WII Technical Reports/Books/Manuals
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Item Capacity building initiative on the dispersal and ranging patterns of elephants for effective management of human-elephant interactions(Wildlife Institute of India, Dehradun, 2022) Nigam, P.; Pandav, B.; Mondol, S.; Lakshmiarayanan, N.; Kumar, A.; Nandwanshi, V.B.; Das, J.; Biswas, S.; Udhayaraj, A.D.; Vishwakarma, R.; Habib, B.; Miachieo, K.; Narasingh Rao, P.V.Wild Asian elephant (Elephas maximus) populations are distributed in four major regions namely North West, North-East, East-Central and Southern regional meta-populations across India. Amongst them, the East-central regional population spread across the States of Odisha, Jharkhand, southern West Bengal, Chhattisgarh, and lately in Madhya Pradesh suffers disproportionately high levels of human elephant conflict. Among the myriad challenges facing management of human-elephant conflict in the region, elephant range expansion into new areas is overriding. One such range expansion that resulted in acute human-elephant conflict is being witnessed in the State of Chhattisgarh. Although northern Chhattisgarh was historically an elephant range, elephants reportedly disappeared during the period 1920 to late 1980s. While episodes of sporadic elephant occurrence in Chhattisgarh was reported during the period 1988- 1993, contemporary range expansion and concomitant human-elephant conflict began from the year 2000, and has accelerated during the last one decade. Faced with an enormous challenge of managing human-elephant conflict that is spatiotemporally dynamic unlike that of other elephant range States, constrained by limited Institutional capacities to assess and deal with the issue. Chhattisgarh Forest Department has been trying diversity its conflict mitigation strategies. Recognizing the need to objectively evaluate human-elephant conflict situation in the State, during the year 2017 Chhattisgarh Forest Department invited Wildlife Institute of India to conduct ecological research on elephants in Chhattisgarh with a three-year budget outlay. The project was a collaborative effort between Chhattisgarh Forest Department and WII. Considering the scope of the project, the project duration was further extended and eventually, the project lasted for the period July 2017 to March 2022. Being the final project report, the activities carried out as part of the project is summarized as under. Distribution and Demography In Chhattisgarh, the elephant distribution during the period 2012 to 2017 was reported from 16 Forest Divisions and four Protected Areas in the north and north-central regions of the state. The elephant population, as enumerated by Chhattisgarh Forest Department during 2021 , ranged from 250 to 300. The adult sex ratio recorded during the study was 1: 4.5. About 44% of the female segment of the population comprised of adults. Chhattisgarh elephant population is presently contiguous with other elephant populations in the neighboring states i.e., Madhya Pradesh, Jharkhand and in Odisha occurring as a meta-population 1 and thus cannot be considered as an isolated population. However, within Chhattisgarh, the population is relatively small and it occurs scattered over a large area as small and disjunctive groups facing a perpetual risk of getting isolated by ongoing linear infrastructure and other associated developmental activities in the State. If such groups get isolated, then they will not be viable in the long run. 1 Meta-population: Population of small populations that are connected through dispersals 1 O. ~ . -~ 1 -WU.d.U.fe .In.s-titu-te. o.f .In.di a Home Range, Movement Patterns & Dispersal, and Habitat Selection by Elephants During the period 2018-2022, WII-CGFD collaborative effort resulted in 10 elephant radio collaring in Chhattisgarh. The resultant effort provided 3106 elephant days of tracking information. Each of the radiocollared elephants provided an average of 310.6 (± 273) days of tracking data. As on 31 51 March 2022 when WII-CGFD collaborative project ended, two of the collared elephants (SD - Sehradev and MT - Maitri) were having functional collars. The estimated average home range (95% minimum convex polygon) of elephants in Chhattisgarh was 3172.8 km2 (± 2002.2 km2, Range: 462.3 - 6969.7 km2). The 95% kernel density home ranges of elephants were much lower averaging 512.3 km2 (± 235.3 km2, Range: 126.5 - 748.9 km2). The elephant home ranges were not wholly well defined, and marked by inter-annual shifts caused by exploratory behaviour. The elephant home ranges were relatively large. The dry season home ranges were significantly lower than monsoon and winter ranges. However, dry