The Mackenzie Landslide Database Summary

(Summary of the data provided in Open Files 3915, 3916, and 3917)

Landslides occur the length of the Mackenzie valley, however, 
they tend to be concentrated in specific zones within the study 
area.  These zones include the banks of the Mackenzie and its 
tributaries where the rivers have eroded deep channels into the 
underlying unconsolidated Quaternary sediments or, in places, 
bedrock; the slopes rising towards the Mackenzie and Richardson 
mountain fronts; the steep slopes of the ranges in the Mackenzie 
and Franklin mountains to the west of the Mackenzie River, and 
to a lesser extent the slopes of the ranges east of the 
Mackenzie River; the shores of the hundreds of small lakes of 
the Tuktoyaktuk Peninsula and Richards Island; and the cliffs of 
the Beaufort Coast.

Landslides range in area from 225 m2 to 20 km2.  The mean area 
(scar and debris tongue) of a landslide in the inventory is 
approximately 0.5 km2 and median value is 0.25 km2.  In general, 
size of landslide increases towards the south.  The northern 
part of the study area is characterized by  hundreds of small 
retrogressive thaw flows.  Rotational slides, which generally 
are larger, are more frequent in the southern part of the study 
area.  Many of the massive landslide areas are composed of 
several large coalescing and overlapping landslides which 
may represent years of landslide activity rather than one event.

Elevations of the scars range from a few metres above sea level 
along the Beaufort coast to 1980 m in the Mackenzie Mountains.  
A general trend of increasing elevation of landslide scar to the 
west reflects the general rise to the Mackenzie and Richardson 
mountains.  Although there is a range of elevations represented, 
generally landslides are restricted to lower elevations (500 m 
or lower).  These are the areas with the greatest accummulation 
of unconsolidated Quaternary sediments, in particular 
glaciolacustrine sediments, and also the areas most affected by 
river erosion.  Landslides at higher elevations are almost 
exclusively bedrock failures on steep slopes.

Although no strong relationship exists between landslide 
frequency and aspect (direction of movement), there are 
somewhat fewer landslides with a northerly aspect.  When only 
landslides in unconsolidated Quaternary sediments are 
considered, a westerly aspect is slightly more dominant than 
the other directions. For the most part, the role of aspect 
unrelated to site control is insignificant. Site considerations, 
i.e. position with respect to the thalweg of a river or 
inclination of a bedrock formation, are more important.

Certain geological materials are particularly prone to slope 
failure. Most landslides in rock occur in shale or in 
shale-mudstone-siltstone formations, -soft, thinly bedded and 
generally friable and fissile sedimentary rock. Where landslides 
occur in harder, more competent rock such as limestone, 
dolomite, sandstone, and quartzite, the failure probably occurs 
along a bedding plane or in a shale bed within or beneath the 
more competent rock formation.  Shale may move as a flow 
(active-layer detachment or debris flow) if very moist and 
disintegrated or as a slide; limestone and dolomite fail as a 
slide, either a translational failure along a bedding plane, or 
a rotational failure on underlying weak shale.

For unconsolidated Quaternary deposits, the greatest number of 
landslides (65%) occurred within till, a glacial sediment having 
a wide range of particle sizes.  This number of failures is 
probably a reflection of both the potentially icy nature of the 
fine-grained matrix and the widespread distribution of till as 
compared to other Quaternary sediments within the region.  In 
some cases, the failure plane is at the till/bedrock interface.  
Lacustrine clays and silts are involved in 17% of the landslides 
and glaciofluvial sands, silts, and gravels (10% of the 
landslides), deltaic sands and silts (5% of the landslides) and 
other deposits (3% of the landslides).  In the case of 
glaciofluvial and deltaic sediments, the deposit commonly 
overlies lacustrine fine-grained sediments and in many instances 
the failure includes these underlying sediments.

Fine-grained sediments (silts and clays or fine-matrix tills) 
are commonly ice-rich, with ice content varying from ice 
crystals to massive lenses of pure ice. Thaw in ice-rich, 
fine-grained sediments causes flow-type landslides, due to 
the low strength of the resulting water-saturated sediments.  
In these icy sediments, even low-angle slopes in areas of 
relatively little relief are susceptible to active-layer 
detachments and retrogressive thaw flows.  If relief is 
sufficient, these flows can move very rapidly as debris flows. 
Although much less common, sands, if well saturated, also may 
flow rapidly downslope as debris flows.

Coarse-grained sediments (sands and gravels) are less likely to 
contain ice in excess of the pore volume and tend to fail in 
blocks as rotational slides.  Landsliding is most likely along 
steep riverbanks eroded in sands and gravels and may be promoted 
by the presence of weaker, unfrozen lacustrine clays underlying 
the typically frozen sands. 

A full discussion of the data can be found in Aylsworth et al., 
2000 and in Aylsworth and Duk-Rodkin, 1997.  These papers 
discuss the types and distribution of landslides in the 
Mackenzie valley, their failure mechanisms, their geological and 
permafrost associations, their susceptibility to climatically 
induced triggers, and the probable impact of climate change on 
slope failure in the future.  With respect to the latter, the 
authors suggest that there will be a period of increased 
landslide activity as the landscape adjusts to new climate 
conditions and that this activity likely will be greatest in 
those regions that are currently experiencing landslide 
activity.  Sites most susceptible to climatically-induced 
landslides include ice-rich, fine-grained sediments on slopes 
in close proximity to bodies of water or rivers,  or  frozen 
coarse-grained sediments overlying clay or  clayey till in 
steep sections along river banks where permafrost does not 
extend to the base of the section.

REFERENCES

Aylsworth, J.M., Duk-Rodkin, A., Robertson, T., and Traynor, J.A.
2000:	Landslides of the Mackenzie Valley and adjacent 
	mountainous and coastal regions; in The Physical 
	Environment of the Mackenzie Valley: A Baseline 
	for the Assessment of Environmental Change, L.D. Dyke
	and G.R. Brooks (eds.), Geological Survey of Canada 
	Bulletin 547, p. 167-176.

Aylsworth, J.M. and Duk-Rodkin, A.
1997: 	Landslides and Permafrost in the Mackenzie Valley; in 
	Mackenzie Basin Impact Study, Final report, S. Cohen, 	
	(ed.), Environment Canada, p. 118-122.