The Effect of Moisture Content on the Thermal Conductivity of Moss and Organic Soil Horizons From Black Spruce Ecosystems in Interior Alaska

TitleThe Effect of Moisture Content on the Thermal Conductivity of Moss and Organic Soil Horizons From Black Spruce Ecosystems in Interior Alaska
Publication TypeJournal Article
Year of Publication2009
AuthorsO’Donnell, JA, Romanovsky, VE, Harden, JW, A. McGuire, D
JournalSoil Science
Volume174
Pagination646-651
Date PublishedDec
ISBN Number0038-075X
Keywordsactive layer, black spruce, boreal forest, boreal forests, carbon, climate-change, dynamics, model, moss, Permafrost, productivity, soil moisture, surface, thermal conductivity, water
Abstract

Organic soil horizons function as important controls on the thermal state of near-surface soil and permafrost in high-latitude ecosystems. The thermal conductivity of organic horizons is typically lower than mineral soils and is closely linked to moisture content, bulk density and water phase. In this study, we examined the relationship between thermal conductivity and soil moisture for different moss and organic horizon types in black spruce ecosystems of interior Alaska. We sampled organic horizons from feather moss-dominated and Sphagnum-dominated stands and divided horizons into live moss and fibrous and amorphous organic matter. Thermal conductivity measurements were made across a range of moisture contents using the transient line heat source method. Our findings indicate a strong positive and linear relationship between thawed thermal conductivity (K-t) and volumetric water content. We observed similar regression parameters (beta or slope) across moss types and organic horizons types and small differences in beta(0) (y intercept) across organic horizon types. Live Sphagnum spp. had a higher range of K-t than did live feather moss because of the field capacity (laboratory based) of live Sphagnum spp. In northern regions, the thermal properties of organic soil horizons play a critical role in mediating the effects of climate warming on permafrost conditions. Findings from this study could improve model parameterization of thermal properties in organic horizons and enhance our understanding of future permafrost and ecosystem dynamics.

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