Vote for your favorite mineral in #MinCup25! - Dioptase vs. Wavellite
It's a green, green world for kiwi #wavellite vs desert emerald #dioptase.

Log In Register

Language:

About Support Us Photos Discussions Search Learn More

Quick Links : The Mindat Manual The Rock H. Currier Digital Library Mindat Newsletter [Free Download]

Home Page About Mindat The Mindat Manual History of Mindat Copyright Status Who We Are Contact Us Advertise on Mindat

Donate to Mindat Corporate Sponsorship Sponsor a Page Sponsored Pages Mindat Advertisers Advertise on Mindat

Learning Center What is a mineral?The most common minerals on earth Information for Educators Mindat Articles The Elements The Rock H. Currier Digital Library Geologic Time

Minerals by Properties Minerals by Chemistry Advanced Locality Search Random Mineral Random Locality Search by minID Localities Near Me Search Articles Search Glossary More Search Options

The Mindat Manual Add a New Photo Rate Photos Locality Edit Report Coordinate Completion Report Add Glossary Item

Mining Companies Statistics Users Mineral Museums Clubs & Organizations Mineral Shows & Events The Mindat Directory Device Settings The Mineral Quiz

Photo Search Photo Galleries Search by Color New Photos Today New Photos Yesterday Members' Photo Galleries Past Photo of the Day Gallery Photography

Burn, C R (1998) The response (1958-1997) of permafrost and near-surface ground temperatures to forest fire, Takhini River valley, southern Yukon Territory. Canadian Journal of Earth Sciences, 35 (2) 184-199 doi:10.1139/e97-105

Library Home Bookshelves View by Type Using Search

Books Catalogs/Sales Lists Journals Reports Thesis/Dissertation

Search for Books Search for Journals Manage Subjects Statistics Books without DDC/LCC Top Unstructured Orphaned Articles

Bookshelves (DDC layout)Bookshelves (LCC layout)Latest Books

Search inside 'Canadian Journal of ...' only

- Only viewable:

Reference Type	Journal (article/letter/editorial)
Title	The response (1958-1997) of permafrost and near-surface ground temperatures to forest fire, Takhini River valley, southern Yukon Territory
Journal	Canadian Journal of Earth Sciences
Authors	Burn, C R		Author
Year	1998 (February 1)	Volume	35
Issue	2
Publisher	Canadian Science Publishing
DOI	doi:10.1139/e97-105Search in ResearchGate
	Generate Citation Formats
Mindat Ref. ID	483075	Long-form Identifier	mindat:1:5:483075:1
GUID	0
Full Reference	Burn, C R (1998) The response (1958-1997) of permafrost and near-surface ground temperatures to forest fire, Takhini River valley, southern Yukon Territory. Canadian Journal of Earth Sciences, 35 (2) 184-199 doi:10.1139/e97-105
Plain Text	Burn, C R (1998) The response (1958-1997) of permafrost and near-surface ground temperatures to forest fire, Takhini River valley, southern Yukon Territory. Canadian Journal of Earth Sciences, 35 (2) 184-199 doi:10.1139/e97-105
In	(1998, February) Canadian Journal of Earth Sciences Vol. 35 (2) Canadian Science Publishing
Abstract/Notes	Forest fires in permafrost areas often modify ground surface conditions, causing deepening of the active layer and thawing of near-surface permafrost. Takhini River valley lies in the discontinuous permafrost zone of southern Yukon Territory. The valley floor is covered by glaciolacustrine deposits, which are locally ice rich. In 1958 extensive forest fires burned most of the vegetation and the soil organic horizon in the valley, but, 50 km west of Whitehorse, 1 km2 of spruce forest adjacent to the Alaska Highway escaped burning. Permafrost beneath this stand of trees is in equilibrium with surface conditions: the active layer is 1.4 m thick, the base of permafrost is at 18.5 m, the annual mean temperature at the top of permafrost (1.5 m) is -0.8°C, and the temperature gradient in permafrost is constant with depth. At burned sites nearby there has been little regeneration of forest vegetation since the fire, and long-term permafrost degradation has occurred. At one burned site, the permafrost table is more than 3.75 m below the ground surface, the mean annual ground temperature is -0.2°C or warmer throughout the profile, the annual mean temperature at 1.5 m is 0.1°C, and permafrost is thawing from top and bottom. A simplified analytical model for thawing of permafrost indicates that over a millennium will be required to degrade permafrost completely at this site, if thawing proceeds from the top down. The result demonstrates the persistence of ice-rich permafrost a few metres below the ground surface, even at sites near the southern margin of permafrost in Canada.

