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Journal of the International Association of Wildland Fire
RESEARCH ARTICLE

Long-term relations among fire, fuel, and climate in the north-western US based on lake-sediment studies

Cathy Whitlock A E , Jennifer Marlon B , Christy Briles B , Andrea Brunelle C , Colin Long D and Patrick Bartlein B
+ Author Affiliations
- Author Affiliations

A Department of Earth Sciences, Montana State University, Bozeman MT 59717, USA.

B Department of Geography, University of Oregon, Eugene, OR 97403, USA.

C Department of Geography, University of Utah, Salt Lake City, UT 84112, USA.

D Department of Geography and Urban Planning, University of Wisconsin Oshkosh, Oshkosh, WI 54901, USA.

E Corresponding author. Email: whitlock@montana.edu

International Journal of Wildland Fire 17(1) 72-83 https://doi.org/10.1071/WF07025
Submitted: 11 November 2006  Accepted: 15 November 2007   Published: 18 February 2008

Abstract

Pollen and high-resolution charcoal records from the north-western USA provide an opportunity to examine the linkages among fire, climate, and fuels on multiple temporal and spatial scales. The data suggest that general charcoal levels were low in the late-glacial period and increased steadily through the last 11 000 years with increasing fuel biomass. At local scales, fire occurrence is governed by the interaction of site controls, including vegetation, local climate and fire weather, and topography. At subregional scales, patterns in the long term fire-episode frequency data are apparent: The Coast Range had relatively few fires in the Holocene, whereas the Klamath–Siskiyou region experienced frequent fire episodes. Fire regimes in the northern Rocky Mountains have been strongly governed by millennial- and centennial-scale climate variability and regional differences in summer moisture. At regional scales, sites in present-day summer-dry areas show a period of protracted high fire activity within the early Holocene that is attributed to intensified summer drought in the summer-dry region. Sites in summer-wet areas show the opposite pattern, that fire was lower in frequency than present in the early Holocene as result of strengthened monsoonal circulation then. Higher fire-episode frequency at many sites in the last 2000 years is attributed to greater drought during the Medieval Climate Anomaly and possibly anthropogenic burning. The association between drought, increased fire occurrence, and available fuels evident on several time scales suggests that long-term fire history patterns should be considered in current assessments of historical fire regimes and fuel conditions.

Additional keywords: charcoal data, fire history, Holocene, pollen data, western US.


Acknowledgements

Research described in the present paper was supported by National Science Foundation grants (ATM-0117160; ATM-9816317; SBR-9616951) and USDA Forest Service Cooperative Agreements from the Pacific South-west Research Station and the Pacific North-west Research Station. The paper benefited from comments by Scott Anderson and an anonymous reviewer.


Contributions: Whitlock, Marlon and Bartlein contributed to the overall conceptual design of the study. Whitlock crafted the manuscript; Marlon was responsible for data standardisation and regional comparisons; Marlon and Bartlein described methods and designed Fig. 6; Briles prepared Figs 2–5; and Brunelle, Briles, Long, and Whitlock contributed subregional histories.


References


Agee JK (1993) ‘Fire ecology of Pacific North-west forests.’ (Island Press: Washington, DC)

Alley RB, Meese DA, Shuman CA, Gow AJ , Taylor KC (1993) Abrupt accumulation increase at the Younger Dryas termination in the GISP2 ice core. Nature  362, 527–529.
Crossref | GoogleScholarGoogle Scholar | Barrett SW, Arno SF, Menakis JP (1997) Fire episodes in the inland North-west (1540–1940) based on fire history data. USDA Forest Service, General Technical Report INT-GTR-370. Rocky Mountain Research Station. (Ogden, UT)

Bartlein PJ, Hostetler SW, Shafer SL, Holman JO , Soloman AM (2008) Temporal and spatial structure in a daily wildfire-start data set from the western United States (1986–96). International Journal of Wildland Fire  17, 8–17.
Crossref | GoogleScholarGoogle Scholar | Franklin JF, Dyrness CT (1988) Natural vegetation of Oregon and Washington. USDA Forest Service, General Technical Report PNW-8. (Portland, OR)

Gavin DG, Hu FS, Lertzman K , Corbett P (2006) Weak climatic control of stand-scale fire history during the late Holocene. Ecology  87, 1722–1732.
Crossref | GoogleScholarGoogle Scholar | PubMed | Impara PC (1997) Spatial and temporal patterns of fire in the forests of the Central Oregon Coast Range. PhD Dissertation, Oregon State University, Corvallis, OR.

IPCC (2007) ‘Climate Change 2007: the Physical Science Basis.’ Contribution of Working Group I to the Fourth Assessment Report of the Intergovernmental Panel on Climate Change. (Eds S Solomon, D Qin, M Manning, Z Chen, M Marquis, KB Averyt, M Tignor, HL Miller) (Cambridge University Press: Cambridge, UK)

Juday GP (1977) The location, composition, and structure of old-growth forest of the Oregon Coast Range. PhD Dissertation, Oregon State University, Corvallis, OR.

