庞泉沟国家级自然保护区狍和野猪时空共存格局

doi:10.17520/biods.2025327

生物多样性 ›› 2026, Vol. 34 ›› Issue (2): 25327. DOI: 10.17520/biods.2025327 cstr: 32101.14.biods.2025327

• 研究报告:动物多样性 • 上一篇下一篇

庞泉沟国家级自然保护区狍和野猪时空共存格局

周铝¹(), 姚世贸¹, 赵战合², 郭画¹(), 田成¹^,^*()()

1.山西农业大学林学院, 山西晋中 030801
2.山西文峪河国家级湿地公园管理局, 山西吕梁 030500

收稿日期:2025-08-17 接受日期:2026-01-08 出版日期:2026-02-20 发布日期:2026-03-23
通讯作者: *E-mail: tiancheng@sxau.edu.cn
基金资助:
山西省基础研究计划青年科学研究项目(20210302124143);山西省优秀博士来晋工作奖励基金(SXBYKY2021029)

Spatiotemporal coexistence patterns of Capreolus pygargus and Sus scrofa in Pangquangou National Nature Reserve

Lü Zhou¹(), Shimao Yao¹, Zhanhe Zhao², Hua Guo¹(), Cheng Tian¹^,^*()()

1 College of Forestry, Shanxi Agricultural University, Jinzhong, Shanxi 030801, China
2 National Wetland Park Management Bureau of Shanxi Wenyuhe, Lüliang, Shanxi 030500, China

Received:2025-08-17 Accepted:2026-01-08 Online:2026-02-20 Published:2026-03-23
Contact: *E-mail: tiancheng@sxau.edu.cn
Supported by:
Shanxi Province Basic Research Program Youth Science Research Project(20210302124143);Excellent Doctoral Work Reward Fundation of Shanxi Province(SXBYKY2021029)

摘要/Abstract

摘要：

探究狍(Capreolus pygargus)与野猪(Sus scrofa)的生态位分化与共存机制, 对于理解我国华北地区物种种间作用机制及指导保护区生态系统管理具有重要的理论与实践意义。本研究基于2023年8月至2024年11月的40台红外相机监测数据, 运用集合模型、核密度估计法、日活动差异指数(α)和昼行性指数(β)等多种方法系统解析了山西庞泉沟国家级自然保护区同域分布狍和野猪的时空分布及共存格局。结果显示: (1) 40台红外相机累计工作15,880个工作日, 获取可识别独立有效照片7,116张, 其中狍2,344张、野猪192张。(2)两物种均呈现昼行性双峰活动模式(狍β = 0.63, 野猪β = 0.71), 每月日活动差异不显著(P > 0.05), 日活动节律重叠存在显著差异(Δ₄ = 0.85; 95% CI: 0.81-0.87; P < 0.05), 狍晨间活动高峰较野猪延迟1-2 h, 下午活动高峰期近乎相同, 表明二者通过时间生态位的分化而减少竞争。(3)集合模型对二者分布预测效果良好。狍与野猪的适宜栖息地主要集中于保护区中部, 狍适宜栖息地面积为71.64 km², 占保护区总面积的67.06%; 野猪适宜栖息地面积为59.08 km², 占比56.91%, 二者生态位重叠程度较高(Schoener’s D = 0.70)。(4)人为干扰、归一化植被指数和等温性是影响二者分布的关键因素。其中狍和野猪的出现概率随等温性升高显著下降, 与归一化植被指数呈正相关, 与人类干扰呈先下降后上升的非线性关系。本研究揭示了狍与野猪日活动节律、空间分布、环境响应及共存格局, 为保护区内狍和野猪的保护与管理提供了理论依据, 同时填补了庞泉沟国家级自然保护区有蹄类物种间时空分布和共存格局的研究空白。

关键词: 庞泉沟国家级自然保护区, 活动节律, 时空分布, 物种共存, 集合模型

Abstract

Aims: This study aims to reveal the daily activity rhythms, spatial distribution, environmental responses, and coexistence patterns of roe deer (Capreolus pygargus) and wild boar (Sus scrofa), filling the research gap regarding the spatiotemporal distribution and coexistence patterns of ungulate species in Pangquangou National Nature Reserve. This is of great theoretical and practical significance for understanding interspecific interactions in North China and guiding the ecosystem management of protected areas.

