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Article

Study on Terrestrial Wild Vertebrate Diversity and Geographical Fauna in Qinghai Area of Qilian Mountain National Park, China

1
School of Geographical Science, Qinghai Normal University, Xining 810008, China
2
Academy of Plateau Science and Sustainability, People’s Government of Qinghai Province, Beijing Normal University, Xining 810016, China
3
Key Laboratory of Tibetan Plateau Land Surface Processes and Ecological Conservation (Ministry of Education), Qinghai Normal University, Xining 810008, China
4
Qinghai Province Key Laboratory of Physical Geography and Environmental Process, Xining 810008, China
*
Author to whom correspondence should be addressed.
Sustainability 2022, 14(24), 16452; https://doi.org/10.3390/su142416452
Submission received: 21 October 2022 / Revised: 5 December 2022 / Accepted: 6 December 2022 / Published: 8 December 2022

Abstract

:
To gain an in-depth understanding of the resource status of terrestrial wild vertebrates in the Qinghai Area of Qilian Mountain National Park, a total of 10 field surveys were conducted in the reserve from May 2019 to May 2022, and the diversity and geographical fauna of terrestrial wild vertebrates in the study area were studied combined with literature. The results show that in the Qinghai Area of the Qilian Mountain National Park, there are 265 species of terrestrial vertebrates in 4 classes, 30 orders, 71 families and 167 genera. Among them, Amphibia has 1 order, 2 families, 2 genera and 3 species; Reptilia has 2 orders, 4 families, 5 genera and 5 species; Aves has 21 orders, 51 families, 131 genera and 214 species; Mammalia has 6 orders, 15 families, 29 genera and 43 species. The composition of terrestrial wild vertebrate species in the study area shows that Aves account for 80.75%, Mammalia account for 16.23%; Reptilia account for 1.89% and Amphibia account for only 1.13%. The geographical fauna is dominated by Cosmopolitan species (218), followed by Palaearctic species (48) and a few Oriental species (3). Data from the G-F analysis shows that birds are more diverse at both family and genus levels, followed by mammals, with amphibians lower and reptiles lowest.

1. Introduction

Biodiversity is inseparable from human life and is one of the conditions for the sustainable development of human society. Biodiversity is the material basis for human survival and plays a vital role in maintaining the stability and functionality of ecosystems. The terrestrial vertebrates are an important component of biodiversity.
China is one of the richest countries in the world in terms of biodiversity, with 3232 species of terrestrial vertebrates, including 687 species of mammals, 1445 species of birds, 548 species of amphibians and 552 species of reptiles [1,2]. In recent years, vertebrates are under great threat of extinction around the world, due mainly to exotic species, conversion, degradation and fragmentation of habitats, climate change, over-exploitation and pollution caused by anthropogenic activities [3,4,5,6,7]. Studies on “terrestrial vertebrate diversity” have focused on the biodiversity and geographical fauna of terrestrial wild vertebrates in different areas [8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35] (see Appendix A Table A1) and the impact of human activities on terrestrial wild vertebrates [36,37]. In addition, based on the research on terrestrial wild vertebrate biodiversity and fauna, scholars have also studied the conservation measures, conservation policies to terrestrial wild vertebrates and utilization of wildlife-related resources [38,39,40], and constructed an index system for evaluating the effectiveness of conservation in national nature reserves [41]. Therefore, it is an important task for China’s wildlife diversity conservation research to identify the number, distribution, population dynamics, habitat and its conservation and utilization status of each species, and to recognize the objective factors that affect and endanger the survival and development of wildlife.
Qilian Mountain National Park is located at the southeast edge of the Qinghai–Tibet Plateau, known as the “Third Pole”. As one of the first ten national parks in China, Qilian Mountain National Park aims to protect the integrity and authenticity of regional biodiversity and natural ecosystems and is China’s major ecological function area, as well as an important ecological security barrier and a water-conserving area in western China. The Park is rich in animal resources and unique in species, where the unique geographical location and the complex and diverse ecosystem environment have nurtured relatively rich biological resources. At present, the only related studies on terrestrial wild vertebrates in Qilian Mountain National Park are those on terrestrial wild vertebrate diversity and geographical fauna in Tianzhu County, the Gansu Area of this Park. As an important part of Qilian Mountains National Park, The Qinghai Area accounts for 31.5% of the total area of the Park. Studying the terrestrial wild vertebrate diversity and geographical fauna in this area will not only acquire the basic data of wildlife resources in the Park and improve the animal data of the reserve, but also provide some reference point for biodiversity conservation in the area.

2. Materials and Methods

2.1. The Study Area

Qilian Mountain National Park is located on the northeastern edge of the Qinghai-Tibet Plateau (see Figure 1), it is located in the northern foot of the Qilian Mountain, which is the intersection of the three major plateaus of Qinghai-Tibet, Mengxin and Loess. It is situated in an alpine zone with a continental plateau climate, strong solar radiation, large temperature differences between day and night, and significant vertical changes in temperature and precipitation. The Park covers a total area of 50,200 square kilometers and is divided into 2 areas, Gansu and Qinghai, of which the Qinghai Area has a total area of 15,800 square kilometers, accounting for 31.5% of the total area, including Menyuan County and Qilian County in Haibei Tibetan Autonomous Prefecture, Qinghai Province, and Tianjun County and Delingha City in Haixi Prefecture. Qilian Mountain National Park Qinghai Area has a unique ecosystem and diverse natural landscape, with an average altitude of 4000~5000 m, extensive glacial cover, making it an important “solid reservoir” in the northeastern part of the Qinghai-Tibet Plateau [42], and is the Source of Heihe River, Shule River, Shiyang River and Datong River.

