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Scientific Reports volume 13, Article number: 5610 (2023)
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Human interventions have a great potential of spatially cornering and limiting species, therefore investigating the species distribution is one of the most crucial issues for managing wildlife populations and suggesting robust conservation strategies. Water deer (Hydropotes inermis) are widespread in China throughout history and are endemic to East Asia. However, they disappeared from Northeast China for years. We rediscovered the water deer in a previous study in Jilin Province, China. Then, we conducted further research in Northeast China to determine their distribution status, supplying fundamental data for the recovery and expansion of their population. An interview survey, line transect survey and infrared camera monitoring were carried out in some counties/cities in Northeast China from June to December 2021. The results showed that the water deer were distributed in Wuchang city of Heilongjiang Province, Changbai Korean Autonomous County, Baishan Municipal District, Ji’an city, Hunchun city, Huadian city, Antu County and Helong County of Jilin Province, Benxi Manchu Autonomous County, Huanren Manchu Autonomous County, Kuandian Manchu Autonomous County, Fengcheng city and Donggang city of Liaoning Province. The ensemble species distribution model constructed by sdm within the TSS of various models that were set as weight revealed that the potential distribution area of the water deer in the study area was 8764.66 km2 (28.77% of the study area). Combining recent studies concerning the distribution of water deer and the current study, we updated the distribution of wild water deer in Northeast China, which is vital for their conservation worldwide.
The distribution status, one of the most basic pieces of information about a species, is crucial for formulating conservation strategies for endangered species. The global species distribution pattern is shaped by multiple factors, including anthropogenic disturbance, pollution, land-use and land-cover change, overexploitation, and climate change1,2. The rapid expansion of human activities has dramatically changed environments worldwide, which has reshaped global biodiversity and caused well-documented shifts in the spatial distribution of wildlife3,4,5. In addition, global ecosystems and biodiversity are suffering from climate change, one of the most serious global environmental concerns—posing multiple threats to ecosystems and species6,7,8. The population and distribution of several animal and plant species have suffered dramatic declines and even extinction during recent decades due to ongoing climate change9,10,11,12,13,14. The distribution of species is likely to be continuously affected by the continuous expansion of human activities and increasingly frequent climate change. Therefore, it is essential to determine the current distribution pattern of species and the factors affecting their distribution.
Species distribution models (SDMs) have been widely used to predict the potential distribution (habitat suitability) of species in given areas using occurrence data of species and environmental data, particularly at large spatial and temporal scales15,16,17,18,19,20. Various software programs have been designed to construct SDMs, some of which performed well when using only presence-only datasets, e.g., BIOCLIM, DOMAIN and LIVES21,22,23. In comparison, others need both the presence and the absence data, e.g., generalized linear model (GLM) and generalized additive model (GAM)22,24. However, absence data are either difficult to obtain or very strenuous to interpret since the species database generally records only presence data15. Hence, several approaches were used to generate pseudoabsence data, e.g., selecting random points from the study area, which is the simplest and most widely used method in ecology25,26,27. Due to different performances between individual models and estimating uncertainty, ensemble SDMs have been recommended by several researchers, and they believe that their prediction accuracy is higher than that of single models15,28,29,30,31. Selecting optimal SDMs for particular species in a given area and condition is limited by many factors, e.g., species body size, environment complexity, and data resolution. Therefore, ensemble SDMs, which combine various individual models constructed with different modelling techniques, have been widely used28,32. Various packages that construct ensemble SDMs have been exploited to better predict the potential distribution of species, such as the packages biomod and sdm28,33.
Water deer (Hydropotes inermis) is a small deer endemic to East Asia. There are two subspecies of this deer: Chinese water deer (H. i. inermis Swinhoe, 1870), naturally distributed in China, and Korean water deer (H. i. argyropus Heude, 1884), naturally distributed in the Korean Peninsula34,35,36. The historical range of water deer was vast in China, including the Liaodong Peninsula, the North China Plain and the areas alongside the Yangtze River37,38. However, habitat loss and fragmentation under the pressure of climate change and anthropogenic disturbance have led to a continuous reduction in the geographical distribution area and population of wild water deer in China39. Hence, the deer was listed as a national key protected class II wildlife of China and as vulnerable (VU) globally by the International Union for Conservation of Nature (IUCN)40. The population of water deer in China was estimated at 10,000–30,000 individuals in the 1990s35. However, its population size is currently unclear, and it is mainly distributed in four regions that are isolated from each other, i.e., coastal area of Jiangsu Province, Zhoushan Islands of Zhejiang Province, Poyang Lake area of Jiangxi Province, and Dongting Lake area of Hunan and Hubei Provinces35,37,41.
