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RESEARCH ARTICLE
Contents Vol 17(1)

Paired charcoal and tree-ring records of high-frequency Holocene fire from two New Mexico bog sites

Craig D. Allen A F , R. Scott Anderson B , Renata B. Jass C , Jaime L. Toney D and Christopher H. Baisan E
+ Author Affiliations
- Author Affiliations

A US Geological Survey, Jemez Mountains Field Station, Los Alamos, NM 87544, USA.

B Center for Environmental Sciences and Education, and Quaternary Sciences Program, Northern Arizona University, Flagstaff, AZ 86011, USA.

C 4014A Lewis Lane, Austin, TX 78730, USA.

D Brown University, Geological Sciences, Providence, RI 02912, USA.

E Laboratory of Tree-Ring Research, University of Arizona, Tucson, AZ 85721, USA.

F Corresponding author. Email: craig_allen@usgs.gov

International Journal of Wildland Fire 17(1) 115-130 https://doi.org/10.1071/WF07165
Submitted: 7 May 2007  Accepted: 15 November 2007   Published: 15 February 2008

Abstract

Two primary methods for reconstructing paleofire occurrence include dendrochronological dating of fire scars and stand ages from live or dead trees (extending back centuries into the past) and sedimentary records of charcoal particles from lakes and bogs, providing perspectives on fire history that can extend back for many thousands of years. Studies using both proxies have become more common in regions where lakes are present and fire frequencies are low, but are rare where high-frequency surface fires dominate and sedimentary deposits are primarily bogs and wetlands. Here we investigate sedimentary and fire-scar records of fire in two small watersheds in northern New Mexico, in settings recently characterised by relatively high-frequency fire where bogs and wetlands (Chihuahueños Bog and Alamo Bog) are more common than lakes. Our research demonstrates that: (1) essential features of the sedimentary charcoal record can be reproduced between multiple cores within a bog deposit; (2) evidence from both fire-scarred trees and charcoal deposits documents an anomalous lack of fire since ~1900, compared with the remainder of the Holocene; (3) sedimentary charcoal records probably underestimate the recurrence of fire events at these high-frequency fire sites; and (4) the sedimentary records from these bogs are complicated by factors such as burning and oxidation of these organic deposits, diversity of vegetation patterns within watersheds, and potential bioturbation by ungulates. We consider a suite of particular challenges in developing and interpreting fire histories from bog and wetland settings in the Southwest. The identification of these issues and constraints with interpretation of sedimentary charcoal fire records does not diminish their essential utility in assessing millennial-scale patterns of fire activity in this dry part of North America.

Additional keywords: Alamo Bog, CHAPS, Chihuahueños Bog, fire scars, Jemez Mountains, replicated charcoal records.


Acknowledgements

We thank Kay Beeley of Bandelier National Monument for fieldwork and graphics support, Rebecca Oertel of the USGS Jemez Mountains Field Station and Victor Leshyk for graphics support, Kiyomi Morino of the University of Arizona Laboratory of Tree-Ring Research for fieldwork and dating of initial fire-scar samples at Alamo Bog, Richard Ku for 210Pb and 137Cs analyses, Tom Swetnam of the Tree-Ring Laboratory for overall support for this work, and Chris Jass, Dave Snyderman, and John Hogan for fieldwork. Permission for field sampling at Chihuahueños Bog was provided by the Coyote Ranger District of the Santa Fe National Forest, and at Alamo Bog in 1996 by the Baca Land and Cattle Co. and after 2000 by the Valles Caldera National Preserve. Funding support was provided by the Global Change Research Program of the USGS, Biological Resources Discipline, through the Western Mountain Initiative. Northern Arizona University Laboratory of Paleoecology Contribution 101.


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