2.2. Data Sources and Processing

Field survey was used as well as a combination of long-term monitoring data from the study area and historical documentation such as scientific expedition collections. Field surveys of the species and numbers of inland wild vertebrates in the reserve were conducted based on vegetation types, topography and landform and distribution of each animal taxon, and geographical information such as topography, landform, elevation and habitat of the survey area were recorded.
Ten surveys were conducted in May, July and October each year from 2019 to 2021 and in May 2022 in the Qinghai Area of Qilian Mountain National Park. The sample line method and infrared camera monitoring method were mainly used to survey the terrestrial wild vertebrates distributed in the area. Due to the influence of climate and topography, the sample line method was mainly used to survey the eastern part of the park, while the infrared camera monitoring method was mainly used in the western part of the park. In addition to field surveys, visits to farmers, foresters and herders to understand the changes in local animal resources and their current status were conducted as a supplement.

2.2.1. Sample Line Method

In the sample line survey, the sample line length was set at least 3 km, the survey time was 8:00–20:00 every day, and the walking speed of the investigators was 1–1.5 km/h. 40 sample lines were laid out, taking into account these issues of functional area, vegetation type, elevation gradient, and frequency of animal occurrence. (see Figure 2).

2.2.2. Infrared Camera Monitoring Method

A total of 70 infrared cameras (LTL-6210 PLUS) were deployed in the park (see Figure 2). In order to improve the efficiency of the infrared cameras, three principles were followed in the selection and deployment of the sites: (1) As far as possible, the sites with more animal tracks, scat, food traces, markers and other activity traces were selected or the animal trails with abundant food and close to water sources. (2) Infrared camera fixed at 50–100 cm from the ground on the trunk of the camera lens to maintain a horizontal or slightly downward, as far as possible to avoid direct sunlight. (3) The distance between adjacent sites should be greater than 500 m. At the same time, the number, date of placement, latitude, longitude, elevation and vegetation type of each camera should be recorded. Infrared cameras are replaced with batteries and memory cards every 2–3 months, and lost cameras are maintained and replenished in a timely manner. The working time of the infrared camera is set to 24 h, and each time the trigger takes three consecutive photos with 1 video of 10–15 s to form 1 group of photos, and the trigger interval is 30 s.

2.3. Species Identification Methods

Species were identified and systematically classified according to the Vertebrate Species and Distribution in Qinghai [43], Qinghai Economic Zoology [44], A Guide to the Mammals of China [45], Catalogue of mammals in China (2021) [46], The Updated Checklists of Amphibians and Reptiles of China [47], A Field Guide to the Birds of China [48], A Checklist on the Classification and Distribution of Birds in China (Third Edition) [49]. Rare species were identified with reference to the List of National Key Protected Wildlife [50] and the Red List of Chinese Vertebrates [51], and species were classified by geographical fauna and distribution type according to the Zoogeography of China [52].

2.4. Research Methods

The G-F index formula [53] was used to calculate the diversity of terrestrial wild vertebrates in the reserve for the aggregated terrestrial wild vertebrate list.
(1)
F-index (diversity of families).
D F = k = 1 m D F K
D F K is the species diversity in family k, calculated as
D F K = i = 1 n p i ln p i
In the formula, P i is the ratio of the number of species in genus i of family k to the total number of species in family k in mammals, n is the number of genera in family k, and m is the number of families in mammals.
(2)
G index (diversity of genera):
D G = j = 1 p q j ln q j
q j is the ratio of the number of species in genus j to the total number of species in an order, and p is the number of genera in an order.
(3)
G-F index:
D G F = 1 D G D F

3. Results

3.1. Species Composition

The survey results showed that there were 265 species of terrestrial wild vertebrates in 4 classes, 30 orders, 71 families and 167 genera in the study area, accounting for 64.4% of the number of terrestrial wild vertebrate species (418 species) in Qinghai Province (see Appendix A Table A2).
There were 214 species of birds in 21 orders, 51 families and 131 genera in the study area, accounting for 80.75% of the total number of species. The birds of the order Passeriformes (95 species) were absolutely dominant with 44.39% of the total species number. This was followed by Charadriiformes (23 species), with the proportion of 10.75%, Falconiformes (20 species) and Anseriformes (20 species), each accounting for 9.35%.
There were 43 species of mammals in 6 orders, 15 families and 29 genera in the study area, accounting for 16.23% of the total number of species. The largest number of species of carnivores (16 species) accounted for 37.21% of the total number of species, followed by Artiodactyla (9 species) at 20.93%, Lagomorpha (8 species) at 18.6%, and Rodentia (7 species) at 16.28%. The least common species was Perissodactyla, only the Equus kiang.
There were 5 species of Reptilia in 2 orders, 4 families, 5 genera in the study area, accounting for 1.89% of the total number of species. They were Eremias multiocellata, Phrynocephalus vlangalii, Rhabdophis tigrinus, Elaphe dione, Gloydius cognatus, etc.
There were 3 species of Amphibia in only 1 order, 2 families, 2 genera in the study area, accounting for 1.13% of the total number of species, and all of them were Anura, namely, Rana kukunoris, Bufo gargarizans minshanicus and Bufo gargarizans.
There were 98 species of terrestrial vertebrates found by the sample line method, including four species of mammals, three species of reptiles, and 91 species of birds. 35 species of terrestrial vertebrates were found by the infrared camera monitoring method, including 20 species of mammals and 15 species of birds. 132 species of terrestrial vertebrates were found by searching published books [43,44] and press reports. (see Table A2)
Figure 3 records the distribution of species found by the sample line method and the infrared camera monitoring method within the park. The amphibians were discovered by reviewing the literature and we presume that they are mainly distributed near rivers and lakes, so we provide maps of the distribution of rivers and lakes in the Park (see Figure 3).