Usually, it is believed that there has been no water deer population in Northeast China in recent decades42,43. However, studies on this area’s water deer (distribution included) have been extremely scarce. In 2017, we rediscovered the water deer population in the Baishan Musk Deer National Nature Reserve in Jilin Province of China44. Then, we obtained numerous reports about the distribution of water deer in Jinlin and Liaoning Provinces, and related studies were performed45,46. In addition, studies have shown that the water deer have spread to the far east of Russia, where there were historically no reports of water deer47,48. On the basis of the information we collected at present, the population of water deer in Northeast China would likely be relatively stable and healthy. However, the specific distribution and potential distribution remained unclear.
Anthropogenic disturbance and climate change have led to changes in the global environment and the distribution pattern of various habitats. In the present study, we aimed to determine the distribution pattern and potential distribution of water deer in the current environment. We carried out a field investigation in the Yalu River basin of China I to clarify the distribution of water deer in Northeast China, II to update the distribution ranges of water deer in China, combined with the current study and other studies concerning the distribution of this ungulate, and III to predict the potential distribution of water deer in the study area using the occurrence data of the deer in the current study and the environmental data. We believe that the current study could supply fundamental information for the distribution of water deer in Northeast China and even the world, which is crucial for conservation and further research on this vulnerable ungulate.
Based on previous studies, interviews, and news reports, the study areas included some counties/cities of the Yalu River basin of China (the area is ~ 30,464.58 km2, Fig. 1), where the water deer were distributed throughout history. The study areas included Changbai Korean Autonomous County, Baishan Municipal District, Ji’an city in Jilin Province, Benxi Manchu Autonomous County, Huanren Manchu Autonomous County, Kuandian Manchu Autonomous County and Fengcheng city of Dandong city in Liaoning Province (Fig. 1). The geographical coordinates of the study area are E120°0′ to E123°35′, N39°59′ to N42°11′, with a north–south span of ~ 260 km and a west–east span of ~ 420 km. Baishan city belongs to the northern temperate continental monsoon climate and is the coldest area in Jilin Province. The annual average temperature is 4.6 °C, and the annual average precipitation is 883.4 mm. Dandong city has a warm temperate humid, monsoon climate; its annual average rainfall is from 800 to 1200 mm, and its annual average temperature is from 6 to 9 °C. The study area is located on the north and northwest banks of the Yalu River. The northeastern part of the study area has a relatively higher elevation, whereas the southwestern part of the area has a relatively lower elevation. Changbai Mountain is the highest part of the region, and its main peak, viz. Baiyun Peak, has an elevation of 2691 m49. In addition to water deer, other notable species inhabit the study area, such as Siberian musk deer (Moschus moschiferus), roe deer (Capreolus pygargus), black bear (Ursus thibetanus), and Eurasian lynx (Lynx lynx). The study area is rich in vegetation resources and diverse habitat types, including broad-leaved forest, mixed coniferous and broad-leaved forest, coniferous forest, shrub, and grassland. The study area has a developed water system adjacent to the Yalu River and several tributaries of the Yalu River, such as the Hun River, Ai River, and Cao River.
The map of the study area generated with ArcGIS 10.7 (Environmental Systems Research Institute, Inc. in Redlands, California, USA). The different colors represent different elevation of the study area, and the digital elevation model (DEM) was downloaded at https://www.gscloud.cn/.
The presence and absence data of water deer were collected by interview survey, random line transect survey and camera traps (Ltl 6210 MC from Ltl Acorn Electronics Co., Ltd.) monitoring. Based on the results of these investigations, the absence points of water deer were carefully selected in combination with the home range and daily activity rhythm of them. The absence points of the deer were selected from the line transects in which no individuals or their marks were found. In addition, the infrared camera locations that never captured photos/videos of the species were recorded as absence points. Certainly, these absence points were far from the known distribution of the deer, and their habitat characteristics were significantly different. The performance of some SDMs is relatively high when only the presence data of a species are available21,22,23, or they can generate pseudoabsence data using several approaches before prediction to obtain good performance25,26,27. However, these pseudoabsence data are generated based on the presence data and environment data50,51,52, which is just a principle of SDMs, and they may not be the real absence point of the species. In addition, literature or interview surveys were conducted to collect the distribution data of the deer in China, Russia, North Korea, and South Korea.