season home ranges of elephants are larger. The present study indicates that habitat quality in some of the forest patches - particularly those that are large and contiguous with minimal of human interference can potentially support elephants in the landscape. Thus, dry season ranges of elephants could serve as a surrogate for habitat quality. Monthly variations in home ranges were significant, and best explained by idiosyncrasies of individual elephants. Among the forest types open, moderately dense and very dense forests classified by Forest Survey of India based on crown densities, elephants selected open forests, that were predominantly juxtaposed with human-use areas. Although the crown density was low, the patches of open forests support dense stands of Sal (Shorea robusta) coppice with rank undergrowth offering adequate cover for elephants. Elephant habitat selection of these open forest patches appears to be influenced by potential foraging opportunities in human-use areas, and further facilitated by low inter-patch distance. Genetic Structure of Elephants Using 258 genetic samples collected from 9 Forest Divisions, elephant genetic structure in northern Chhattisgarh was evaluated. Analysis indicates that at least two different elephant lineages occur in Chhattisgarh. This implies that elephants occurring in Chhattisgarh have possibly come from different areas. Within the two different lineages, high relatedness amongst the individuals was observed corroborating with the general social structure of Asian elephant clans where individuals are mostly related. Crop Losses and Human Fatalities due to Elephants Crop losses caused by elephants were acute and widespread in Chhattisgarh. To draw an analogy, Karnataka's ex gratia payment towards crop losses by elephants during the period 2015-2020 was comparable with Chhattisgarh, although the former's elephant population is 93% more than the latter. The landscape-level assessment covering the whole of northern Chhattisgarh, and fine-scale assessment covering select areas in Surguja circle identified correlates of crop losses at both spatial scales. Elephant-related human deaths were widespread in the state. However, nearly 70% of incidences occurred in areas of high intensity of habitat-use by elephants. The human fatalities due to elephants were both temporally and spatially auto-correlated. 2Item Ecology of tigers in Pench Tiger Reserve, Madhya Pradesh and Maharashtra(Wildlife Institute of India, Dehradun, 2013) Sankar, K.; Qureshi, Q.; Jhala, Y.V.; Gopal, R.; Majumdar, Aniruddha; Basu, S.The present study aimed to map land use/land cover patterns and to assess spatial structure and configuration of landscape; structure and composition of vegetation types in landscape; and varies ecological aspects of tiger (Panthera tigris) in a tropical deciduous forest of Central India from 2005 to 2013. Prey species availability was estimated using line transect method in an intensive study areas of 410 sq km between January 2007 and June 2012.Item Ecological impacts of major invasive alien plants on native flora in Rajaji Tiger Reserve, Uttarakhand(Wildlife Institute of India, Dehradun, 2024) Kumar, Amit; Kumar, S.; Sahu, H.; Patra, R.; Page, N.; Qureshi, Q.This study focuses on Rajaji Tiger Reserve in Uttarakhand, within the Shivalik hills, to investigate the invasion patterns and ecological impacts of a major invasive plant speciesItem PAN-India assessment and monitoring of endangered species covered under the Integrated Development of Wildlife Habitat Program (IDWH) - Snow leopard(Wildlife Institute of India, Dehradun, 2025) WII-MoEFCCIn 2019, the MoEF&CC launched the 'Snow Leopard Population Assessment in India (SPAI)* program, as part of India's active participation in the National and Global Snow Leopard and Ecosystem Protection Program (NSLEP & GSLEP). India has contributed in three significant landscapes to NSLEP & GSLER viz. Hemis-Spiti, Nanda Devi-Gangotri, and Khangchendzonga-Tawang. Alongside twelve National Snow Leopard and Ecosystem Priorities (NSLEPs), these efforts are aimed at conserving snow leopard and its habitats. The SPAI was designed to generate scientifically robust national and state-wise population estimates of the snow leopard across the high altitude habitats both inside and outside protected areas. Its overarching goal is to gather reliable data to guide effective conservation efforts and policy decisions. Based on the consultations with the Chief Wildlife Wardens (CWLWS) of the states and Union Territories (UTs) the SPAI sampling exercise was effectively executed across the PAN-INDIA Assessment and Monitoring of Endangered Species Covered Under the Integrated Development of