Methods: Based on the monitoring data collected by 40 infrared cameras deployed in Shanxi Pangquangou National Nature Reserve from August 2023 to November 2024, this study systematically analyzed the spatiotemporal distribution and coexistence patterns of sympatric roe deer and wild boars using multiple methods, including ensemble models, kernel density estimation, daily-discrepancy index (α) and diurnal-nocturnal index (β).

Results: (1) A total of 40 infrared cameras operated continuously for a cumulative 15,880 camera-days, capturing 7,116 independently identifiable valid photos, including 2,344 of roe deers and 192 of wild boars. (2) Both species showed a diurnal bimodal activity pattern (roe deer: β = 0.63; wild boars: β = 0.71). The monthly differences in daily activity patterns were not significant (P > 0.05), but there was a significant difference in the overlap of daily activity rhythms (Δ₄ = 0.85; 95% CI: 0.81-0.87; P < 0.05). The morning activity peak of roe deer occurred 1-2 hours later than that of wild boars, while their afternoon activity peaks were nearly synchronous. This temporal shift indicates that the two species reduce interspecific competition through temporal niche differentiation. (3) The ensemble models showed good performance in predicting the distribution of both species (TSS > 0.7, AUC > 0.9). The suitable habitats of both roe deer and wild boars were mainly concentrated in the central part of the reserve. The suitable habitat area for roe deer was 71.64 km², accounting for 67.06% of the total reserve area; the suitable habitat area for wild boars was 59.08 km², accounting for 56.91%. The niche overlap between the two species was high (Schoener’s D = 0.70). (4) The human influence index, normalized difference vegetation index (NDVI), and isothermality were identified as the key factors influencing the distribution of both species. Specifically, the probability of presence of both roe deer and wild boars decreased significantly with increasing isothermality, was positively correlated with NDVI, and exhibited a non-linear relationship with the human influence index (initially decreasing before increasing).

Conclusion: Regarding the temporal niche, although both species exhibited a diurnal bimodal activity patterns with high niche overlap, a significant fine-scale differentiation in peak activity—specifically, the 1-2 hour delay in the morning peak of roe deer—constitutes a key behavioral adaptation to reduce direct competition for critical resources. Spatially, suitable habitats for both species were concentrated in the central reserve, and they demonstrated similar responses to the environmental factors driving their distribution. In conclusion, this study highlights that conservation strategies for roe deer and wild boars must prioritize the central core habitat quality and address the nonlinear impacts of environmental factors and human activities on species distribution and interspecific relationships.

Key words: Pangquangou National Nature Reserve, activity rhythm, spatiotemporal distribution, species coexistence, ensemble model

周铝, 姚世贸, 赵战合, 郭画, 田成 (2026) 庞泉沟国家级自然保护区狍和野猪时空共存格局. 生物多样性, 34, 25327. DOI: 10.17520/biods.2025327.

Lü Zhou, Shimao Yao, Zhanhe Zhao, Hua Guo, Cheng Tian (2026) Spatiotemporal coexistence patterns of Capreolus pygargus and Sus scrofa in Pangquangou National Nature Reserve. Biodiversity Science, 34, 25327. DOI: 10.17520/biods.2025327.