3.2. Rare and Endangered Species Composition of the Reserve

According to the newly released National List of Key Protection Wildlife, there are 77 species of national key protection wildlife in the reserve, accounting for 29% of the number of wildlife species in the reserve. Among them, there are 20 species of China‘s national first-class key protected wild animals, with 13 species of birds and 7 species of mammals; 57 species of China‘s national second-class key protected wild animals, with 43 species of birds and 14 species of mammals (see Table A2); China‘s national first-class and second-class protected animals account for 7.6% and 16% of the vertebrate species in the reserve.
In addition, there are 55 threatened species listed in the Red List of Chinese Vertebrates, accounting for 20.75% of the number of wildlife species in the reserve. One species, Felis bieti, is classified as Critically Endangered (CR). Ten species are classified as Endangered (EN), including 4 species of birds and 6 species of mammals, including Falco cherrug, Haliaeetus leucoryphus, Aquila heliaca, Pelecanus onocrotalus, Cervus elaphus, Cervus albirostris, Lynx lynx, Felis manul, Panthera uncia and Martes foina. Thirteen species are classified as Vulnerable (VU), including 9 species of birds and 4 species of mammals. Meanwhile, there are also 16 species of wildlife listed as Near Threatened (LC), including 15 species of birds and 1 species of mammals (see Table A2).

3.3. Geographical Fauna Features

The number of Cosmopolitan species (214 species) was absolutely dominant, accounting for 80.75% of the total number of species, followed by the Palaearctic (48 species), accounting for 18.11%, and the Oriental species (3 species), accounting for 1.13% of the least number of species. Among them, the number of species in Cosmopolitan species: Aves > Mammalia > Amphibian = Reptilia; the number of species in Palaearctic species: Aves > Mammalia > Reptilia > Amphibian; the number of species in Oriental species: Aves > Mammalia, with no distribution in Amphibian and Reptilia (see Table 1).

3.4. Distribution Type

In terms of species distribution type, Palaearctic type (U) accounted for 22.64%, followed by Highland type (P) accounting for 20%, Palaearctic & Nearctic type (C) and south China type (O) accounting for 15.09% and 14.34%, Central Asian type (D), Himalayan-Transverse mountain type (H) and Oriental type (W) accounting for 8.68%, 7.17% and 5.28%, and the remaining Northeastern type (M), Monsoon type (E), North China type (B), Northeast-North China type (X), Not-easily-categorized type (S) and Local type (L) all accounted for less than 5%. Mammalia occupied 11 distribution types, among which Palaearctic and Highland types were dominant, with no Northeast type; Aves occupied 11 distribution types, among which Palaearctic and Himalayan-Transverse type were dominant, with no North China type; Reptilia had Palaearctic & Nearctic type (1 species), Monsoon type (1 species) and Himalayan-Transverse type (1 species); Amphibia occupied 4 distribution types and were more evenly distributed (see Table 2).

3.5. G-F Index Features

The data show that in terms of the number of orders, families, genera, species, G-index and F-index: Aves > Mammalia > Reptilia > Amphibian, which shows that birds in the reserve have the highest species diversity and are richer in both families and genera; in terms of G-F index: Aves >Mammalia >Amphibian > Reptilia, which shows that birds and mammals have higher species diversity than the other two groups, while reptiles have the lowest species diversity level with negative values (see Table 3).

4. Discussion

In this study, a total of 265 species of terrestrial wild vertebrates in Qinghai Area of Qilian Mountain National Park were recorded and collated, including 4 classes, 30 orders, 71 families, 167 genera. Among them, there are 21 orders, 51 families, 131 genera, 214 species of birds, 6 orders, 15 families, 29 genera, 43 species of mammals, 2 orders, 4 families, 5 genera, 5 species of reptiles, and only 1 order, 2 families, 2 genera, 3 species of amphibians. Rare and endemic species and their distribution forms are important indicators of the biodiversity of an area [54,55]. Protected species in the study area accounted for 29.06% of the total species, and the discovery of numerous protected animals proves that the conservation measures of the reserve have achieved a certain degree of success.
There are 214 species of Aves in the study area. The area is rich in rivers and water resources, and the fish, invertebrates and aquatic plants in rivers and wetlands provide abundant food for birds. Among them, the Passeriformes (95 species) occupy an absolute advantage with 44.39% proportion, indicating that medium and small finches are highly adaptable and can radiate into various ecological environments, becoming the dominant bird species in the reserve. There are 43 species of Mammalia, whose species composition, geographical fauna composition and distribution characteristics are related to the geographical location of the reserve. The Park has high vegetation cover, diverse habitat types and vast grasslands, resulting in a high number of species of Artiodactyla, Lagomorpha and Rodentia, while species of Carnivora, which feed on the above-mentioned orders, are predominant. The small number of amphibian and reptilian species is probably due to the geographical location of the park. Amphibia and Reptilia cannot migrate long distances due to their morphological and functional characteristics, and their habitats are relatively fixed, especially for Amphibians, which cannot breed without a water environment, while the Park has a series of high mountains running northwest to southeast, with an average altitude of about 4000 m, which, to large extent, limits the penetration of Amphibia and Reptilia species from other areas, and the Park is located in the alpine zone with an alpine climate unsuitable for the breeding and survival of Amphibia and Reptilia. Consequently, the level of species diversity of Amphibia and Reptilia is not high.
Wildlife, through long-term evolution, will interact with the regional habitats they live in and adapt to each other, so that wild animals with the same distribution range and same distribution environment have the same geographical fauna characteristics [17]. The size of the range of a wildlife is closely related to the extent to which it is adapted to its environment. The migratory nature of wildlife can lead to a complex regional geographical fauna, mostly characterized by a cross-fertilization of different distribution types and zones. In terms of geographical fauna distribution types, the Park is dominated by Palaearctic type, Highland type, Palaearctic & Nearctic type and South China type, with Central Asian type, Himalayan-Transverse Mountain type and Oriental types occupying a certain proportion, and a smaller number of Northeast type, Monsoon type, North China type, Northeast-North China type, Not-easily-categorized type and local type. The multi-distribution pattern is probably related to the typical plateau geographical features of the Park. The Park is the source of inland rivers such as the Shule River, with good habitat quality, and has the highest peak in the Qilian Mountain, Tuanjie Feng, with relatively undulating areas on the north and south sides and east part of the mountain, and a part of this area is close to no man’s land, and benefits from religious influence, which is a “paradise” for wildlife.

