Sage Journals: Discover world-class research

Abstract

The past decade has seen a rapid increase in interest in the biogeochemical record preserved in peat, particularly as it relates to carbon dynamics and environmental change. Importantly, recent studies show that carbon dynamics, that is, organic matter decomposition, can influence the record of atmospherically derived elements such as halogens and mercury. Most commonly, bulk density, light transmission, or carbon/nitrogen (C/N) ratios are used as a proxy to qualitatively infer the degree of decomposition in peat, but do these three proxies reflect the same patterns? Furthermore, how do each of these proxies relate to other geochemical data? To address these questions, we analyzed bulk density, light transmission, and C/N ratios, as well as multielement geochemistry (wavelength-dispersive x-ray fluorescence (WD-XRF)), in three hummock cores (70 cm in length, c. 500 years) from an ombrotrophic Swedish bog. To compare the proxies, we applied principal component analysis (PCA) to identify how the proxies relate to and interact with the geochemical matrix. This was coupled with changepoint modeling to identify and compare statistically significant changes for each proxy. Our results show differences between the proxies within and between cores, indicating each responds to a different part of the decomposition process. This is supported by the PCA, where the three proxies fall on different principal components. Changepoint analysis also showed that the inferred number of changepoints and their depths vary for each proxy and core. This suggests that decomposition is not fully captured by any one of these commonly used proxies, and thus, more than one proxy should be included.

Keywords

bulk density C/N ratio decomposition humification light transmission peat

Get full access to this article

View all access options for this article.

References

Aaby

(1976) Cyclic climatic variations in climate over past 5,500 yr reflected in raised bogs. Nature 263: 281–284.

Barber

Maddy

Rose

. (2000) Replicated proxy-climate signals over the last 2000 yr from two distant UK peat bogs: New evidence for regional palaeoclimate teleconnections. Quaternary Science Reviews 19: 481–487.

Biester

Hermanns

Martínez-Cortizas

(2012) The influence of organic matter decay on the distribution of major and trace elements in ombrotrophic mires – A case study from the Harz Mountains. Geochimica et Cosmochimica Acta 84: 126–136.

Biester

Martínez-Cortizas

Birkenstock

. (2003) Effect of peat decomposition and mass loss on historic mercury records in peat bogs from Patagonia. Environmental Science & Technology 37: 32–39.

Bindler

Klaminder

(2006) Reply to comment by William Shotyk on ‘Does within-bog spatial variability of mercury and lead constrain reconstructions of absolute deposition rates from single peat records? The example of Store Mosse, Sweden’. Global Biogeochemical Cycles 20. DOI: 10.1029/2005GB002658.

Bindler

Klarqvist

Klaminder

. (2004) Does within-bog spatial variability of mercury and lead constrain reconstructions of absolute deposition rates from single peat records? The example of Store Mosse, Sweden. Global Biogeochemical Cycles 18. DOI: 10.1029/2004GB002270.

Blackford

Chambers

(1993) Determining the degree of peat decomposition for peat based palaeoclimatic studies. International Peat Journal 5: 7–24.

Borgmark

(2005) Holocene climate variability and periodicities in south-central Sweden, as interpreted from peat humification analysis. The Holocene 15: 387–395.

Borgmark

Schoning

(2006) A comparative study of peat proxies from two eastern central Swedish bogs and their relation to meteorological data. Journal of Quaternary Science 21: 109–114.

10.

Caseldine

Baker

Charman

. (2000) A comparative study of optical properties of NaOH peat extracts: Implications for humification studies. The Holocene 10: 649–658.

11.

Chambers

Beilman

(2011) Methods for determining peat humification and for quantifying peat bulk density, organic matter and carbon content for palaeostudies of climate and peatland carbon dynamics. Mires & Peat 7: Article 7.

12.

Chambers

Barber

Maddy

. (1997) A 5500-year proxy-climate and vegetation record from blanket mire at Talla Moss, Borders, Scotland. The Holocene 7: 391–399.

13.

Chambers

Booth

De Vleeschouwer

. (2012) Development and refinement of proxy-climate indicators from peats. Quaternary International 268: 21–33.

14.

Clymo

(1965) Experiments on breakdown of Sphagnum in 2 bogs. Journal of Ecology 53: 747–758.

15.

Clymo

(1984) The limits to peat bog growth. Philosophical Transactions of the Royal Society of London, Series B 303: 605–654.

16.

De Vleeschouwer

Renson

Claeys

. (2011) Quantitative WD-XRF calibration for small ceramic samples and their source material. Geoarchaeology 26: 440–450.

17.

Fenton

JHC

(1982) The formation of vertical edges on Antarctic moss peat banks. Arctic and Alpine Research 14: 21–26.

18.

Franzén

(2006) Increased decomposition of subsurface peat in Swedish raised bogs: Are temperate peatlands still net sinks of carbon? Mires & Peat 1: Article 3.

19.