Long CJ , Whitlock C (2002) Fire and vegetation history from the coastal rainforest of the western Oregon Coast Range. Quaternary Research  58, 215–225.
Crossref | GoogleScholarGoogle Scholar | Millspaugh SH, Whitlock C, Bartlein PJ (2004) Post-glacial fire, vegetation, and climate history of the Yellowstone-Lamar and Central Plateau provinces, Yellowstone National Park. In ‘After the fires: the ecology of change in Yellowstone National Park’. (Ed. L Wallace) pp. 10–28. (Yale University Press: New Haven, CT)

Minckley TF, Whitlock C , Bartlein PJ (2007) Vegetation, fire, and climate history of the Warner Mountains, northern Great Basin, USA. Quaternary Science Reviews  26, 2167–2184.
Crossref | GoogleScholarGoogle Scholar | Pederson G, Whitlock C, Watson E, Luckman B, Graumlich L (2007) Paleoperspectives on climate and ecosystem change. In ‘Sustaining Rocky Mountain landscapes’. (Eds T Prato, D Fagre) pp. 151–170. (RFF Press: Washington, DC)

Peters ME , Higuera PE (2007) Quantifying the source area of macroscopic charcoal with a particle dispersal model. Quaternary Research  67, 304–310.
Crossref | GoogleScholarGoogle Scholar | Sawyer JO, Thornburgh DA (1988) Montane and subalpine vegetation of the Klamath Mountains. In ‘Terrestrial vegetation of California, special publication no. 9’. (Eds MG Barbour, J Major) pp. 699–732. (California Native Plant Society: Berkeley, CA)

Skinner CN, Chang C (1996) Fire regimes, past and present. In ‘Sierra Nevada Ecosystem Project: Final Report to Congress, Vol. II, Assessments and Scientific Basis for Management Options’. pp. 1041–1069. (Centers for Water and Wildland Resources, University of California: Davis, CA)

Stuiver M, Reimer PJ , Braziunas TF (1998) High-precision radiocarbon age calibration for terrestrial and marine samples. Radiocarbon  40, 1127–1151.
Teensma P, Rienstra J, Yeiter M (1991) Preliminary reconstruction and analysis of change in forest stand age classes of the Oregon Coast Range from 1850 to 1940. USDI Bureau of Land Management, Technical Note T/N OR-9. (Portland, OR)

Trouet V, Taylor AH, Carleton AM , Skinner CN (2006) Fire–climate interactions in forests of the American Pacific coast. Geophysical Research Letters  33, L18704.
Crossref | GoogleScholarGoogle Scholar | Vale TR (Ed.) (2001) ‘Fire, native peoples, and the natural landscape.’ (Island Press: Washington, DC)

Vasek FC, Thorne RF (1988) Transmontane coniferous vegetation. In ‘Terrestrial Vegetation of California, Special Publication No. 9.’ (Eds MG Barbour, J Major) pp. 797–832. (California Native Plant Society: Berkeley, CA)

West GJ (1989) Late Pleistocene/Holocene vegetation and climate. In ‘Prehistory of the Sacramento River Canyon, Shasta County, California’. (Eds ME Basgall, WR Hildebrandt) pp. 36–55. (Center for Archaeological Research: Davis, CA)

Westerling AL, Hidalgo HG, Cayan DR , Swetnam TW (2006) Warming and earlier spring increases western US forest wildfire activity. Science  313, 940–943.
Crossref | GoogleScholarGoogle Scholar | PubMed | Whitlock C, Bartlein PJ (2004) Holocene fire activity as a record of past environmental change. In ‘The Quaternary period in the United States. Developments in Quaternary science’. (Eds AR Gillespie, SC Porter, BF Atwater) pp. 479–490. (Elsevier: Amsterdam)

Whitlock C , Millspaugh SH (1996) Testing the assumptions of fire-history studies: an examination of modern charcoal accumulation in Yellowstone National Park, USA. The Holocene  6, 7–15.
Crossref | GoogleScholarGoogle Scholar |

Whitlock C, Shafer S , Marlon J (2003) The role of climate and vegetation change in shaping past and future fire regimes in the north-western US and the implications for ecosystem management. Forest Ecology and Management  178, 5–21.
Crossref | GoogleScholarGoogle Scholar |

Worona MA , Whitlock C (1995) Late-Quaternary vegetation and climate history near Little Lake, central Coast Range, Oregon. Geological Society of America Bulletin  107, 867–876.
Crossref | GoogleScholarGoogle Scholar |

Zdanowicz CM, Zielinski GA , Germani MS (1999) Mount Mazama eruption: calendrical age verified and atmospheric impact assessed. Geology  27, 621–624.
Crossref | GoogleScholarGoogle Scholar |