5. Conclusions

In the Qinghai Area of Qilian Mountain National Park, there are 265 species of terrestrial wild vertebrates in 4 classes, 30 orders, 71 families and 167 genera. 98 species were identified by the sample line method,35 species were identified by the infrared camera monitoring method. The species geographical fauna is dominated by the following types: Palaearctic and Highland types, with more species of Palaearctic & Nearctic type and south China type, and a certain pro-portion of Central Asian type, Himalayan-Transverse Mountains type, Oriental type and Northeast China type. But the number of species of these types are smaller: monsoon type, North China type, Northeast-North China type, Not-easily-categorized type and local type. The G-F index indicates high levels of species diversity in birds and mammals and low levels in amphibians and reptiles.

Author Contributions

Conceptualization, methodology, formal analysis, writing—original draft preparation: S.X.; investigation, data curation, validation, visualization: H.M.; writing—review and editing: J.X.; investigation, data curation, software: F.W.; resources, supervision, project administration, funding acquisition, Z.R. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Second Tibetan Plateau Scientific Expedition and Research Program (2019QZKK0501), Qinghai Key R&D and Transformation Program (2020-SF-146).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Data is available from the corresponding author upon reasonable request.

Acknowledgments

The authors thank the Second Tibetan Plateau Scientific Expedition and Research Program (2019QZKK0501), the Qinghai Key R&D and Transformation Program (2020-SF-146), and the Technological Innovation Project of Qinghai Normal University (qhnuxskj2022003, qhnuxskj2022032, qhnuxskj2022036).