Wildlife Habitats Program (IDWH) - SNOW LEOPARD Union Territories of Ladakh and Jammu & Kashmir and four snow leopard range states viz. Himachal Pradesh, Uttarakhand, Sikkim, and Arunachal Pradesh. The SPAI exercise was conducted from 2019 to 2023 following a two-step framework. Within this, the STEP-I involved a meticulous evaluation of snow leopard spatial distribution, incorporating habitat covariates into the analysis. This approach, founded on occupancy modeling, relied on data sourced from sign and interview surveys, comprehensive fieldwork, and precise geospatial mapping. This assessment culminated in the refinement of the snow leopard distribution map and the establishment of a foundational dataset for the stratification of snow leopard population sampling. In the STEP- II, snow leopard abundance estimation was achieved through camera trapping. Furthermore, comprehensive abundance assessments were conducted for the primary prey species at selected sites. Given the constraints posed by the situations of Covid-19, some states such as Sikkim and Arunachal Pradesh conducted the STEP-I and II exercises simultaneously. Till 2016, a substantial third of the snow leopard range (spanning ca. 100,347 km2) had not received research attention, which was reduced to just 5%, mainly in small pockets of Ladakh, Jammu & Kashmir; Uttarakhand, and Himachal Pradesh. However; status surveys in the recent years have increased the understanding on preliminary information about snow leopard or prey is available for 80% of the snow leopard range (ca. 79,745 km2), compared to 56% in 2016. To provide robust information on the snow leopard numbers, the SPAI exercise involved surveying the snow leopard habitats using a substantial network of camera traps. In total, the SPAI sampling exercise utilized 1,971 camera trap locations, leading to the identification of 241 unique individuals. These comprehensive findings allow for the estimation of a total snow leopard population of 718 individuals in India. A total of 126 unique snow leopard individuals were identified from the Union Territory of Ladakh, across a total of 956 camera trap locations, yielding an estimated density of 0.34 individuals/100 km2 and a population of477 individuals. Camera trapping efforts in 135 sites in the Union Territory of Jammu & Kashmir led to detection of 9 unique individuals across the snow leopard range. The estimated density was 0.75 individuals/100 km2 and population of 9 individuals. For the snow leopard range states, Himachal Pradesh recorded a total of 44 unique individuals identified across 284 camera trap locations. The density of snow leopard in the state ranged from 0.08 to 0.37 individuals/100 km2. The exercise was indicative of a mean population size of 51 individuals of snow leopard in Himachal Pradesh. The state of I PAN-INDIA Assessment and Monitoring of Endangered Species Covered Under the Integrated Development of Wildlife Habitats Program (IDWH) - SNOW LEOPARD Uttarakhand recorded a total of 40 unique individuals, with a density ranging from 0.7 to 1.04 individuals/100 km2. The population estimates of snow leopard in Uttarakhand was 124. In the eastern Himalayan states, Sikkim, with a total of 99 camera trap locations, recorded a total of 14 unique individuals with an estimated density of 0.40 snow leopards/100 km2. The estimate was 21 snow leopards for this state. On the other hand, in Arunachal Pradesh, 8 unique snow leopards were identified across 115 camera trap locations. The density was 0.26 individuals/100 km2 and the population was estimated as 36 individuals in the state. In the Indian Himalayan region, two prey species dominate the diet of the snow leopard: the bharal or blue sheep (Pseudois nayaur), and the Siberian ibex (Capra sibirica). Bharal exhibit a near-total range overlap with snow leopard across the greater and trans-Himalayan regions, while ibex occupy extensive ranges within the northwestern trans-Himalayan region. In the subalpine and alpine region Himalayan tahr and musk deer form important component to snow leopard diet. Other mountain ungulates, though less prominent, contribute to the diet and hold local importance. Himachal Pradesh is the only snow leopard range state in India where systematic surveys on its primary prey species have been conducted. Conversely, states like Arunachal Pradesh and Jammu & Kashmir remain significantly understudied, while data from Uttarakhand and Sikkim are fragmented and localized. Ladakh, due to its visibility and accessibility, has a relatively well-documented history of ungulate monitoring. Limited long term data suggest a decline in ungulate populations across the Himalaya, except for the Tibetan antelope (Pantholops