典型“高山-绿洲-荒漠”生态区植被净初级生产力时空变化特征分析

doi:10.3964/j.issn.1000-0593(2022)08-2595-08

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摘要： “高山-绿洲-荒漠”作为干旱区独特的自然景观，其内部迥异的生态系统极易在全球变化影响下产生不同波动，而植被净初级生产力（NPP）作为评价生态环境质量的重要指标，对整体认识区域变化有重要意义。遥感影像的产生为大尺度、长时间的区域NPP估算提供了可能，通过土地利用类型数据划分的不同植物覆被下的最大光能利用效率也提高了NPP估算的精度。因此选取具有典型“高山-绿洲-荒漠”生态系统的叶尔羌河流域作为研究区，使用多年遥感影像数据、气象数据，选用基于光能利用率的CASA模型对其进行模拟并对各生态区NPP状况进行分析，得出以下结论：(1) 叶尔羌河流域NPP年均值在2000年之后整体呈波动上升状态，约有85.9%的区域呈上升趋势，在绿洲区域的水域以及居住地处NPP出现下降状况。(2) 流域内NPP变化与降水量相关性较强，其空间分布特征与NPP和温度的相关性表现出相反状态。(3) 叶尔羌河流域NPP在各生态区上表现出“绿洲最高，荒漠绿洲过渡带次之，高山以及荒漠最低”的状况，生态环境相对绿洲、荒漠绿洲过渡带更为脆弱的区域（荒漠、高山）NPP波动性更强。研究结果将为区域生态环境保护修复、应对气候变化、实现人类与自然协调发展、促进多民族共同繁荣提供科学支撑。

关键词：干旱区；绿洲；NPP；CASA模型；时空变化

Abstract：“Alpine-oasis-desert” is a unique natural landscape in arid areas, its internally distinct ecosystems are prone to different fluctuations under global change. As an important indicator to evaluate the quality of the ecological environment, vegetation net primary productivity ( NPP ) is of great significance to the overall understanding of regional changes. The generation of remote sensing images allows large-scale and long-term regional NPP estimation. The maximum light energy utilization efficiency under different plant covers classified by land-use type data also improves the accuracy of NPP estimation. Therefore, this paper selects the Yarkand River Basin with a typical alpine-oasis-desert ecosystem as the study area, using remote sensing image data and meteorological data for many years, selecting the CASA model based on light utilization rate simulate and analyze the NPP status of each ecological area. The following conclusions were drawn: (1) The annual average value of NPP in the Yarkand River Basin showed a fluctuating upward trend after 2 000, and about 85.9 % of the regions showed an upward trend. In the water area and the residential location of the oasis area, the NPP decreased. (2) The variation of NPP in the basin strongly correlations with precipitation, and its spatial distribution characteristics have an opposite correlation with NPP and temperature. (3) NPP in the Yarkand River Basin showed the highest in the oasis, followed by the desert-oasis transition zone, and the lowest in the alpine and desert regions. The fluctuation of NPP in the regions with relatively more fragile ecosystems (desert and alpine) was more substantial than that in the oasis and desert-oasis transition zone. The research results will provide theoretical support for restoring regional ecological environment protection, the response to climate change, the coordinated development of human beings and nature, and the promotion of multi-ethnic common prosperity.

Key words：Arid region;Oasis;NPP;CASA model;Temporal and spatial changes

收稿日期: 2021-06-16 修订日期: 2021-10-18

中图分类号:

TP79

基金资助: 国家自然科学基金项目(41901022)资助

通讯作者: 孙从建 E-mail: suncongjian@sina.com

作者简介: 乔鹏，1996年生，山西师范大学地理科学学院硕士研究生 e-mail: 1057310285@qq.com

引用本文:

乔鹏，孙从建，李亚新，周思捷，陈亚宁. 典型“高山-绿洲-荒漠”生态区植被净初级生产力时空变化特征分析[J]. 光谱学与光谱分析, 2022, 42(08): 2595-2602.
QIAO Peng, SUN Cong-jian, LI Ya-xin, ZHOU Si-jie, CHEN Ya-ning. Analysis on Temporal and Spatial Changes of Vegetation Net Primary Productivity in Typical “Alpine-Oasis-Desert” Ecological Region. SPECTROSCOPY AND SPECTRAL ANALYSIS, 2022, 42(08): 2595-2602.

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