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

Table A1. Diversity of terrestrial vertebrates in different parts of the China.
Table A1. Diversity of terrestrial vertebrates in different parts of the China.
Province AvesMammaliaReptiliaAmphibiaTotalYear
Hubei Northwestern Hubei Province40510855516192017
Hubei Shennongjia World Natural Heritage Site4008753375772018
Hubei Dongting Lake Wetlands1801918122292017
Hubei Zhonghua Mountain Nature Reserve1653931152502018
GansuTaizishan National Nature Reserve13860372082022
GansuGuazhou Tangdun Hu Nature Reserve12029921602020
GansuMazongshan482570802017
TibetNgari 712620992018
TibetNiyang River Basin521521702013
TibetNational Reserve of Lhalu Wetland, Lhasa62621712010
HebeiChagannur wetlands14119841722022
HebeiHebei Province440832585562012
ShanxiGucheng National Wetland Park15911741812018
ShanxiXi County Seat7730501222015
GuangdongZhongshan Xiangshan Nature Reserve1061036161682021
GuangdongNanling National Nature Reserve2598994444862012
GuangdongMeijiang Basin2014242173022012
GuangxiWanggangshan Nature Reserve1221839141932018
GuangxiMulun Nature Reserve 2036064333602014
SichuangRuoerge Wetland National Nature Reserve18738432322021
YunnanPu’er City49918287698372020
Inner MongoliaTumuji Nature Reserve27623863132020
QinghaiTianzhu County Seat16664732402020
Tengger Desert201331232492020
HeilongjiangShuanghe Nature Reserve 18028762812017
GuizhouChishui Suoluo National Nature Reserve1826035233002013
JiangxiMountain National Forest Park1493438162372013
NingxiaLiupan Mountain National Nature Reserve16047852202013
Table A2. Checklist of terrestrial wild vertebrates in Qinghai Area of Qilian Mountain National Park.
Table A2. Checklist of terrestrial wild vertebrates in Qinghai Area of Qilian Mountain National Park.
NameOrderFaunaFauna TypesAnimal Protection ClassConservation StatusSurvey Methodology
Rana kukunorisAnuraCosmopolitan speciesP
Bufo gargarizans minshanicusAnuraCosmopolitan speciesL
Bufo gargarizansAnuraCosmopolitan speciesE
Rhabdophis tigrinusSquamataCosmopolitan speciesE
Elaphe dioneSquamataCosmopolitan speciesU Simple line method
Gloydius cognatusSquamataCosmopolitan speciesD
Phrynocephalus vlangaliiSquamataPalaearctic realmP Simple line method
Eremias multiocellataSquamataPalaearctic realmD Simple line method
Jynx torquillaPiciformesCosmopolitan speciesU
Picus canusPiciformesCosmopolitan speciesU Simple line method
Dendrocopos majorPiciformesCosmopolitan speciesU Simple line method
Picoides tridactylusPiciformesCosmopolitan speciesCIILC
Dryocopus martiusPiciformesCosmopolitan speciesUIILCSimple line method
Apus pacificusCaprimulgiformesCosmopolitan speciesM Simple line method
Anser anserAnseriformesPalaearctic realmU
Anser indicusAnseriformesCosmopolitan speciesP Simple line method
Mareca streperaAnseriformesPalaearctic realmU Simple line method
Anas platyrhynchosAnseriformesPalaearctic realmC Simple line method
Anas creccaAnseriformesPalaearctic realmC Simple line method
Anas zonorhynchaAnseriformesPalaearctic realmW Simple line method
Spatula clypeataAnseriformesCosmopolitan speciesC
Anas penelopeAnseriformesCosmopolitan speciesC Simple line method
Anas acutaAnseriformesCosmopolitan speciesC
Netta rufinaAnseriformesPalaearctic realmO Simple line method
Bucephala clangulaAnseriformesCosmopolitan speciesC
Mergus merganserAnseriformesCosmopolitan speciesC Simple line method
Aythya ferinaAnseriformesPalaearctic realmC
Aythya fuligulaAnseriformesPalaearctic realmU Simple line method
Aythya nyrocaAnseriformesCosmopolitan speciesO Simple line method
Tadorna ferrugineaAnseriformesCosmopolitan speciesU Simple line method
Anser cygnoidesAnseriformesCosmopolitan speciesMIIVU
Cygnus cygnusAnseriformesPalaearctic realmCIINTSimple line method
Cygnus olorAnseriformesCosmopolitan speciesUIINT
Mergellus albellusAnseriformesCosmopolitan speciesUIILC
Ithaginis cruentusGalliformesCosmopolitan speciesHIINTSimple line method
Tetraogallus tibetanusGalliformesCosmopolitan speciesPIINTInfrared camera monitoring method
Tetraogallus himalayensisGalliformesPalaearctic realmPIINTInfrared camera monitoring method
Crossoptilon auritumGalliformesCosmopolitan speciesPIINTSimple line method
Alectoris magnaGalliformesPalaearctic realmPIINTInfrared camera monitoring method
Tetraophasis obscurusGalliformesCosmopolitan speciesHIVUSimple line method
Tetrastes sewerzowiGalliformesCosmopolitan speciesHI Simple line method
Phasianus colchicusGalliformesCosmopolitan speciesO Simple line method
Alectoris chukarGalliformesPalaearctic realmD Simple line method
Perdix dauuricaGalliformesPalaearctic realmD Simple line method
Perdix hodgsoniaeGalliformesCosmopolitan speciesH Simple line method
Upupa epopsBucerotiformesCosmopolitan speciesO Simple line method
Nycticorax nycticoraxCiconiiformesCosmopolitan speciesO
Egretta garzettaCiconiiformesCosmopolitan speciesW Simple line method
Ciconia nigraCiconiiformesCosmopolitan speciesUIVUSimple line method
Podiceps nigricollisPodicipediformesCosmopolitan speciesCIILCSimple line method
Tachybaptus ruficollisPodicipediformesCosmopolitan speciesW
Podiceps cristatusPodicipediformesCosmopolitan speciesU
Urocynchramus pylzowiPasseriformesCosmopolitan speciesPIINT
Alauda arvensisPasseriformesCosmopolitan speciesUIILCSimple line method
Melanocorypha mongolicaPasseriformesPalaearctic realmDIIVUSimple line method
Alauda gulgulaPasseriformesCosmopolitan speciesC Simple line method
Eremophila alpestrisPasseriformesCosmopolitan speciesC Simple line method
Galerida cristataPasseriformesCosmopolitan speciesO Simple line method
Calandrella acutirostrisPasseriformesCosmopolitan speciesP Simple line method
Calandrella brachydactylaPasseriformesCosmopolitan speciesO Simple line method
Melanocorypha maximaPasseriformesCosmopolitan speciesP Simple line method
Loxia curvirostraPasseriformesCosmopolitan speciesCIILCSimple line method
Carpodacus erythrinusPasseriformesCosmopolitan speciesU Simple line method
Carpodacus rubicilloidesPasseriformesCosmopolitan speciesP
Carpodacus rubicillaPasseriformesPalaearctic realmP
Carpodacus pulcherrimusPasseriformesCosmopolitan speciesH
Carpodacus puniceusPasseriformesCosmopolitan speciesP
Carpodacus dubiusPasseriformesCosmopolitan speciesW
Linaria flavirostrisPasseriformesCosmopolitan speciesU
Mycerobas carnipesPasseriformesCosmopolitan speciesP
Leucosticte brandtiPasseriformesCosmopolitan speciesP Infrared camera monitoring method