We know that it is risky for us to use the absence points identified by us in the current study because these points may not truly lack water deer. We believe that it may be more credible than the absence data generated by models, and its characteristics may be closer to those of the habitats where the water deer are not distributed. We obtained 1296 presence points and 158 absence points for water deer from the line transect survey and infrared camera monitoring. Since the body size of water deer is smaller than that of red deer (Cervus canadensis) and other large deer, the home range of water deer is relatively small, and there is high spatial overlap among individuals53,54. Hence, the presence/absence points with a distance of less than 500 m were excluded to avoid pseudoreplication. Finally, we obtained 156 presence points and 54 absence points for water deer. The presence/absence points were stored as a .shp file in ArcGIS 10.7 for further analysis.
Based on previous research on water deer and other deer species and habitat studies on similar species45,54,55, the bioclimate factors (bio_1: annual mean temperature, bio_5: max temperature of the warmest month, bio_6: min temperature of the coldest month, bio_12: annual precipitation, http://www.worldclim.org/), topographical factors (elevation, slope, slope direction, https://www.gscloud.cn/), distance to the water source (National Catalogue Service for Geographic Information, https://www.webmap.cn/), vegetation factors (normalized difference vegetation index (NDVI), https://www.gscloud.cn/), and human disturbance factors (distance to road, national basic geographic information of China, http://www.ngcc.cn/) were selected to construct SDMs (Table 1). The coordinates, geographical spatial scope, and raster size of various factors were unified and stored as an .asc file using ArcGIS 10.7 for further analysis.
The sdm package in R was used to construct the SDMs33. First, the VIF (variance inflation factor) function of the usdm package was used to calculate the VIF of various factors, and the factors with a VIF value larger than 10 were excluded (Table 1)56,57. Bio_1, bio_5, and bio_6 were excluded. The rest of the factors were used to test the performance of various models, which were evaluated by the true skill statistic (TSS) and the area under the curve (AUC) of the receiver operating characteristic curve (ROC)58. Finally, boosted regression trees (brt), classification and regression trees (cart), multivariate adaptive regression splines (mars), random forest (rf), and support vector machine (svm) were selected33. We randomly assigned 70% of the dataset as the training dataset, and model performance was tested with the remaining 30%. The models were run for 30 replicates using a bootstrap method. Then, the ensemble function in the sdm package was used to construct ensemble SDMs within the TSS of various models that were set as weight33. The average TSS from the 30 replicates of the models was set as the threshold to derive presence-absence distributions from the continuous model outputs of habitat suitability55,59,60. Every output cell was categorized as either present (above the cut-off) or absent (below the cut-off) in ArcGIS 10.7, and we obtained the potential distribution of the water deer. Since the reliability or amount of the presence data we obtained in Russia and the Korean Peninsula was relatively lower than that in China, we predicted only the potential distribution of water deer in Northeast China.
The line transects survey and infrared camera monitoring showed that water deer are distributed in Changbai Korean Autonomous County, Baishan Municipal District, and Ji’an city of Jilin Province, whereas its distribution range is relatively larger in Kuandian Manchu Autonomous County, Huanren Manchu Autonomous County, and Fengcheng city of Liaoning Province. Particularly, there is a wide distribution range of water deer in Kuandian Manchu Autonomous County, which account for almost 3/4 of the county. In addition, interview surveys and news reports indicated that water deer are distributed in Wuchang city of Heilongjiang Province; Hunchun city, Huadian city, Antu County and Helong County of Jilin Province; and Benxi Manchu Autonomous County, Donggang city of Liaoning Province (Figs. 2, 3).
The distribution status of water deer in Northeast China based on our field surveys and interview. The circular points come from line transects survey and infrared camera monitoring, the triangular points come from interview. This map was generated with ArcGIS 10.7 (Environmental Systems Research Institute, Inc. in Redlands, California, USA. URL: https://www.esri.com/en-us/arcgis/products/arcgis-desktop/overview).
Photos of water deer captured by the infrared camera. (a) Photo of female water deer captured in summer. (b) Photo of male water deer captured in winter.
We rediscovered the distribution of water deer in Jilin Province of China in 201744. Darman et al. (2019) first discovered the water deer distribution in the Khasansky district of Primorsky Province, Russia47,48. Then, Dmitry et al. discovered the distribution of water deer in Mikhailovskiy district, Russia, which was thought to be the northernmost distribution of water deer in the world61. Combined with our previous and related recent studies concerning water deer34,40,44,47,48,61,62,63,64, we believe that it is meaningful and essential to update the distribution range of water deer. Therefore, according to recent studies, we generated a new distribution map for water deer, in which Northeast China, Russia, and the Korean Peninsula were included (Fig. 4).
