: Compound-specific isotope analysis
; Compound-specific stable isotope analysis
; Inverse correlation
; LC-IRMS
; Microbial activities
; Organic geochemical techniques
; Speleothem
; Vegetation parameters
; Biogeochemistry
; Biological materials
; Calcite
; Forestry
; Isotopes
; Organic carbon
; Organic compounds
; Soils
; Vegetation
; Carbon dioxide
; calcite
; carbon dioxide
; carbon isotope
; deciduous forest
; isotopic analysis
; microbial activity
; organic carbon
; paleoenvironment
; peatland
; speleothem
; stable isotope
; woodland
; Scotland
; United Kingdom
英文摘要: The analysis of δ13C in speleothem calcite is established as a palaeoenvironmental proxy, but records can often be complex to interpret due to multiple controls on the signal. Here we present a novel palaeoenvironmental application of non-purgeable organic carbon (NPOC) δ13C analysis and compound-specific isotope analysis (CSIA) to speleothems, and compare the resultant signals to a conventional calcite δ13C record. By accessing the carbon pool held in molecular organic matter, we are able for the first time to produce stable isotope records complementary to the CO2-derived signal from the speleothem calcite, and begin to identify separate ecological and climatic controls. In this sample from north-west Scotland, the calcite δ13C record and the NPOC δ13C both show fluctuations at a period of increasing wetness and change from birch woodland to more open peatland, the NPOC signal having a strong correlation with biomarkers for vegetation change. We interpret an inverse correlation between the NPOC and CO2 δ13C signals as primarily driven by changes in soil conditions impacting upon microbial activity, with decreased activity leading to a reduction in 13C enrichment of the residual organic matter (the NPOC fraction), and an increase in δ13C in the CO2 pool (calcite) due to a decrease in respired 12C. This opens the way for the application of parallel analyses to distinguish between soil conditions and vegetation parameters as the primary control on a record, and highlights the advantage of combining both inorganic and organic geochemical techniques in the palaeoenvironmental interpretation of stable carbon isotopic records. © 2013 Elsevier Ltd. Citation statistics:
资源类型: 期刊论文
标识符: http://119.78.100.158/handle/2HF3EXSE/60549
Appears in Collections: 过去全球变化的重建
There are no files associated with this item.
作者单位: WA-OIGC, Department of Chemistry, Chemistry and Resources Precinct, Curtin University, GPO Box U1987, Perth, WA 6845, Australia; Department of Archaeology Environment and Community Planning, La Trobe University Melbourne, Vic. 3086, Australia; Department of Resource Management and Geography, Melbourne School of Land and Environment, University of Melbourne, Vic. 3010, Australia; EDYTEM, UMR CNRS 5204, Université de Savoie, 73376 Le Bourget du Lac Cedex, France
Recommended Citation:
Blyth A.J.,Smith C.I.,Drysdale R.N.. A new perspective on the δ13C signal preserved in speleothems using LC-IRMS analysis of bulk organic matter and compound specific stable isotope analysis[J]. Quaternary Science Reviews,2013-01-01,75