The area was divided into four elev

The area was divided into four elevation classes. The elevation
map (Fig. 2) reveals that elevation ranges from 2031 to 4311m asl.
More than 89% of the debris-rock slides falls in the elevation interval
ranging from 3000 to 4311ma.s.l. (categories 3 and 4), with a
frequency ratio of 1.306 and 3.656 which means a higher correlation
but with a coefficient of logistic regression of 1.000, signals of
low elevation influence.
Aspect regions (Fig. 2) were classified according to the aspect
class as flat (1
), north (315
e360
, 0
e45
), east (45
e135
),
south (135
e225
) and west (225
e315
). More than 76% of debris
rockslides fall within the quadrants represented the east category
aspect (Table 2), with a frequency ratio of 1.935 (higher correlation)
and a coefficient of logistic regression of 0.989. This means an influence
of aspect on debris rockslide.
The slope angle map (Fig. 2) was divided into four slope classes:
(a) flat to gentle slope (0
e15
), (b) moderate slope (15
e25
), (c)
fairly moderate slope (25
e35
), (d) steep slope to very steep slope
(35
e57
). The slide percentage in each slope class is presented in
Table 2. This table indicates that most of the debris rockslides occur
at slope angle between 15
and 35
, with a frequency ratio of 1.375
and 2.003, which indicates a higher correlation and coefficients of
logistic regression of 1.038.
Six lithological units (Fig. 2) were differentiated depending on
the rock type. The units included (1) limestone and dark lutite, (2)
sandstones and lutites, (3) conglomerate, sandstones and argillite,
(4) conglomerates, (5) colluvial-alluvial deposits and (6) Unconsolidated
modern deposits, sand, silt and clay. All the debris rockslides
observed in the area occurred in the unit number 2 (Table 2)
which means that sandstones and lutites are the most influent lithology-
type.
An examination of the distances to lineaments map (Fig. 2 and
Table 2) reveals that most debris rockslides (about 59%) occur less
than 1500 m from the lineament. However, no accuracy constraint
exists for the position of the faults which were mostly extracted
from morphological interpretation. However, the study area and its
vicinity are significantly affected by the Neotectonic activity of the
region (Perucca and Onorato, 2011).
Although there is a lack of numerical dating evidence, the debris
rockslides can be assigned to mid-late Quaternary based on their
physical location in the landscape and relative degree of preservation
(accumulation and depletion zone preserved, well preserved
failures). The role of rainfall as landslide trigger is acknowledged.
However, while there is no doubt that precipitation has amajor role
in initiating slope failures in the surroundings of the study area
(Esper Angillieri, 2011), the abundant earthquakes and very active
faults (Perucca and Onorato, 2011; Esper Angillieri and Perucca,
2013) in the area have a key role to play. Hence, it is possible to
conclude that the debris rockslides may have been triggered by
high magnitude earthquakes, as was previously observed by
Hermanns et al. (2001), who had argued that most of the landslides
of central-western Argentina were seismically triggered.
5. Conclusion
Through high resolution satellite imagery interpretation, 35
debris rockslides were identified. In all debris rockslides, the lithology
(sandstones and lutites) acts as the main controlling factor.
A seismic origin related to Qauternary faults is proposed as the
triggering factor of landslides in the area. Nevertheless, it has not
been possibly to clearly relate a single slide to a certain trigger
event or fault. In this context, earthquakes should be considered as
a primary triggering factor for slide occurrence rather than precipitation
in the study area.
The statistical analysis revealed that the distribution of debris
rockslides can be explained mainly by lithology, with some additional
influences of elevation and aspect. All debris rockslides lie