Leucosticte nemoricolaPasseriformesCosmopolitan speciesP Infrared camera monitoring method
Phoenicurus alaschanicusPasseriformesPalaearctic realmDII Simple line method
Luscinia calliopePasseriformesCosmopolitan speciesUII Simple line method
Chaimarrornis leucocephalusPasseriformesCosmopolitan speciesH Infrared camera monitoring method
Saxicola maurusPasseriformesCosmopolitan speciesO
Tarsiger cyanurusPasseriformesCosmopolitan speciesM Simple line method
Oenanthe isabellinaPasseriformesPalaearctic realmD
Oenanthe pleschankaPasseriformesPalaearctic realmD
Oenanthe desertiPasseriformesPalaearctic realmD Infrared camera monitoring method
Phoenicuropsis schisticepsPasseriformesCosmopolitan speciesH Simple line method
Phoenicuropsis frontalisPasseriformesCosmopolitan speciesH
Phoenicurus ochrurosPasseriformesCosmopolitan speciesO Infrared camera monitoring method
Phoenicurus hodgsoniPasseriformesCosmopolitan speciesH Simple line method
Phoenicurus auroreusPasseriformesCosmopolitan speciesM Simple line method
Phoenicurus erythrogastrusPasseriformesPalaearctic realmP Infrared camera monitoring method
Calliope pectoralisPasseriformesCosmopolitan speciesH
Grandala coelicolorPasseriformesCosmopolitan speciesH
Luscinia svecicaPasseriformesCosmopolitan speciesUII
Turdus kessleriPasseriformesCosmopolitan speciesH Simple line method
Turdus ruficollisPasseriformesCosmopolitan speciesO
Poecile superciliosusPasseriformesCosmopolitan speciesPIINTSimple line method
Aegithalos glaucogularisPasseriformesCosmopolitan speciesU
Periparus rubidiventrisPasseriformesCosmopolitan speciesH Simple line method
Poecile montanusPasseriformesCosmopolitan speciesC
Pseudopodoces humilisPasseriformesCosmopolitan speciesP
Trochalopteron elliotiiPasseriformesCosmopolitan speciesHIILCSimple line method
Garrulax davidiPasseriformesPalaearctic realmB Simple line method
Syrrhaptes paradoxusPterocliformesCosmopolitan speciesD Simple line method
Syrrhaptes tibetanusPterocliformesPalaearctic realmP Simple line method
Hirundo rusticaPasseriformesCosmopolitan speciesC Simple line method
Delichon urbicumPasseriformesCosmopolitan speciesU
Cecropis dauricaPasseriformesCosmopolitan speciesU Simple line method
Prunella fulvescensPasseriformesCosmopolitan speciesP Infrared camera monitoring method
Prunella collarisPasseriformesCosmopolitan speciesU Infrared camera monitoring method
Prunella rubeculoidesPasseriformesCosmopolitan speciesP
Corvus coraxPasseriformesCosmopolitan speciesC
Corvus monedulaPasseriformesCosmopolitan speciesU
Corvus dauuricusPasseriformesPalaearctic realmU
Corvus macrorhynchosPasseriformesCosmopolitan speciesE Simple line method
Pyrrhocorax graculusPasseriformesCosmopolitan speciesO
Pyrrhocorax pyrrhocoraxPasseriformesCosmopolitan speciesO Infrared camera monitoring method
Pica picaPasseriformesCosmopolitan speciesC Simple line method
Pseudopodoces humilisPasseriformesCosmopolitan speciesP Simple line method
Cyanopica cyanusPasseriformesCosmopolitan speciesU Simple line method
Podoces hendersoniPasseriformesPalaearctic realmD
Montifringilla henriciPasseriformesCosmopolitan speciesP Infrared camera monitoring method
Montifringilla nivalisPasseriformesPalaearctic realmP Simple line method
Montifringilla adamsiPasseriformesCosmopolitan speciesP Simple line method
Petronia petroniaPasseriformesCosmopolitan speciesO
Passer montanusPasseriformesCosmopolitan speciesU Simple line method
Pyrgilauda davidianaPasseriformesCosmopolitan speciesP Simple line method
Pyrgilauda ruficollisPasseriformesCosmopolitan speciesP Infrared camera monitoring method
Onychostruthus taczanowskiiPasseriformesCosmopolitan speciesP Simple line method
Pyrgilauda blanfordiPasseriformesCosmopolitan speciesP
Certhia familiarisPasseriformesCosmopolitan speciesC Simple line method
Tichodroma murariaPasseriformesCosmopolitan speciesO Simple line method
Emberiza leucocephalosPasseriformesPalaearctic realmU Simple line method
Emberiza godlewskiiPasseriformesCosmopolitan speciesO
Leptopoecile sophiaePasseriformesCosmopolitan speciesP
Leptopoecile elegansPasseriformesCosmopolitan speciesH
Anthus richardiPasseriformesCosmopolitan speciesM
Anthus roseatusPasseriformesCosmopolitan speciesP
Anthus spinolettaPasseriformesCosmopolitan speciesC
Motacilla albaPasseriformesCosmopolitan speciesU Simple line method
Motacilla tschutschensisPasseriformesCosmopolitan speciesU
Motacilla citreolaPasseriformesCosmopolitan speciesU
Phylloscopus inornatusPasseriformesPalaearctic realmU
Phylloscopus fuscatusPasseriformesCosmopolitan speciesM
Phylloscopus affinisPasseriformesCosmopolitan speciesH
Phylloscopus subaffinisPasseriformesOriental realmS
Phylloscopus proregulusPasseriformesCosmopolitan speciesU
Sturnus vulgarisPasseriformesCosmopolitan speciesO
Dicrurus hottentottusPasseriformesCosmopolitan speciesW
Troglodytes troglodytesPasseriformesCosmopolitan speciesC
Cinclus cinclusPasseriformesCosmopolitan speciesO Simple line method
Regulus regulusPasseriformesCosmopolitan speciesC
Lanius tephronotusPasseriformesCosmopolitan speciesH
Lanius sphenocercusPasseriformesCosmopolitan speciesM
Lanius isabellinusPasseriformesCosmopolitan speciesX
Aegypius monachusAccipitriformesCosmopolitan speciesOINT
Milvus migransAccipitriformesCosmopolitan speciesUIILC
Accipiter nisusAccipitriformesCosmopolitan speciesUIILC
Circus cyaneusAccipitriformesCosmopolitan speciesCIINT
Gyps fulvusAccipitriformesOriental realmWIINT
Gyps himalayensisAccipitriformesCosmopolitan speciesOIINTSimple line method
Buteo hemilasiusAccipitriformesCosmopolitan speciesDIINTSimple line method
Buteo japonicusAccipitriformesCosmopolitan speciesUIILCSimple line method
Gypaetus barbatusAccipitriformesCosmopolitan speciesOINT
Pandion haliaetusAccipitriformesCosmopolitan speciesCIINT
Haliaeetus leucoryphusAccipitriformesCosmopolitan speciesDIEN
Haliaeetus albicillaAccipitriformesCosmopolitan speciesUIVU
Aquila nipalensisAccipitriformesCosmopolitan speciesDIVU
Aquila chrysaetosAccipitriformesCosmopolitan speciesCIVUSimple line method
Red-legged FalconAccipitriformesCosmopolitan speciesU
Falco tinnunculusFalconiformesCosmopolitan speciesOIILC
Falco columbariusFalconiformesCosmopolitan speciesCIINT
Falco cherrugFalconiformesCosmopolitan speciesCIENSimple line method
Falco peregrinusFalconiformesCosmopolitan speciesCIINT
Aquila heliacaFalconiformesCosmopolitan speciesOIEN
Athene noctuaStrigiformesCosmopolitan speciesUIILCInfrared camera monitoring method
Aegolius funereusStrigiformesCosmopolitan speciesCIIVU
