不同营林面积情景下鹿科动物的潜在生境分布

doi:10.13287/j.1001-9332.201708.021

摘要/Abstract

摘要： 在有人为干扰的森林景观中开展鹿科动物适宜生境分布研究,对于解决大尺度生境保护与小面积森林经营的矛盾问题有着重要的参考意义,也符合我国林区的现实需求.2013—2015年冬季进行的多次野外调查收集196处鹿科动物出现点信息,将这些点作为分布点数据,选取地形、景观类型、植被特征和人类干扰4类17种因子作为环境变量,利用最大熵模型方法,分析4种林下经营面积情景下小兴安岭铁力林业局马鹿和狍的潜在适宜生境分布特征及其对环境因子的响应.结果表明:模型预测精度达到优秀水平,稳定性好,鹿科动物的适宜生境主要集中在东部区域;不同情景下,两种鹿科动物的主要环境影响因子相似,均为距农田距离、距居民点距离、距河流距离、距营林区距离和海拔因子,其中,距营林区距离因子的贡献率稳定在4%～6%;两种鹿科动物躲避人类经营活动干扰的距离(1200～1300 m)较为接近.在无林下经营情景中,鹿科动物的适宜生境分布较广、面积较大;随着经营面积的增大,适宜生境面积减少;当经营面积扩大到现实情况的2～3倍时,鹿科动物栖息地面积缩减较为严重.

Abstract: It is theoretically and practically important to explore suitable habitat distribution of the Cervids for relieving the confliction between small-scale human management and large-scale habitat conservation in a human-disturbed forest landscape. Using the present locations of Cervids (n=196) observed in field investigations in 2013, 2014 and 2015, we grouped 17 environmental predictor variables into four predictor classes (terrain, habitat type, vegetation feature, and interference) and used those variables to build a maximum entropy (MaxEnt) model. Then, we estimated the potential habitat of red deer and roe deer, and determined the contribution of environmental factors to the distribution characteristics in four forest management area scenarios by this model. Results showed that models validation had high average accuracy and the stability appeared satisfactory. The potential suitable habitat for Cervids was located mostly in the eastern region. The environmental factors significantly affecting habitat suitability of red deer and roe deer were similar in different scenarios, and they were distance to farmland, distance to settlement, distance to river, distance to management area and elevation. Distance to management area factor was found to have a certain extent effect on habitat suitability with contribution probability from 4% to 6%. The distance to management area was about 1200-1300 m both for red deer and roe deer. In none management scenario, the suitable habitat was widely distributed in large area. With the increase of management area, the suitable habitat decreased. When the management area expanded to the twofold or threefold of the current one, Cervids habitat shrank greatly.

吴文, 李月辉, 胡远满, 陈龙, 熊在平. 不同营林面积情景下鹿科动物的潜在生境分布[J]. 应用生态学报, 2017, 28(8): 2705-2713.

WU Wen, LI Yue-hui, HU Yuan-man, CHEN Long, XIONG Zai-ping. Potential habitat distribution for Cervids based on different forest management area scena-rios[J]. Chinese Journal of Applied Ecology, 2017, 28(8): 2705-2713.