The distribution status of water deer in Northeast China and its surrounding areas. The blue points reflects the distribution of water deer in the south China which performed in 200662. The orange and green points reflect their distribution in Northeast China in current study. The purple points reflects their distribution in Russia47,48. The black points is the distribution of water deer based on Li et al.64. The blue areas is their distribution based on IUCN40. The orange areas with diagonal reflects their current distribution in the Korean Peninsula34. This map was generated with ArcGIS 10.7 (Environmental Systems Research Institute, Inc. in Redlands, California, USA. URL: https://www.esri.com/en-us/arcgis/products/arcgis-desktop/overview).
All of the AUC values of various models were at least 0.84 (lowest: AUC of cart = 0.84, highest: AUC of rf = 0.95) (Table 2). The relative variable importance of the NDVI (n = 23.90%) was highest among the various factors, followed by that of elevation (n = 20.40%) and bio_12 (n = 13.00%) (Table 3). The average TSS of 30 replicates of the five models was 0.701. This threshold was used to categorize the continuous outputs of habitat suitability from ensemble SDMs as presence/absence data.
The results revealed that the whole potential distribution area of water deer in the study area was 8764.66 km2 (28.77%). Its potential distribution area was largest in Kuandian Manchu Autonomous County, reaching 3078.46 km2 (49.23%). In contrast, it was the smallest in Changbai Korean Autonomous County, with only 494.80 km2 (19.83%) (Fig. 5, Table 4).
Potential distribution map of water deer generated by the ensemble SDMs and the range of nature reserves (orange areas with diagonal) in Northeast China. The purple points are the presence location of water deer, and the blue points are the absence location of the deer which was defined by current study. This map was generated with ArcGIS 10.7 (Environmental Systems Research Institute, Inc. in Redlands, California, USA. URL: https://www.esri.com/en-us/arcgis/products/arcgis-desktop/overview).
In the current study, a line transects survey, infrared camera monitoring, an interview survey, and a literature survey were employed. The results showed that the water deer were distributed in several counties/cities of the Yalu River basin of China. The distribution range of water deer in Northeast China was vaster than previously thought47,48,61. In addition, combining our results with related research on the deer, we updated the distribution range of its natural population in China, which may indicate its global distribution should be updated. Water deer presence/absence data in Northeast China were employed to predict its potential distribution. There was a considerable potential distribution of the deer in the study area, which is a crucial area for further conservation and study in China. It should be noted that the potential distribution range of water deer in various counties/cities was different.
Throughout history, the distribution of water deer in China was vast, and its range reached from N45°42′ (Harbin, Heilongjiang) to N18°24′ (Lingshui, Hainan) and from E97°6′′ (Changdu, Tibet) to 122°24′ (Shengsi, Zhejiang). However, in the 1980s, its distribution shrank from N34°6′ (Shuyang, Jiangsu) to N21°30′ (Dianbai, Guangdong) and east of E107°6′ (Tian’e, Guangxi)62. The population decline in China in the past ten thousand years was due to the decrease in its living space caused by climate change, agricultural production, human disturbance, and a decline of shallows65,66,67,68,69. Moreover, the extreme decline in water deer in recent decades was caused by habitat degradation, habitat loss, and overhunting, particularly in the south of the Yangtze River70,71,72,73. Then, the water deer was introduced to England, and the escaped individuals formed a wild population74,75, which accounts for more than 40% of the wild population in the world76. Previous research indicated that the population of water deer in England could supply support for the population recovery of the deer in China77. Our study suggested that the distribution and population size of water deer in Northeast China are relatively large, and there may be no need to introduce the species from other places to recover the population. Fortunately, due to the Chinese government’s strict conservation efforts and policies, many forests in China have been recovering in recent decades78, which provides a foundation for the population recovery of water deer.
In recent years, water deer have spread and ranged in Russia’s far east, forming healthy and stable populations47,48,61. The spread of the deer may be caused by habitat transformation under the effects of anthropogenic disturbance and climate change. In the most recent years, two studies focused on the distribution, habitat suitability, and dispersal routes of water deer among Northeast China, the far east of Russia, and the Korean Peninsula, while both were relatively lacking in the ranges of field investigation64,79. Their field investigation was lacking in Liaoning Province, China, where our results revealed that the distribution of the deer was vastest. Their habitat suitability of the deer in their study area was almost opposite79, which may be caused by their lack of occurrence data of the species in Liaoning. Hence, the possible dispersal routes of water deer obtained by them did not match the distribution pattern in our study79, which demonstrated the importance of obtaining adequate presence data and updating the distribution of the species in a comprehensive study on them.