See Also

These are possibly similar items as determined by title/reference text matching only.

	Karunaratne, K C, Burn, C R (2004) Relations between air and surface temperature in discontinuous permafrost terrain near Mayo, Yukon Territory. Canadian Journal of Earth Sciences, 41 (12) 1437-1451 doi:10.1139/e04-082
	Burn, C. R., Michel, F. A. (1988) Evidence for recent temperature-induced water migration into permafrost from the tritium content of ground ice near Mayo, Yukon Territory, Canada. Canadian Journal of Earth Sciences, 25 (6) 909-915 doi:10.1139/e88-087
	*Burn, C R (2000) The thermal regime of a retrogressive thaw slump near Mayo, Yukon Territory. Canadian Journal of Earth Sciences, 37 (7) 967-981 doi:10.1139/e00-017*
	*Fraser, T. A., Burn, C. R. (1997) On the nature and origin of "muck" deposits in the Klondike area, Yukon Territory. Canadian Journal of Earth Sciences, 34 (10) 1333-1344 doi:10.1139/e17-106*
	*Kotler, E, Burn, C R (2000) Cryostratigraphy of the Klondike "muck" deposits, west-central Yukon Territory. Canadian Journal of Earth Sciences, 37 (6) 849-861 doi:10.1139/e00-013*
	Burn, C. R. (1994) Permafrost, tectonics, and past and future regional climate change, Yukon and adjacent Northwest Territories. Canadian Journal of Earth Sciences, 31 (1) 182-191 doi:10.1139/e94-015
	Burn, C. R. (1991) Permafrost and ground ice conditions reported during recent geotechnical investigations in the Mayo district, Yukon territory. Permafrost and Periglacial Processes, 2 (3). 259-268 doi:10.1002/ppp.3430020310
	*Nickling, W. G. (1978) Eolian sediment transport during dust storms: Slims River Valley, Yukon Territory. Canadian Journal of Earth Sciences, 15 (7) 1069-1084 doi:10.1139/e78-114*
	*Burn, C. R. (1988) The development of near-surface ground ice during the Holocene at sites near Mayo, Yukon Territory, Canada. Journal of Quaternary Science, 3 (1). 31-38 doi:10.1002/jqs.3390030106*
	Kokelj, S V, Burn, C R (2005) Geochemistry of the active layer and near-surface permafrost, Mackenzie delta region, Northwest Territories, Canada. Canadian Journal of Earth Sciences, 42 (1) 37-48 doi:10.1139/e04-089
	Fletcher, Terence P, Collins, Desmond H (1998) The Middle Cambrian Burgess Shale and its relationship to the Stephen Formation in the southern Canadian Rocky Mountains. Canadian Journal of Earth Sciences, 35 (4) 413-436 doi:10.1139/e97-120

Mindat.org is an outreach project of the Hudson Institute of Mineralogy, a 501(c)(3) not-for-profit organization.
Copyright © mindat.org and the Hudson Institute of Mineralogy 1993-2025, except where stated. Most political location boundaries are © OpenStreetMap contributors. Mindat.org relies on the contributions of thousands of members and supporters. Founded in 2000 by Jolyon Ralph.
To cite: Ralph, J., Von Bargen, D., Martynov, P., Zhang, J., Que, X., Prabhu, A., Morrison, S. M., Li, W., Chen, W., & Ma, X. (2025). Mindat.org: The open access mineralogy database to accelerate data-intensive geoscience research. American Mineralogist, 110(6), 833–844. doi:10.2138/am-2024-9486.
Privacy Policy - Terms & Conditions - Contact Us / DMCA issues - Report a bug/vulnerability Current server date and time: September 10, 2025 20:04:55

Go to top of page