参考文献

[1] Laurance WF, Useche DC, Rendeiro J, et al. Averting biodiversity collapse in tropical forest protected areas. Nature, 2012, 489: 290-294
[2] Leclerc M, Dussault C, St-Laurent MH. Multiscale assessment of the impacts of roads and cutovers on calving site selection in woodland caribou. Forest Ecology and Management, 2012, 286: 59-65
[3] Li N-N (李娜娜), Li Y-H (李月辉). Management models of different ownership forests and their ecological effects: A review. Chinese Journal of Applied Ecology (应用生态学报), 2011, 22(6): 1623-1631 (in Chinese)
[4] Li Y-H (李月辉), Wu W (吴文), Li N-N (李娜娜), et al. Effects of forest ownership regime on landscape pattern and animal habitat: A review. Chinese Journal of Applied Ecology (应用生态学报), 2013, 24(7): 2056-2062 (in Chinese)
[5] Forman RTT, Alexander LE. Roads and their major ecological effects. Annual Review of Ecology and Systema-tics, 1998, 29: 207-231
[6] Trombulak SC, Frissell CA. Review of ecological effects of roads on terrestrial and aquatic communities. Conservation Biology, 2000, 14: 18-30
[7] Zeng Q, Zhang YM, Sun GQ, et al. Using species distribution model to estimate the wintering population size of the endangered scaly-sided merganser in China. PLoS One, 2015, 10(2): e0117307
[8] Wu W, Hu Y, Li Y, et al. Plant diversity and vegetation structures in the understory of mixed boreal forests under different management regimes. Polish Journal of Environmental Studies, 2016, 25: 1749-1757
[9] Qin Y (秦瑜), Zhang M-H (张明海). Review of researches of red deer (Cervus elaphus) and perspects in China. Chinese Journal of Wildlife (野生动物), 2009, 30(2): 100-104 (in Chinese)
[10] Li Y-H (李月辉), Chang Y (常禹), Hu Y-M (胡远满), et al. Research advance in effects of anthropogenic activity on forest landscape. Scientia Silvae Sinicae (林业科学), 2006, 42(9): 119-126 (in Chinese)
[11] Gustafson EJ, Lytle DE, Swaty R, et al. Simulating the cumulative effects of multiple forest management strategies on landscape measures of forest sustainability. Landscape Ecology, 2007, 22: 141-156
[12] Tian Y, Wu J, Smith AT, et al. Population viability of the Siberian Tiger in a changing landscape: Going, going and gone? Ecological Modelling, 2011, 222: 3166-3180
[13] Tian Y, Wu J, Wang T, et al. Climate change and landscape fragmentation jeopardize the population viability of the Siberian tiger (Panthera tigris altaica). Landscape Ecology, 2014, 29: 621-637
[14] Wang T, Feng L, Mou P, et al. Amur tigers and leo-pards returning to China: Direct evidence and a landscape conservation plan. Landscape Ecology, 2016, 31: 491-503
[15] Wu W (吴文), Li Y-H (李月辉), Hu Y-M (胡远满), et al. Suitable winter habitat for Cervus elaphus on the southern slope of the Lesser Xingan Mountains. Biodiversity Science (生物多样性), 2016, 24(1): 20-29 (in Chinese)
[16] Elith J, Graham CH, Anderson RP, et al. Novel methods improve prediction of species’ distributions from occurrence data. Ecography, 2006, 29: 129-151
[17] Phillips SJ, Anderson RP, Schapire RE. Maximum entropy modeling of species geographic distributions. Ecological Modelling, 2006, 190: 231-259
[18] Phillips SJ, Dudik M. Modeling of species distributions with Maxent: New extensions and a comprehensive eva-luation. Ecography, 2008, 31: 161-175
[19] Xing D-L (邢丁亮), Hao Z-Q (郝占庆). The principle of maximum entropy and its applications in ecology. Biodiversity Science (生物多样性), 2011, 19(3): 295-302 (in Chinese)
[20] Leathwick JR, Elith J, Francis MP, et al. Variation in demersal fish species richness in the oceans surrounding New Zealand: An analysis using boosted regression trees. Marine Ecology Progress Series, 2006, 321: 267-281
[21] Thomas L, Buckland ST, Rexstad EA, et al. Distance software: Design and analysis of distance sampling surveys for estimating population size. Journal of Applied Ecology, 2010, 47: 5-14
[22] Dormann CF, Elith J, Bacher S, et al. Collinearity: A review of methods to deal with it and a simulation study evaluating their performance. Ecography, 2013, 36: 27-46
[23] Gallardo B, Aldridge DC. Evaluating the combined threat of climate change and biological invasions on endangered species. Biological Conservation, 2013, 160: 225-233