Asio otusStrigiformesCosmopolitan speciesCIILCSimple line method
Asio flammeusStrigiformesCosmopolitan speciesCIINTSimple line method
Bubo buboStrigiformesCosmopolitan speciesUIINT
Sterna hirundoLariformesCosmopolitan speciesC
Larus brunnicephalus JerdonLariformesCosmopolitan speciesP Simple line method
Chlidonias leucopterusLariformesCosmopolitan speciesU
Cuculus canorusCuculiformesCosmopolitan speciesO Simple line method
Phalacrocorax carboSuliformesCosmopolitan speciesO Simple line method
Phoenicopterus roseus PhoenicopteriformesPalaearctic realmO
Ibidorhyncha struthersiiCharadriiformesCosmopolitan speciesPIINT
Arenaria interpresCharadriiformesCosmopolitan speciesCIILC
Numenius minutusCharadriiformesCosmopolitan speciesMIINT
Tringa totanusCharadriiformesCosmopolitan speciesU Simple line method
Tringa nebulariaCharadriiformesCosmopolitan speciesU
Xenus cinereusCharadriiformesCosmopolitan speciesU
Actitis hypoleucosCharadriiformesCosmopolitan speciesC Simple line method
Limosa lapponicaCharadriiformesCosmopolitan speciesU
Calidris alpinaCharadriiformesCosmopolitan speciesC
Calidris ruficollisCharadriiformesCosmopolitan speciesM
Calidris temminckiiCharadriiformesCosmopolitan speciesU
Calidris ferrugineaCharadriiformesCosmopolitan speciesU
Ichthyaetus ichthyaetusCharadriiformesCosmopolitan speciesD Simple line method
Himantopus himantopusCharadriiformesCosmopolitan speciesO
Recurvirostra avosettaCharadriiformesCosmopolitan speciesO
Tringa ochropusCharadriiformesCosmopolitan speciesU Simple line method
Tringa glareolaCharadriiformesCosmopolitan speciesU
Tringa erythropusCharadriiformesCosmopolitan speciesU
Vanellus vanellusCharadriiformesCosmopolitan speciesU Simple line method
Charadrius dubiusCharadriiformesCosmopolitan speciesO Simple line method
Charadrius alexandrinusCharadriiformesCosmopolitan speciesO
Charadrius mongolusCharadriiformesCosmopolitan speciesD
Pluvialis fulvaCharadriiformesCosmopolitan speciesC Simple line method
Grus virgoGruiformesCosmopolitan speciesWIILC
Grus grusGruiformesCosmopolitan speciesUIINT
Grus nigricollisGruiformesCosmopolitan speciesPIVUSimple line method
Rallus aquaticusGruiformesCosmopolitan speciesU Simple line method
Fulica atraGruiformesCosmopolitan speciesO Simple line method
Gallinula chloropusGruiformesCosmopolitan speciesO
Ixobrychus sinensisPelecaniformesCosmopolitan speciesW
Bubulcus ibisPelecaniformesCosmopolitan speciesW
Ardea cinereaPelecaniformesCosmopolitan speciesU
Ardea albaPelecaniformesCosmopolitan speciesO
Ardeola bacchusPelecaniformesCosmopolitan speciesW
Platalea leucorodiaPelecaniformesCosmopolitan speciesOIINT
Pelecanus onocrotalusPelecaniformesCosmopolitan speciesOIEN
Columba liviaColumbiformesPalaearctic realmO Simple line method
Columba rupestrisColumbiformesPalaearctic realmO Simple line method
Columba leuconotaColumbiformesPalaearctic realmH Simple line method
Streptopelia decaoctoColumbiformesCosmopolitan speciesW Simple line method
Alcedo atthisCoracheiiformesCosmopolitan speciesO
Naemorhedus griseusArtiodactylaPalaearctic realmEIIVU
Procapra picticaudataArtiodactylaPalaearctic realmPIINTInfrared camera monitoring method
Pseudois nayaurArtiodactylaCosmopolitan speciesPIILCInfrared camera monitoring method
Ovis ammonArtiodactylaCosmopolitan speciesPII Infrared camera monitoring method
Bos grunniensArtiodactylaOriental realmPIVUInfrared camera monitoring method
Lepus oiostalusLagomorphaCosmopolitan speciesP Infrared camera monitoring method
Lepus oiostolusLagomorphaCosmopolitan speciesP Infrared camera monitoring method
Ochotona macrotisLagomorphaPalaearctic realmP
Ochotona erythrotisLagomorphaPalaearctic realmP
Ochotona curzoniaeLagomorphaCosmopolitan speciesP Infrared camera monitoring method
Ochotona thomasiLagomorphaPalaearctic realmP
Ochotona cansusLagomorphaCosmopolitan speciesP
Ochotona dauuricaLagomorphaPalaearctic realmD
Cervus elaphusArtiodactylaCosmopolitan speciesCIIENSimple line method
Moschus chrysogasterArtiodactylaCosmopolitan speciesPI Infrared camera monitoring method
Capreolus capreolusArtiodactylaCosmopolitan speciesU Simple line method
Cervus albirostrisArtiodactylaPalaearctic realmPIENInfrared camera monitoring method
Equus kiangPerissodactylaPalaearctic realmPINTInfrared camera monitoring method
Felis bietiCarnivoraCosmopolitan speciesDICRInfrared camera monitoring method
Lynx lynxCarnivoraCosmopolitan speciesCIIENInfrared camera monitoring method
Felis manulCarnivoraCosmopolitan speciesDIIENInfrared camera monitoring method
Felis bengalensisCarnivoraCosmopolitan speciesWIIVU
Panthera unciaCarnivoraPalaearctic realmPIENInfrared camera monitoring method
Vulpes ferrilataCarnivoraCosmopolitan speciesPIINTInfrared camera monitoring method
Cuon alpinusCarnivoraCosmopolitan speciesWINTSimple line method
Canis lupusCarnivoraCosmopolitan speciesCIINTInfrared camera monitoring method
Vulpes vulpesCarnivoraCosmopolitan speciesCIINTInfrared camera monitoring method
Vulpes corsacCarnivoraPalaearctic realmDIINT
Mustela altaicaCarnivoraCosmopolitan speciesO
Mustela sibiricaCarnivoraCosmopolitan speciesU
Ursus arctosCarnivoraPalaearctic realmCIIVUInfrared camera monitoring method
Meles melesCarnivoraCosmopolitan speciesU Simple line method
Mustela eversmaniiCarnivoraCosmopolitan speciesU
Martes foinaCarnivoraCosmopolitan speciesUIIENInfrared camera monitoring method
Allactaga sibiricaRodentiaPalaearctic realmD
Petaurista xanthotisRodentiaCosmopolitan speciesH
Marmota himalayanaRodentiaCosmopolitan species P
Myospalax bailyiRodentiaPalaearctic realmB Infrared camera monitoring method
Cricetulus kamensisRodentiaCosmopolitan speciesP
Cricetulus longicandatusRodentiaPalaearctic realmD
Alticola stracheyinusRodentiaPalaearctic realmP
Sorex caecutiensInsectivoraCosmopolitan speciesU
Sorex thibetanusInsectivoraCosmopolitan speciesU
Figure A1. Photos of wildlife in the study area (All photos were taken by Z.R).
Figure A1. Photos of wildlife in the study area (All photos were taken by Z.R).
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Figure A2. Photos of wildlife in the study area (All photos were taken by Z.R).
Figure A2. Photos of wildlife in the study area (All photos were taken by Z.R).
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Figure A3. Photos of Panthera uncia in the study area (All photos were taken by Z.R).
Figure A3. Photos of Panthera uncia in the study area (All photos were taken by Z.R).
Sustainability 14 16452 g0a3

