Abstract Analysis and modelling of temperature anomalies from 25 selected deep wells in Alberta show that the differences between GST (ground surface temperature) warming for the northern Boreal Forest ecozone and the combined Prairie Grassland ecozone and Aspen Parkland transition region to the south occur during the latter half of this century. This corresponds with recent changes in surface albedo resulting from permanent land development in the northern areas and also to increases in natural forest fires in the past 20 years. Differences between GST and SAT (surface air temperature) warming are much higher in the Boreal Forest ecozone than in the Prairie Grassland ecozone and Aspen Parkland transition region. Various hypotheses which could account for the existing differences between the GST and SAT warming in the different ecozones of Alberta, and western Canada in general, are tested. Analysis of existing data on soil temperature, hydrological piezometric surfaces, snowfall and moisture patterns, and land clearing and forest fires, indicate that large areas of Alberta, characterised by anomalous GST warming, have experienced widespread changes to the surface landscape in this century. It is postulated that this has resulted in a lower surface albedo with a subsequent increase in the absorption of solar energy. Heat flow modelling shows that, after climatic SAT warming, permanent clearing of the land is the most effective and likely cause of the observed changes in the GST warming. The greater GST warming in the Boreal Forest ecozone in the latter half of this century is related to landscape change due to land development and increasing forest fire activity. It appears to account for a portion of the observed SAT warming in this region through a positive feedback loop with the overlying air. The anthropogenic effect on regional climatic warming through 20th century land clearing and landscape alteration requires further study. In future, more accurate quantification of these various forcings will be necessary in order to distinguish between, and to detect, the variety of natural and anthropogenic influences and on climate.
[1]
Kelin Wang,et al.
Influence of terrain on bedrock temperatures
,
1992
.
[2]
C. E. V. Wagner.
The Historical Pattern of Annual Burned Area in Canada
,
1988
.
[3]
Underground temperature fields and changing climate: evidence from Cuba
,
1992
.
[4]
G. Watts,et al.
Climate Change 1995
,
1998
.
[5]
A. Lachenbruch,et al.
Changing Climate: Geothermal Evidence from Permafrost in the Alaskan Arctic
,
1986,
Science.
[6]
J. Houghton,et al.
Climate change 1995: the science of climate change.
,
1996
.
[7]
J. Majorowicz,et al.
ANOMALOUS GROUND WARMING VERSUS SURFACE AIR WARMING IN THE CANADIAN PRAIRIE PROVINCES
,
1997
.
[8]
R. Harris,et al.
Borehole Temperatures and a Baseline for 20th-Century Global Warming Estimates
,
1997,
Science.
[9]
H. Pollack,et al.
Underground Records of Changing Climate
,
1993
.
[10]
J. Majorowicz.
Climate change inferred from analysis of borehole temperatures: First results from Alberta Basin, Canada
,
1993
.