hodgsoni), which has shown signs of recovery. Markhor (Capra falconeri) habitat shrank from 300 km2 in the 1940s to just 120 km2 by 2004-2005. Similarly, musk deer (Moschus spp.) in Kedarnath Wildlife Sanctuary (Uttarakhand) have seen a steady decline from 3.7 individuals/km2 (1989-1991) to 1.2 individuals/km2 by 2000. A similar declining trend is evident in ibex (Capra sibirica) populations in Pin Valley National Park, Himachal Pradesh. Density estimates dropped from 2.3 individuals/km2 in 1989 to 1.2 individuals/km2 in 1997, with a further reduction to 0.37 individuals/km2 by 2012. These declines underscore the urgent need for targeted conservation efforts and systematic prey monitoring to ensure the long-term viability of snow leopard populations.Item Unveiling Torputitora presence in Sikkim streams through eDNA(Wildlife Institute of India, Dehradun, 2025) Mane, S.S.; Pant, B.; Kolipakam, VishnupriyaEnvironmental DNA (eDNA) metabarcoding was used to detect the presence of Tor putitora (Golden mahseer) in selected streams of Sikkim. Water samples were collected from six sites based on habitat characteristics conducive to the species survival. The collection of samples was followed by filtration of water samples, isolation of the DNA, PCR and sequencing targeting the COI region were conducted under aseptic conditions. The results confirmed Tor putitora presence at two locations (BR-06 and BR-08) with high certainty (>99%) aligning with previous studies on tis distribution in Sikkim. These results indicate that these streams serve as habitats for Tor putitora. These findings highlight the potential of these streams to support mahseer populations, reinforcing the need for conservation efforts to protect these critical habitats from ecological threats like ecological pressures, including hydropower and linear infrastructure development. This study adds to the expending evidence concerning mahseer distribution in Sikkim and highlights the critical need for conservation initiatives aimed at safeguarding its essential habitats by incorporating appropriate mitigation measures. Continued research and long term monitoring are imperative to evaluate population dynamics and ensure the sustainable management of Tor putitora in the region.Item Patterns of Mortality in Free Ranging Tigers(Wildlife Institute of India, Dehradun, 2016) Nigam, Parag; Muliya, S.K.; Srivastav, A.; Malik, P.K.; Shrivastava, A.B.; Mathur, V.C.This study initiated an effort to maintain a centralized database of all tiger mortality events that are reported in India to address this shortcoming. We have initiated an attempt to study mortality patterns of tigers inhabiting landscapes in India based on available reports of mortality events in tigers from this databaseItem Rapid survey and mapping of medicinal plants in forest divisions of Garhwal region, Uttarakhand : Executive summary(Wildlife Institute of India, Dehradun and Uttarakhand Forest Department, 2012) Rawat, G.S.Item Status, distribution and conservation perspectives of lesser florican in the North-Western India: a survey report(Wildlife Institute of India, Dehradun, 2011) Bhardwaj, G.S.; Sivakumar, K.; Jhala, Y.V.The Lesser Florican Sypheotides indica, a species endemic to the Indian subcontinent, is largely seen during the monsoon season in north-western India, where it breeds. Its population and range is believed to be decreasing at an alarming rate due to breeding habitat loss and threats in the non-breeding habitats, believed to be in south and south-east India. In this connection, to understand the present status and distribution of Lesser florican in the north-western India i.e. in Gujarat, Madhya Pradesh and Rajasthan, a survey following an established protocol (Sankaran 2000) was carried out in the month of August 2010, which is a part of breeding season of this species, when most of males display in the grasslands. A total of 84 individual Lesser Floricans (83 male and 1 female) were sighted in three states of north-western India, which is 65% less than the sightings reported in 1999 by Dr. Sankaran. It was found significantly fewer sightings than reported in 1999 in all grasslands surveyed (t=2.81, df=14, p<0.05). Of the 169 potential grasslands available for floricans in the north-western India, 91 grasslands were surveyed, which include grasslands surveyed during 1999. Of the surveyed grasslands, Lesser Floricans were found in 24 grasslands as against 37 grasslands in 1999. Among the three states, more sightings of Lesser Florican were reported in the state of Gujarat (N=54) followed by Rajasthan (N=18) and Madhya Pradesh (N=12). But in 1999, more sightings of florican were reported in Gujarat (N=141) followed by