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Figure 1. Location of the Qinghai Area of Qilian Mountain National Park.
Figure 1. Location of the Qinghai Area of Qilian Mountain National Park.
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Figure 2. Location of Sample Lines and Infrared camera points in the Qinghai Area of Qilian Mountain National Park.
Figure 2. Location of Sample Lines and Infrared camera points in the Qinghai Area of Qilian Mountain National Park.
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Figure 3. Distribution of Mammalia, Aves, Reptilia, River and Lake in the Qinghai Area of Qilian Mountain National Park.
Figure 3. Distribution of Mammalia, Aves, Reptilia, River and Lake in the Qinghai Area of Qilian Mountain National Park.
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Table 1. Fauna composition of terrestrial wild vertebrates.
Table 1. Fauna composition of terrestrial wild vertebrates.
Fauna Number of SpeciesTotal Number of SpeciesProportion of Total Species (%)Proportion of Classes (%)
Cosmopolitan speciesAmphibia3 2141.13 100
Reptilia3 1.13 60
Mammalia27 10.19 62.79
Aves181 68.3 84.58
Palaearctic realmAmphibia0 480 0
Reptilia2 0.75 40
Mammalia15 5.66 34.88
Aves31 11.7 14.49
Oriental realmAmphibia0 30 0
Reptilia0 0 0
Mammalia1 0.38 2.33
Aves2 0.75 1.03
Table 2. Fauna composition of terrestrial wild vertebrates.
Table 2. Fauna composition of terrestrial wild vertebrates.
ClassAmphibiaReptiliaMammaliaAvesTotalPercentage (%)
U017526022.64
P1118335320
C005354015.09
O001373814.34
D02714238.68
H00118197.17
W00212145.28
M000993.40
E111141.51
B001120.75
X000110.38
S000110.38
L100010.38
Table 3. Analysis of G-F indexes of terrestrial wild vertebrates.
Table 3. Analysis of G-F indexes of terrestrial wild vertebrates.
ClassOrderFamilyGenusNumber of
Species
G IndexF IndexG-F Index
Amphibia12230.6400
Reptilia24551.610.69−1.33
Mammalia61428433.156.540.52
Aves21511312144.6829.740.84
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Xu, S.; Rong, Z.; Ma, H.; Xie, J.; Wang, F. Study on Terrestrial Wild Vertebrate Diversity and Geographical Fauna in Qinghai Area of Qilian Mountain National Park, China. Sustainability 2022, 14, 16452. https://doi.org/10.3390/su142416452

AMA Style

Xu S, Rong Z, Ma H, Xie J, Wang F. Study on Terrestrial Wild Vertebrate Diversity and Geographical Fauna in Qinghai Area of Qilian Mountain National Park, China. Sustainability. 2022; 14(24):16452. https://doi.org/10.3390/su142416452

Chicago/Turabian Style

Xu, Shiyu, Zhanlei Rong, Hu Ma, Jiaan Xie, and Fang Wang. 2022. "Study on Terrestrial Wild Vertebrate Diversity and Geographical Fauna in Qinghai Area of Qilian Mountain National Park, China" Sustainability 14, no. 24: 16452. https://doi.org/10.3390/su142416452

APA Style

Xu, S., Rong, Z., Ma, H., Xie, J., & Wang, F. (2022). Study on Terrestrial Wild Vertebrate Diversity and Geographical Fauna in Qinghai Area of Qilian Mountain National Park, China. Sustainability, 14(24), 16452. https://doi.org/10.3390/su142416452

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