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Geits, A. V., Makarov, O.A. (1977). About the distribution of the snow leopard in the Altai. In V. E. Sokolov (Ed.), Rare Types of Mammals and Their Conservation (pp. 115–116).
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Geits, A. V., Makarov, O.A., Shopin, R.P. (1975). Population of snow leopards in Tadzhikstan.116–117.
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Ghoshal, A. (2017). Snow Leopard Ecology and Conservation Issues in India. Resonance, , 677–690.
Abstract: Snow leopard, an elusive mammal species of the cat family,
is the top-predator of the Central and South Asian, highaltitude
ecosystem. Snow leopards occur at low densities across
the Central Asian mountains and the Indian Himalayan region.
Owing to their secretive nature and inaccessible habitat,
little is known about its ecology and distribution. Due to
its endangered status and high aesthetic value, the snow leopard
is considered as an �umbrella species� for wildlife conservation
in the Indian Himalayas. This article summarizes the
current knowledge on snow leopard ecology and conservation
issues in the Indian context.
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Ghoshal, A., Bhatnagar, Y. V., Pandav, B., Sharma, K., Mshra, C. (2017). Assessing changes in distribution of the Endangered snow leopard Panthera uncia and its wild prey over 2 decades in the Indian Himalaya through interviewbased occupancy surveys. Oryx, , 1–13.
Abstract: Understanding species distributions, patterns of
change and threats can form the basis for assessing the conservation
status of elusive species that are difficult to survey.
The snow leopard Panthera uncia is the top predator of the
Central and South Asian mountains. Knowledge of the distribution
and status of this elusive felid and its wild prey is
limited. Using recall-based key-informant interviews we estimated
site use by snow leopards and their primary wild
prey, blue sheep Pseudois nayaur and Asiatic ibex Capra
sibirica, across two time periods (past: �; recent:
�) in the state of Himachal Pradesh, India. We
also conducted a threat assessment for the recent period.
Probability of site use was similar across the two time periods
for snow leopards, blue sheep and ibex, whereas for wild
prey (blue sheep and ibex combined) overall there was an
% contraction. Although our surveys were conducted in
areas within the presumed distribution range of the snow
leopard, we found snow leopards were using only % of
the area (, km). Blue sheep and ibex had distinct distribution
ranges. Snow leopards and their wild prey were not
restricted to protected areas, which encompassed only %
of their distribution within the study area. Migratory livestock
grazing was pervasive across ibex distribution range
and was the most widespread and serious conservation
threat. Depredation by free-ranging dogs, and illegal hunting
and wildlife trade were the other severe threats. Our
results underscore the importance of community-based, landscape-
scale conservation approaches and caution against reliance
on geophysical and opinion-based distribution maps that have been used to estimate national and global snow leopard ranges.
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Grachev, Y. A., Fedosenko, A.K. (1975). Contemporary distribution and numbers of snow leopards in Kazakhstan.122–123.
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Green, M. (1980). Letter.
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Green, M. (1981). A check-list and some notes concerning the mammlas of the Langtang National Park, Nepal. Journal of the Bombay Natural History Society, 78(1), 77–87.
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Gronberg, E. (2011). Movement patterns of snow leopard (Panthera uncia) around kills based on GPS location clusters. Master's thesis, , .
Abstract: Research concerning movement patterns of wild animals has been advancing since GPS technology arrived. But studying the snow leopard (Panthera uncia) is still difficult because of the harsh territory it inhabits in Central Asia. This study took place in south Gobi, Mongolia, and aimed to estimate the time spent at kills and the maximum distance away from kills between visits. Snow leopards were monitored with GPS collars that took a location every five or seven hours. Potential kill sites were established by identifying clusters of GPS-locations in ArcGIS and visited in the field for confirmation. ArcGIS was used to calculate the distance between cluster and GPS-locations. I used two buffer zones (100 m and 500 m radius) to define the time snow leopards spent at kills. It was found that snow leopard age and prey category affected time spent at kills and also that snow leopard sex together with prey category affected the maximum distance moved away from kills between visits. Season had no significant effect on either time at kills or distance moved away from kills between visits. Snow leopards spent on average 3.2 days at their kills in the 100 m buffer zone and 3.5 days at their kills in the 500 m buffer zone. Subadults stayed longer at kills than adults and animals of both age categories spent longer time on larger prey. The mean maximum distance moved away from kills between visits was 179 m in the 100 m buffer zone and 252 m in the 500 m buffer zone. Female snow leopards moved further away from kills between visits than male snow leopards. Both the number of days spent on kills and maximum distance moved away from kills between visits increased when kills consisted of more than one animal. This study has provided some basic information on snow leopard behaviors around their kills but also highlights the need to monitor more snow leopards before more solid conclusions can be drawn as this study was based on based on a relatively small sample.
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Guoliang, P., Alexander, J. S., Riordan, P., Shi, K., Kederhan, Yang, H. (2016). Detection of a snow leopard population in northern Bortala, Xinjiang, China. Cat News, (63).
Abstract: We substantiate the presence of snow leopards Panthera uncia using camera
traps within the Dzungarian Alatau range in Bortala Mongolia Autonomous Prefecture,
Xinjiang Province, China. A total of 13 camera trap stations were set up in
2012 and a total of 14 camera trap stations in 2013 within an area of 192 km2. A total
of 11-15 individual adult snow leopards and two sub adults were identified from
photo captures of sufficient quality. A range of human activities were noted within
and surrounding the survey area, including livestock herding and mining. We recommend
more large scale and intensive camera trap surveys to further assess the
population status of the snow leopard within this area
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Gurung, G. S. (2011). Enhancing herder's livelihoods and conserving the snow leopard in Nepal. Cat News, 55, 6.
Abstract: Loss of livestock to snow leopards Panthera Uncia is one of the primary concerns of subsistence herders' communities and one of the primary threats to conservation of this endsngered species throughout the alpine regions of the central Asia. Unless the relationship between snow leopards abd humans is better understood and appropriate strategies are applied, coexistence may not be sustainable. thus, to address this issue, WWF Nepal piloted a community-managed livestock insurance scheme in Ghunsa valley of Kangchenjunga Conservation Area simultaneously with various types of mitigation measures (i.e preventive and curative) We found significan advantages of the insurance scheme including that it is self-sustaining and locally managed thereby ensuring it is economically viable and effective in preventive retaliatory killing of snow leopards. The main strength of the insurance scheme is that it was designed and developed in close co-operation with the affected herders' communities. The communities start by designing a simple livestock insurance plan whereby owners contribute to a common fund that is later administered and managed at the local level, thus reducing likelihood of fraud. Benefit sharing of funds among subsistence herders' communities from income generating activities is on of the positive motivating tools for people towards snow leopards. Since initiated, snow leopard killings have gone from 1-3/year to 0/year for 3 years.
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