Gallagher

Bodin

Sambridge

. (2011) Inference of abrupt changes in noisy geochemical records using transdimensional changepoint models. Earth and Planetary Science Letters 311: 182–194.

20.

Givelet

Le Roux

Cheburkin

. (2004) Suggested protocol for collecting, handling and preparing peat cores and peat samples for physical, chemical, mineralogical and isotopic analyses. Journal of Environmental Monitoring 6: 481–492.

21.

Johnson

Damman

AWH

Malmer

(1990) Sphagnum macrostructure as an indicator of decay and compaction in peat cores from an ombrotrophic south Swedish peat-bog. Journal of Ecology 78: 633–647.

22.

Jolliffe

(2002) Principal Component Analysis. New York: Springer-Verlag.

23.

Kuhry

Vitt

(1996) Fossil carbon/nitrogen ratios as a measure of peat decomposition. Ecology 77: 271–275.

24.

Kylander

Bindler

Martínez-Cortizas

. (2013) A novel geochemical approach to paleorecords of dust deposition and effective humidity: 8500 years of peat accumulation at Store Mosse (‘Big Bog’), Sweden. Quaternary Science Reviews 69: 69–82.

25.

Kylander

Muller

Wust

RAJ

. (2007) Rare earth element and Pb isotope variations in a 52 kyr peat core from Lynch’s Crater (NE Queensland, Australia): Proxy development and application to paleoclimate in the Southern Hemisphere. Geochimica et Cosmochimica Acta 71: 942–960.

26.

Malmer

Holm

(1984) Variation in the C/N-quotient of peat in relation to decomposition rate and age determination with ²¹⁰Pb. Oikos 43: 171–182.

27.

Malmer

Wallen

(1993) Accumulation and release of organic-matter in ombrotrophic bog hummocks – Processes and regional variation. Ecography 16: 193–211.

28.

Malmer

Wallen

(2004) Input rates, decay losses and accumulation rates of carbon in bogs during the last millennium: Internal processes and environmental changes. The Holocene 14: 111–117.

29.

Malmer

Svensson

Wallen

(1997) Mass balance and nitrogen accumulation in hummocks on a South Swedish bog during the late Holocene. Ecography 20: 535–549.

30.

Martínez-Cortizas

Varela

Bindler

. (2012) Reconstructing historical Pb and Hg pollution in NW Spain using multiple cores from the Chao de Lamoso bog (Xistral Mountains). Geochimica et Cosmochimica Acta 82: 68–78.

31.

Menot

Burns

(2001) Carbon isotopes in ombrogenic peat bog plants as climatic indicators: Calibration from an altitudinal transect in Switzerland. Organic Geochemistry 32: 233–245.

32.

Nott

Xie

Avsejs

. (2000) n-Alkane distributions in ombrotrophic mires as indicators of vegetation change related to climatic variation. Organic Geochemistry 31: 231–235.

33.

Overbeck

(1947) Studien zur hochmoorentwicklung in niedersachsen und die bestimmung der humifizierung bei stratigraphisch-pollen analytischen mooruntersuchungen. Planta 35: 1–56.

34.

Roos-Barraclough

van der Knaap

van Leeuwen

JFN

. (2004) A late-glacial and Holocene record of climatic change from a Swiss peat humification profile. The Holocene 14: 7–19.

35.

Shotyk

Steinmann

(1994) Pore-water indicators of rainwater-dominated versus groundwater-dominated peat bog profiles (Jura Mountains, Switzerland). Chemical Geology 116: 137–146.

36.

Shotyk

Weiss

Kramers

. (2001) Geochemistry of the peat bog at Etang de la Gruere, Jura Mountains, Switzerland, and its record of atmospheric Pb and lithogenic trace metals (Sc, Ti, Y, Zr, and REE) since 12,370 C-14 yr BP. Geochimica et Cosmochimica Acta 65: 2337–2360.

37.

Svensson

(1988a) Bog development and environmental-conditions as shown by the stratigraphy of Store Mosse mire in southern Sweden. Boreas 17: 89–111.

38.

Svensson

(1988b) Fossil plant-communities and regeneration patterns on a raised bog in South Sweden. Journal of Ecology 76: 41–59.

39.

Wardenaar

ECP

(1987) A new hand tool for cutting peat profiles. Canadian Journal of Botany 65: 1772–1773.

40.

Weiss

Shotyk

Cheburkin

. (1997) Atmospheric lead deposition from 12,400 to Ca. 2,000 yrs BP in a peat bog profile, Jura Mountains, Switzerland. Water, Air, and Soil Pollution 100: 311–324.

41.

Yeloff

Mauquoy

(2006) The influence of vegetation composition on peat humification: Implications for palaeoclimatic studies. Boreas 35: 662–673.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.16 MB

Evaluating paleoproxies for peat decomposition and their relationship to peat geochemistry

Abstract

Keywords

Get full access to this article

References

Supplementary Material