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定量分析青藏高原东部典型亚高山地区植被恢复及其潜在驱动因素。

Quantitative analysis of vegetation restoration and potential driving factors in a typical subalpine region of the Eastern Tibet Plateau.

机构信息

College of Earth Sciences, Chengdu University of Technology, Chengdu, China.

College of Tourism and Urban-Rural Planning, Chengdu University of Technology, Chengdu, China.

出版信息

PeerJ. 2022 Apr 28;10:e13358. doi: 10.7717/peerj.13358. eCollection 2022.

DOI:10.7717/peerj.13358
PMID:35505680
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9057294/
Abstract

Vegetation restoration is an essential approach to re-establish the ecological balance in subalpine areas. Changes in vegetation cover represent, to some extent, vegetation growth trends and are the consequence of a complex of different natural factors and human activities. Microtopography influences vegetation growth by affecting the amount of heat and moisture reaching the ground, a role that is more pronounced in subalpine areas. However, little research is concerned with the characteristics and dynamics of vegetation restoration in different microtopography types. The respective importance of the factors driving vegetation changes in subalpine areas is also not clear yet. We used linear regression and the Hurst exponent to analyze the trends in vegetation restoration and sustainability in different microtopography types since 2000, based on Fractional Vegetation Cover (FVC) and identified potential driving factors of vegetation change and their importance by using Geographical Detector. The results show that: (1) The FVC in the region under study has shown an up-trend since 2000, and the rate of increase is 0.26/year ( = 0.028). It would be going from improvement to degradation, continuous decrease or continuous significant decrease in 47.48% of the region, in the future. (2) The mean FVC is in the following order: lower slope (cool), lower slope, lower slope (warm), valley, upper slope (warm), upper slope, valley (narrow), upper slope (cool), cliff, mountain/divide, peak/ridge (warm), peak/ridge, peak/ridge (cool). The lower slope is the microtopographic type with the best vegetation cover, and ridge peak is the most difficult to be afforested. (3) The main factors affecting vegetation restoration in subalpine areas are aspect, microtopographic type, and soil taxonomy great groups. The interaction between multiple factors has a much stronger effect on vegetation cover than single factors, with the effect of temperatures and aspects having the most significant impact on the vegetation cover changes. Natural factors have a greater impact on vegetation restoration than human factors in the study area. The results of this research can contribute a better understanding of the influence of different drivers on the change of vegetation cover, and provide appropriate references and recommendations for vegetation restoration and sustainable development in typical logging areas in subalpine areas.

摘要

植被恢复是恢复亚高山地区生态平衡的重要方法。植被覆盖的变化在一定程度上代表了植被生长趋势,是多种自然因素和人类活动的综合结果。微地形通过影响到达地面的热量和水分的数量来影响植被生长,这种作用在亚高山地区更为明显。然而,很少有研究关注不同微地形类型中植被恢复的特征和动态。亚高山地区驱动植被变化的因素的相对重要性也尚不清楚。我们使用线性回归和赫斯特指数分析了 2000 年以来不同微地形类型中植被恢复和可持续性的趋势,基于分数植被覆盖(FVC),并通过地理探测器确定了植被变化的潜在驱动因素及其重要性。结果表明:(1)研究区植被 FVC 自 2000 年以来呈上升趋势,增长率为 0.26/年(=0.028)。在未来,该地区 47.48%的区域可能会从改善转变为退化、持续减少或持续显著减少。(2)平均 FVC 顺序为:缓坡(冷)、缓坡、缓坡(暖)、山谷、陡坡(暖)、陡坡、山谷(窄)、陡坡(冷)、悬崖、山脊/分水岭(暖)、山脊/分水岭、山脊/分水岭(冷)。缓坡是植被覆盖最好的微地形类型,而山顶是最难造林的。(3)影响亚高山地区植被恢复的主要因素是坡向、微地形类型和土壤分类大纲巨群。多个因素的相互作用对植被覆盖的影响比单个因素要强得多,温度和坡向对植被覆盖变化的影响最大。在研究区域中,自然因素对植被恢复的影响大于人为因素。本研究结果可以更好地理解不同驱动因素对植被覆盖变化的影响,为亚高山地区典型采伐区的植被恢复和可持续发展提供适当的参考和建议。

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Dynamic change of vegetation and its response to climate and topographic factors in the Xijiang River basin, China.中国西江流域植被动态及其对气候和地形因素的响应。
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