The AUC in multiple replicates of the ensemble SDMs was relatively high (from 0.84 to 0.95), revealing that the simulated potential distribution of water deer in Northeast China is reliable, which has important guiding significance for the future conservation area designation of the species. The potential distribution area of the water deer was relatively scattered (Fig. 5), making it difficult to spread and communicate among the populations in the future. On the one hand, this may be caused by the difference in altitude and vegetation types of various habitat patches in the study area since the NDVI and elevation are crucial for the habitat of water deer (Table 3). On the other hand, roads in the study area have contributed to the dispersion of potential distribution areas of water deer to a certain extent. Based on observations in our fieldwork, many traces of water deer were found in areas close to roads or residents. Roads pose potential threats to their lives, as water deer roaming or spreading across roads are more likely to be struck and killed by cars. In South Korea, roadkill is an important factor leading to the death of water deer80,81. During our interviews, we also learned that there were many roadkills of water deer in Northeast China.
A total of 50.52% of the total occurrence points were collected from Kuandian Manchu Autonomous County, reflecting a large water deer population in this area. Therefore, Kuandian Manchu Autonomous County may be the most important region to maintain the stability of the water deer population in Northeast China. The ensemble SDMs revealed an enormous potential distribution of water deer in the study area (8764.66 km2, 28.77%, Fig. 5, Table 4). Among them, the area of the potential distribution area and the proportion of the total potential distribution area in Kuandian Manchu Autonomous County were the largest (3078.46 km2, 35.12%, Fig. 5, Table 4). However, the potential distribution area of water deer in protected areas in the study area was deficient (Fig. 5). Moreover, there were no protected areas in the main potential distribution area of the species, let alone the protected area specializing in the conservation of water deer (Fig. 5). Protected area with a distribution of water deer is scarce in China54,82,83. Protected areas are considered the cornerstones of biodiversity conservation84,85,86. According to the habitat characteristics of water deer, key conservation efforts should be carried out in their potential distribution as soon as possible. In other words, establishing a special reserve to protect the deer population in Northeast China is very important and necessary.
The relative variable importance of the NDVI (23.90%) was highest among various factors, reflecting an essential role of vegetation in the habitat of water deer. The occurrence points of the deer were found in the habitats of grass/shrub most frequently, which possess relatively good vegetation conditions and could supply favourable shelter as well as adequate/palatable food for them, and it is similar to the studies on the species in both Northeast and South China45,54,82. Water deer prefer grass/shrub habitats with relatively high hiding levels and good vegetation cover45,54. Hence, they also prefer cropland. Moreover, the deer have caused certain damage to local crops. Fabaceae account for a high proportion of the food of water deer63, and we found that they consumed a large amount of soybean (Glycine max) leaves in the cropland. In addition, the leaves of sweet potato (Ipomoea batatas) are their favourite food, and they even dig sweet potato out with their hooves. All of these croplands were close to settlements or roads, suggesting that the deer may not be afraid of humans. The relative variable importance of distance to the road (6.30%) was relatively lower than that of the other three factors, which could also prove this to some extent (Table 3).
Following the NDVI, the relative variable importance of elevation ranked second with a proportion of 20.40%. The elevation affected the distribution of different plant species in our study area. There were more grass/shrub species distributed in places with lower elevations, whereas there were more tree species distributed in places with higher elevations. Since elevation is important for the habitat selection of water deer45 and its relation with the distribution of plants, we summarized the typical habitats of the deer in Northeast China: 1 grassland/cropland habitat: grassland with a slope of less than 30° in the middle and low slopes and cropland of soybean, sweet potato, peanut (Arachis hypogaea), and corn (Zea mays); 2 shrub/orchard habitat: shrubs with a slope of less than 30° in the middle and low slopes and orchards of filbert (Corylus spp.), Pinus koraiensis sapling, and fruits; and 3 larch (Larix gmelinii) habitats: larch forest habitat with a slope of less than 30° and a canopy closure not higher than 80% in the middle and upper slopes. There are a few herbs/shrubs under the forest, the forest area is not large, and there are overlapping areas with grassland/shrub habitats. This summary of the habitat of water deer may supply guidance for conservation and future research. This summary is just our speculation and requires a future careful comparison. We will record detailed information on the habitat characteristics in different counties/cities in future studies, aiming to compare their habitat among areas and summarize their habitat with sufficient data.
