Title: Permafrost%20in%20Canada%20and%20climate%20change
1Permafrost in Canada and climate change
Source NRC
2Source Hinzman et al. (2005)
3Snow permafrost warming
Source Stieglitz et al. (2003)
Source Stieglitz et al. (2003)
4Source Hinzman et al. (2005)
5Permafrost and climate change
- During the past few thousand years, Earth's
climate has been subject of fairly small changes
and world temperatures have fluctuated only
within a couple of degrees. - However, higher levels of carbon dioxide and
other greenhouse gases in the atmosphere may
progressively increase global temperature by as
much as 2 to 4oC over the next century.
6- In addition to temperature changes, the patterns
of precipitation would undoubtedly change -
annual totals would likely increase over the
arctic mainland, although current regional
projections are again quite variable between
models. - Increase of 10 to 50 in summer and as much as
60 in winter may be anticipated for parts of the
Canadian Arctic. - Such large and rapid climatic changes would have
serious and far-reaching environmental and
socio-economic effects in permafrost regions and
for the arctic environment as a whole.
7- Some might look on the transition to a warmer
Arctic with happy anticipation in the long term,
it would undoubtedly result in greatly reduced
costs of living and operating there. - New resources could become available, and mining
and agriculture, for example, might expand
however the terrestrial environment of the north,
in which permafrost plays a major role, would be
profoundly disrupted during the transition.
8- The mechanisms of energy exchange at Earth's
surface in cold regions are the same as those
elsewhere on the planet. Together they determine
the surface temperature regime and whether or not
frozen ground will exist.
9- Let us imagine some change in climatic conditions
which causes the mean annual surface temperature
to fall below 0oC, so that the depth of winter
freezing will exceed the depth of summer thaw. - A layer of permafrost would grow downward from
the base of the seasonal frost, thickening
progressively with each succeeding winter.
10- Was it not for the effect of heat escaping from
Earth's interior (the geothermal heat flux), the
permafrost would grow to depths in response to
surface temperatures only slightly below 0oC. - However, this outward heat flow results in a
temperature increase of about 30 K km-1, the
figure varying with regional geological
conditions.
11- Thus the base of permafrost approaches an
equilibrium depth where the temperature increase
caused by this geothermal gradient just offsets
the amount by which the surface temperature is
below freezing. - Whereas the base of permafrost is determined by
the mean surface temperature and geothermal heat
flow, the upper layers of permafrost are
influenced more by seasonal and interannual
fluctuations of temperature and snowpack.
12- The major variation in surface temperature has a
period of one year, corresponding to the annual
cycle of solar radiation (there is also a diurnal
variation corresponding to the daily cycle of
radiation). - Temperature variations experienced with the
passage of the seasons at the surface extend in a
progressively dampened manner to a depth of some
10-20 m.
13- Within the layer of annual variation, maximum and
minimum figures form an envelope about the mean,
and the top of permafrost is that depth where the
maximum annual temperature is 0oC. - Superimposed on normal periodic variations are
other fluctuations with durations from seconds to
years causes may included sporadic cloudiness,
variations in weather and changes in climate.
14- Let us now imagine some change in climatic
conditions which causes mean annual surface
temperature to rise. - The result would be deepening of the active
layer, as both the mean annual temperature and
the envelope of maximum (summer) temperatures
shift to higher values. - If climatic warming were sustained, the
permafrost table would recede further year by
year and the base of the permafrost would begin
to rise as surface warming propagated to greater
depths.
15- If the progressive warming were great enough,
then permafrost could eventually disappear
altogether. - Since permafrost is a thermal condition, it is
potentially sensitive to changes in climate. - However changes in the thermal regime of the
ground that lead to degradation (or formation) of
permafrost can result from environmental changes
other than fluctuations in climate.
16- For example, removal, damage, or compaction of
surface vegetation, peat, and soil alters the
balance of surface energy transfers, generally
raising mean summer surface temperature and
thawing the upper layer of permafrost. - In winter, increases in snow cover accumulation,
as can result from barriers, structures, and
depressions or changes in wind patterns, can lead
to significant warming of the ground. - Decreases in snow cover, in contrast, lead to
cooling of the ground, other things being equal.
17- While the effects of surface environmental
changes are usually restricted in areal extent,
climatic change can affect extensive areas of
permafrost. - Even modest climatic warming could have drastic
effects for terrain conditions and northern
engineering, since thousands of square kilometers
of warm permafrost would be directly affected. - While many centuries would be required for
complete degradation of the affected permafrost,
thawing from the surface would begin immediately,
with many potentially serious results.
18- There is some evidence that permafrost has been
retreating during the past decades Syslov (1961)
reports that the permafrost extent at Mezen
(Russia) has retreated northward at an average
rate of 400 m per year since 1837, whereas
similar findings have been reported for the
Mackenzie Valley of Canada. - Although permafrost is temperature dependent, the
relation with climate is not straightforward,
since the surface temperature regime does not
depend solely on geographic location.
19- Local surface conditions such as the type of
vegetation, depth of snow cover, soil type, and
moisture content, profoundly affect the surface
energy regime, being interposed between the
atmosphere and the ground. - Thus myriad local variations of vegetation,
topography, and soil conditions can cause
differences in mean ground temperatures of
several degrees over quite small areas. Wherever
average temperature is within a few degrees of
0oC, such variation mean that permafrost occurs
in patches, or discontinuously.
20- These circumstances, together with the scattered
nature of direct observations, make precise
mapping of permafrost difficult. - While cold is usually seen as the singular
feature of high latitudes, problems resulting
from thaw are generally of greater practical
concern.
21- Where permafrost contains ground ice,
considerable thaw settlement can occur and such
action has been responsible for significant
damage to buildings, roads, runways, etc. and
increased action would undoubtedly cause
additional and severe maintenance and repair
problems. - Special concern might be directed to existing
water-retaining structures, such as reservoirs,
and hydrodams, especially in areas of
thaw-sensitive permafrost.
22- Erosion of lake, river, and reservoir shorelines
may increase because of permafrost thawing and a
longer open-water season. - Greater sediment transport in rivers could
shorten the operating life of hydro-electric
projects, for example. - The expected rise in sea level accompanying
global warming could accelerate coastal retreat
in permafrost regions and combined with thaw
settlement as permafrost melts, could produce
inundation of low-lying areas.
23Potential Changes in the Components of the
Surface Water Budget, Kuparuk River Basin
Source Déry et al. (2005), JHM.
24Source Anisimov (2006)
25Slaymaker and Kelly (2007)
26Source Lawrence and Slater (2005)
27Source Lawrence and Slater (2005)
28Source Lawrence and Slater (2005)
29Source Vavrus (2007)
30Source Vavrus (2007)
31(No Transcript)