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链接本文: https://www.biodiversity-science.net/CN/10.17520/biods.2025327

https://www.biodiversity-science.net/CN/Y2026/V34/I2/25327

图/表 10

图1 庞泉沟国家级自然保护区40台红外相机分布图

Fig. 1 Distribution map of 40 infrared cameras in Pangquangou National Nature Reserve

表1 用于模型构建的环境因子

Table 1 Environmental factors used for model construction

变量类型 Variable type	变量名称 Variable
气候变量 Climatic variables	等温性 Isothermality (BIO3)
	最湿月降水量 Precipitation of wettest month (BIO13)
	最干月降水量 Precipitation of driest month (BIO14)
	降水季节性 Precipitation seasonality (BIO15)
	最干季降水量 Precipitation of driest quarter (BIO17)
地形变量 Topographic variables	坡度 Slope (Slope)
地形变量 Topographic variables	坡向 Aspect (Aspect)
人为活动变量 Human activity variables	人类干扰指数 Human influence index (HII)
生物变量 Biotic variables	归一化植被指数 Normalized difference vegetation index (NDVI)

图2 狍和野猪有效分布点位

Fig. 2 Valid occurrence locations of Capreolus pygargus and Sus scrofa

图3 狍(a)与野猪(b)的日活动节律。根据实地调查, 庞泉沟国家级自然保护区每日日出时间为7:00, 日落时间为18:30, 故图中白天与黑夜时间设置分割线为7:00和18:30。

Fig. 3 The daily activity rhythms of Capreolus pygargus (a) and Sus scrofa (b). According to the field investigation, the daily sunrise time at Pangquangou National Nature Reserve is 7:00 and the sunset time is 18:30. Therefore, the dividing line for daytime and nighttime in the figure is set at 7:00 and 18:30.

图4 狍和野猪日活动节律重叠图

Fig. 4 Overlap plot of the daily activity rhythms of Capreolus pygargus and Sus scrofa

图5 狍和野猪的11种单一模型评价。ANN: 人工神经网络; CTA: 分类树分析; FDA: 灵活判别分析; GAM: 广义加性模型; GBM: 梯度提升机; GLM: 广义线性模型; MARS: 多元自适应回归样条; MAXENT: 最大熵模型; RF: 随机森林; SRE: 表面范围包络法; XGBOOST: 极端梯度提升。

Fig. 5 Evaluation of 11 single models for Capreolus pygargus and Sus scrofa. ANN, Artificial neural network; CTA, Classification tree analysis; FDA, Flexible discriminant analysis; GAM, Generalized additive model; GBM, Gradient boosting machine; GLM, Generalized linear model; MARS, Multivariate adaptive regression splines; MAXENT, Maximum entropy model; RF, Random forest; XGBOOST, Extreme gradient boosting.

图6 狍和野猪适宜栖息地分布图

Fig. 6 Distribution map of suitable habitats for Capreolus pygargus and Sus scrofa

表2 狍与野猪适宜栖息地面积及占比

Table 2 Area and proportion of suitable habitats for Capreolus pygargus and Sus scrofa

适宜性 Suitability	狍 Capreolus pygargus		野猪 Sus scrofa
适宜性 Suitability	面积 Area (km²)	%	面积 Area (km²)	%
非适宜栖息地 Unsuitable habitat	35.19	32.94	44.74	43.09
低适宜栖息地 Low suitable habitat	38.33	35.88	28.33	27.29
中适宜栖息地 Moderately suitable habitat	21.40	20.03	16.25	15.65
高适宜栖息地 Highly suitable habitat	11.91	11.15	14.50	13.97

图7 狍(a)和野猪(b)的模型贡献度。EMmean: 平均值集成法; EMmedian: 中位数集成法; EMca: 二元投票; EMwmean: 加权平均值集成法。环境因子缩写含义见表1。

Fig. 7 Contribution of the model for Capreolus pygargus (a) and Sus scrofa (b). EMmean, Ensemble model of mean; EMmedian, Ensemble model of median; EMca, Ensemble model of consensus averaging; EMwmean, Ensemble model of weighted mean. Abbreviations for environmental factors are defined in Table 1.

图8 狍和野猪响应曲线

Fig. 8 Response curves of Capreolus pygargus and Sus scrofa

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庞泉沟国家级自然保护区狍和野猪时空共存格局

Spatiotemporal coexistence patterns of Capreolus pygargus and Sus scrofa in Pangquangou National Nature Reserve

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