The current study could not determine whether the water deer in Northeast China were remaining populations or whether they spread from the Korean Peninsula. Further study on the cross-border activity pattern and movement corridors of water deer between China and the Korean Peninsula may help to solve this issue. We know that Chinese water deer and Korean water deer are naturally distributed in China and the Korean Peninsula, respectively34,35,36. However, recent research has shown that there are two subspecies of water deer in South Korea87; therefore, the subspecies belonging to the water deer in Northeast China could not be used to distinguish whether they were local populations or whether they spread from the Korean Peninsula. However, the subspecies of the deer in Northeast China remains unclear and needs more research in the future.
We believe there may have been populations of water deer in Northeast China for a long time, and perhaps they never disappeared, but related research is lacking. On the one hand, the lack of research on this species may be due to its relatively lower economic value than that of sika deer (Cervus nippon)88,89. In addition, the mammals in our study area other than the water deer are musk deer (Moschus spp.), black bears, etc., which are more endangered or have a larger influence on humans, so there is more research on them55,90. Hence, little is known about the distribution and population status of water deer in Northeast China in recent years45. On the other hand, the locals could mistake the water deer for musk deer or roe deer because their body size and fur colour are similar41,91. In our investigation, if we showed a photo of water deer to locals, they were pretty sure that the species they saw was water deer, but they still called it “musk deer” or “roe deer”. In addition, the spread of water deer from the Korean Peninsula has occurred79. When the Yalu River freezes in winter, water deer can easily spread from North Korea to China over the ice, which locals have witnessed many times. Moreover, water deer are skilled in swimming; their swimming distance can be 2 kms or more. In the Zhoushan Archipelago of China, water deer always spread by swimming among islands53,73,92,93. In summary, we believe that the deer in Northeast China may have always been, and at the same time, the species may have also spread from the Korean Peninsula to China through the Yalu River.
In the current study, we investigated the distribution of water deer in Northeast China and found a large distribution and population of the species alongside the Yalu River in China. We updated the distribution map of water deer in Northeast China and its surrounding areas, reflecting the distribution range of the species in Russia, the Korean Peninsula, and China. Finally, we predicted the potential water deer distribution in Northeast China. The results showed a large potential distribution area of the species in the study area, which is a good foundation for their population recovery.
The raw data supporting the conclusions of this article are stored in College of Wildlife and Protected Areas, Northeast Forestry University and it will be made available by the corresponding author without undue reservation.
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We thank the assistance supplied by the Hongshi Forestry Bureau, Helong Forestry Bureau, Changbai Forest Management Bureau, Linjiang Forestry Bureau, Baishan Forestry Bureau, Ji’an Forestry Bureau, Benxi Forestry Development Service Center, Kuandian Manchu Autonomous County Forestry and Grassland Bureau, and Fengcheng forestry and grassland Bureau.
This research was supported by “National Natural Science Foundation of China” (Grant nos. 32071649, 31870512). “Key Research and Development Program of Ningxia Hui autonomous region” (Grant no. 2020BEG02001). “Fundamental Research Funds for the Central Universities, China” (Grant nos. 2572021AW03, 2572021AW05).
College of Wildlife and Protected Areas, Northeast Forestry University, Harbin, 150040, China
Zongzhi Li, Romaan Hayat Khattak, Xingzhi Han, Nan Zhang, Jianping Wu, Zhensheng Liu & Liwei Teng
Key Laboratory of Conservation Biology, National Forestry and Grassland Administration, Harbin, 150040, China
Zhensheng Liu & Liwei Teng
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L.Z.Z., L.Z.S., W.J.P. and T.L.W. conceived the ideas and designed the study and its methods, L.Z.Z. and L.Z.S. performed data analyses, prepared figures and tables, and wrote the manuscript, L.Z.Z., L.Z.S., Z.N. and H.X.Z. conducted the fieldwork and data collection, R.H.K., H.X.Z., L.Z.S., and T.L.W. interpreted the results and edited the manuscript to its final submitted draft. All authors contributed to the article and approved the submitted version.
Correspondence to Zhensheng Liu or Liwei Teng.
The authors declare no competing interests.
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Li, Z., Khattak, R.H., Han, X. et al. Distribution update of water deer (Hydropotes inermis) and prediction of their potential distribution in Northeast China. Sci Rep 13, 5610 (2023). https://doi.org/10.1038/s41598-023-32314-z
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