[24] Behdarvand N, Kaboli M, Ahmadi M, et al. Spatial risk model and mitigation implications for wolf-human conflict in a highly modified agroecosystem in western Iran. Biological Conservation, 2014, 177: 156-164
[25] Luo C (罗翀), Xu W-H (徐卫华), Zhou Z-X (周志翔), et al. Habitat prediction for forest musk deer (Moschus berezovskii) in Qinling Mountain range based on niche model. Acta Ecologica Sinica (生态学报), 2011, 31(5): 1221-1229 (in Chinese)
[26] Araujo MB, Alagador D, Cabeza M, et al. Climate change threatens European conservation areas. Ecology Letters, 2011, 14: 484-492
[27] Vega Garcia C, Woodard PM, Titus SJ, et al. A logit model for predicting the daily occurrence of human caused forest-fires.International Journal of Wildland Fire, 1995, 5: 101-111
[28] Catry FX, Rego FC, Bacao F, et al. Modeling and mapping wildfire ignition risk in Portugal. International Journal of Wildland Fire, 2009, 18: 921-931
[29] Hou N (侯宁), Dai Q (戴强), Ran J-H (冉江洪), et al. A corridor design for the giant panda in the Niba Mountain of China. Chinese Journal of Applied and Environmental Biology (应用与环境生物学报), 2014, 20(6): 1039-1045 (in Chinese)
[30] Piekielek NB, Hansen AJ. Extent of fragmentation of coarse-scale habitats in and around US National Parks. Biological Conservation, 2012, 155: 13-22
[31] Underwood VJ, Ober HK, Miller DL, et al. Contributions of private landowners to the conservation of the gopher tortoise (Gopherus polyphemus). Environmental Management, 2012, 49: 846-854
[32] Jin L-R (金龙如), He H-S (贺红士), Zong C (宗诚), et al. Effects of different forest management alternatives on Sciurus vulgaris habitat. Chinese Journal of Applied Ecology (应用生态学报), 2008, 19(5):949-955 (in Chinese)
[33] Li YH, Wu W, Xiong ZP, et al. Effects of forest roads on habitat pattern for sables in Da Hinggan Mountains, northeasten China. Chinese Geographical Science, 2014, 24: 587-598
[34] Pena JCD, Kamino LHY, Rodrigues M, et al. Assessing the conservation status of species with limited available data and disjunct distribution. Biological Conservation, 2014, 170: 130-136
[35] Chen X-M (陈新美), Lei Y-C (雷渊才), Zhang X-Q (张雄清), et al. Effects of sample sizes on accuracy and stability of Maximum Entropy Model in predicting species distribution. Scientia Silvae Sinicae (林业科学), 2012, 48(1): 53-59 (in Chinese)
[36] Wilson JW, Sexton JO, Jobe RT, et al. The relative contribution of terrain, land cover, and vegetation structure indices to species distribution models. Biological Conservation, 2013, 164: 170-176
[37] Silva VDE, Pressey RL, Machado RB, et al. Formulating conservation targets for a gap analysis of endemic lizards in a biodiversity hotspot. Biological Conservation, 2014, 180: 1-10
[38] Quinn A, Gallardo B, Aldridge DC. Quantifying the ecological niche overlap between two interacting invasive species: The zebra mussel (Dreissena polymorpha) and the quagga mussel (Dreissena rostriformis bugensis). Aquatic Conservation: Marine and Freshwater Ecosystems, 2014, 24: 324-337
[39] Holzmann I, Agostini I, Dematteo K, et al. Using species distribution modeling to assess factors that determine the distribution of two parapatric howlers (Alouatta spp.) in South America. International Journal of Primatology, 2015, 36: 18-32
[40] Wu W, Li Y, Hu Y. Simulation of potential habitat overlap between red deer (Cervus elaphus) and roe deer (Capreolus capreolus) in northeastern China. PeerJ, 2016, 4: e1756, doi: 10.7717/peerj.1756
[41] Gogol-Prokurat M. Predicting habitat suitability for rare plants at local spatial scales using a species distribution model. Ecological Applications, 2011, 21: 33-47
[42] Razgour O, Hanmer J, Jones G. Using multi-scale mode-lling to predict habitat suitability for species of conservation concern: The grey long-eared bat as a case study. Biological Conservation, 2011, 144: 2922-2930
[43] Brambilla M, Saporetti F. Modelling distribution of habitats required for different uses by the same species: Implications for conservation at the regional scale. Biological Conservation, 2014, 174: 39-46