Madhya Pradesh (N=63) and Rajasthan (N=34). More than 55% of grasslands in Gujarat that were reported with florican in 1999 (Sankaran 2000) were observed without florican in 2010. More or less similar situation was in Madhya Pradesh also. Population and habitat of Lesser Florican in the north-western India was observed to be continuously declining at an alarming rate. Lack of a National Policy on grassland management, habitat degradation, plantations, poor landuse planning, pesticide pollution, invasive species, inadequate coverage of florican habitats in the Wildlife Protected Area Network and lack of knowledge on the non-breeding habitats of this species are observed to be major threats to this species.Item Ecology of two endemic turtles in the Western Ghats(Wildlife Institute of India, Dehradun, 2010) Vasudevan, K.; Pandav, B.; Deepak, V.This project was initiated on the 16th January 2006 with an aim to generate natural history information on two out of the three endemic species of terrestrial turtles. India has 28 species of freshwater turtles and tortoises, of them three species are endemic. The endemic species: Caneturtle, Vijayachelys silvatica; Travancore tortoise Indotestudo travancorica; Leith’s softshell Nilssonia leithii, are restricted to the southern peninsula and the Western Ghats. In this study the focal species were the Cane turtle and the Travancore tortoise which had their distribution in the Western Ghats. The objectives of the project were (i) to estimate the population density of Travancore tortoise and cane turtle in a fragmented landscape; (ii) to quantify the diet of these two species and describe the feeding ecology with respect to their role in seed dispersal; (iii) to identify threats to the turtle population based on their habitat use ranging pattern and food habits and recommend measures for their conservation; (iv) to carry out a survey of these two species along the Western Ghats to ascertain the exact distribution in the context of Protected area network in the region. The study employed methods to study the population, diet and ranging patterns of the Cane turtle and the Travancore tortoise in Anamalai and Parambikulam Tiger Reserves. In the case of Travancore tortoise, the animals were searched on forest trails scattered in the reserves and repeated over three years to determine the proportion of area occupied accounting for imperfect detections. These surveys revealed that about 82% of the area surveyed is occupied by the tortoise, suggesting that the reserves hold sizeable population of the tortoise. The occupancy of the Travancore tortoise was negatively influenced by anthropogenic disturbance levels and positively influenced by the availability of water bodies and grass marsh in different sites. Only 35% of the sites occupied by the species resulted in detections, suggesting that it was cryptic. The important constituents of its diet were grass, other plant matter, invertebrates and other animal matter. The vayal (grass openings within woodland) habitat might be crucial for foraging by Travancore tortoise. The five individuals that were radio-tagged used an area from 5 to 35 ha covering evergreen, bamboo and open scurb-grass marshes. The animals spent about 98% of their time under leaf litter, logs, rocks crevices, tree holes, termite or pangolin burrows, bamboo tickets and under grass. In the case of cane turtle, various search methods employed did not yield detections and therefore, an intensive area was combed intensively. This resulted in detections of the elusive cane turtle. During the study spanning over four years, 42 ha of the evergreen forests in the reserve resulted in sightings of 27 different individuals of the cane turtle. This suggests that the species occurs in high density in the evergreen forests. Six cane turtles were fixed with radio-transmitters and monitored for two years. They used an area from 3.5 to 14.2 ha restricted to the evergreen forests alone. They also had extensive overlap in their home-ranges, suggesting no territoriality in the species. The movement of the animals were influenced by temperature and rainfall in the intensive study area. Diet of the species consisted of forest floor invertebrates, seeds and other plant material. The field observations on feeding on a large land snail and aggressive encounters between males of the cane turtle were the highlights of the study on the species. A survey of the three endemic species of turtles was taken up in the fifth year of the project. The survey involved visiting 12 sites in the states of Karnataka and Tamil Nadu. The potential sites where the species might be found were visited and the locals were interviewed in order to document the occurrence of the species. This resulted in one new locality record for cane turtle and two new records for Travancore tortoise. The Leith’s softshell was reported from five different locations in Karnataka and Tamil Nadu based on the interviews with locals. The sites occupied by the species were located within and outside protected areas. So far the study has resulted in three peer reviewed publications and two presentations in international conference. Based on the findings of the study it could be inferred that the Travancore tortoise is sensitive to human disturbance. This might be the consequence of exploitation of the animal by the locals in the reserves where the study was conducted. It is not uncommon to find locals using domesticogs during their forays into the forest. We speculate that there is some level of subsistence exploitation of the species in the region. The behaviour and ranging pattern of the species make them cryptic for detection by humans, but vulnerable to detection by domestic dogs. The study revealed that there is poor awareness among wildlife protection staff in the reserves on the species in general. Increasing the awareness of the staff could result in curbing subsistence exploitation of the species in the reserves. The vayals in the reserve are crucial habitats for the species; therefore, their protection and monitoring should be of importance for the persistence of the tortoise population. In the case the cane turtle, contrary to our initial expectations they survive in high densities (60 individuals in 1 sq. km) in the middle and low elevation evergreen forests (between 10 – 1000 m above mean sea level). The Karian Shola National Park is having a large population of this species which is of importance of the management of the protected area. The species is extremely stenotypic, showing strong preference to a narrow range of microclimatic variation prevailing in evergreen forests that are below 1000 m elevation in the Western Ghats. This indicates that the low elevation evergreen forest areas are crucial habitats for the species. Our intensive study on the species spanning over four years did not yield much information on the reproductive ecology of the species, because of their secretive lives. We recommend studies on the reproductive biology of the species, which might be important in the context of conservation breeding of the species. In the case of Leith’s softshell, we suggest extensive surveys to document the distribution, the status of population and, the genetic and morphological variation in the populations in peninsular India.Item Distribution and abundance of birds and mammals in the Southern Indian ocean, larsemann hills and princess astrid coast East Antarctica(Wildlife Institute of India, Dehradun, 2010) Jayapal, R.; Ramesh, K.The spatial distribution and abundance of sea birds, penguins and pack ice seals along the Southern Ocean, Ingrid Christensen and Princess Astrid Coast during 29th Indian Scientific Expedition to Antarctica was carried out between November 2009 and March 2010. A total of 34 species of birds with an encounter rate of 9.82/ nautical miles2 were recorded. High species turnover of sea birds was observed between 40° and 50° S longitude. Six aerial sorties were flown along the Ingrid Christensen and Princess Astrid Coast to count penguins and seals along the coast, totalling a length of approx. 1200 km. Adelie and Emperor penguins were recorded with encounter rate of 0.63 ± 0.20 (#/nm ±SE) and 3.81 ± 1.68 (#/nm ±SE) respectively at Ingrid Christensen casts. At Princess Astrid Coast more number of Adelie penguins (1.22 ± 0.12/nm ±SE) was recorded when compared to Emperor penguin (0.60 ± 0.2/nm ±SE). In the present survey, a total of 3601 hauled-out seals were counted from six aerial sorties totalling a length of approx. 1200 km, with each sortie lasting about two hours. Weddell seal Leptonychotes weddellii was the most commonly sighted species in both the areas surveyed (98.2%), and had an encounter rate of 2.9 seals/km. The other species encountered during the survey were crab-eater seal Lobodon carcinophagus (1.7%) and leopard seal Hydrurga leptonyx (0.03%). Group size of hauled-out weddell seals varied considerably and ranged from solitary to maximum of 42 individuals. The median group size of weddell seals hauled-out along the Ingrid Christenson coast was found to be significantly different between the December 2009 and January 2010 survey. Further, along this Coast weddell seals were found hauled-out mainly close to the ice shelf and their spatial distribution appeared to be influenced by the extent of sea ice in the area.
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