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【目的】植被净初级生产力(NPP)作为陆地生态系统碳循环的重要参与者,探究其时空演变和驱动因素对促进区域生态文明建设具有重要意义。【方法】以嘉陵江流域为研究区域,基于变异系数、Theil-Median趋势法、Mann-Kendall统计检验法、R/S分析法和地理探测器和PLS-SEM模型,分析植被NPP时空演变规律及驱动因素。【结果】NPP时间上呈波动上升趋势,空间上随海拔先增后减;趋势总体稳定,波动“南高北低”,历史极显著增为主,未来分持续增和转减两类。Temp、NDVI、DEM等自然因子主导空间分异,GDP等人为影响显著;交互探测中Temp∩Pre、NDVI∩GDP和Temp∩NDVI解释力最强。PLS-SEM揭示地形通过抑制气候恶化、促进植被生长间接最大促进NPP;气候直接抑制NPP但经植被生长间接正向调节,经人类活动间接抑制;人类活动直接间接均负向。基于未来风险分区,四川盆地应优化植被与城市景观;西北高寒区构建人工-自然协同修复体系;山地丘陵区强化生态红线与廊道;全流域统筹生态补偿与水土保持工程。【结论】嘉陵江流域植被NPP以增加为主,自然因子主导空间分异,Temp∩Pre、NDVI∩GDP和Temp∩NDVI解释力最强。地形通过抑制气候恶化和促进植被生长间接促进NPP,气候直接抑制NPP但通过植被生长间接正向调节,人类活动直接和间接均抑制NPP。未来策略应着重开展分区治理。
Abstract:[Objective]Vegetation net primary productivity(NPP) is a crucial component in the carbon cycle of terrestrial ecosystems. Investigating its spatiotemporal evolution and driving factors is of great significance for promoting regional ecological civilization development.[Methods]Taking the Jialing River Basin as the study area, the spatiotemporal evolution patterns and driving factors of vegetation NPP were analyzed based on the coefficient of variation, Theil-Median trend method, Mann-Kendall statistical test, R/S analysis, geodetector, and PLS-SEM model.[Results]NPP showed a fluctuating upward trend, with spatial variation increasing and then decreasing with elevation. The overall trend remained stable, with fluctuations characterized by “higher in the south and lower in the north”. Historically, extremely significant increases predominated, while future trends were divided into two types: continuous increase and shift to decrease. Spatial differentiation was mainly dominated by natural factors such as temperature(Temp), normalized difference vegetation index(NDVI), and digital elevation model(DEM), while anthropogenic factors such as GDP also had significant effects. In interaction detection, Temp∩Pre, NDVI∩GDP, and Temp∩NDVI demonstrated the strongest explanatory power. PLS-SEM revealed that topography indirectly promoted NPP the most by inhibiting climate deterioration and promoting vegetation growth. Climate directly inhibited NPP but indirectly exerted a positive regulatory effect through vegetation growth, while indirectly inhibiting NPP through human activities. Human activities had negative effects both directly and indirectly. Based on future risk zoning, vegetation and urban landscapes should be optimized in the Sichuan Basin. A synergistic artificial-natural restoration system should be constructed in the northwest alpine area. Ecological redlines and corridors should be strengthened in mountainous and hilly areas. Ecological compensation and soil and water conservation projects should be coordinated across the entire basin.[Conclusion]Vegetation NPP in the Jialing River Basin is mainly increasing, with spatial differentiation dominated by natural factors. Temp∩Pre, NDVI∩GDP, and Temp∩NDVI have the strongest explanatory power. Topography indirectly promotes NPP by inhibiting climate deterioration and promoting vegetation growth. Climate directly inhibits NPP but indirectly regulates it positively through vegetation growth. Human activities inhibit NPP both directly and indirectly. Future strategies should focus on zoned management.
[1] LONG B Y,ZENG C L,ZHOU T,et al.Quantifying the relative importance of influencing factors on NPP in Hengduan Mountains of the Tibetan Plateau from 2002 to 2021:A Dominance Analysis[J].Ecological Informatics,2024,81:102636.
[2] 方贺,樊高峰,王阔,等.2000—2022年长江三角洲地区植被净初级生产力时空演化特征及驱动因素[J/OL].环境科学,2024:1-17.[2025-02-26].https://doi.org/10.13227/j.hjkx.202408 215.FANG H,FAN G F,WANG K,et al.Spatiotemporal variation characteristics and driving factors of vegetation NPP in the Yangtze River Delta from 2000 to 2022[J/OL].Environmental Science,2024:1-17.[2025-02-26].https://doi.org/10.13227/j.hjkx.202408215.
[3] BAI X Y,ZHANG S R,LI C J,et al.A carbon-neutrality-capacity index for evaluating carbon sink contributions[J].Environmental Science and Ecotechnology,2023,15:100237.
[4] WU Y Y,YANG J L,LI S L,et al.The impact of climate change and human activities on the spatial and temporal variations of vegetation NPP in the hilly-plain region of Shandong Province,China[J].Forests,2024,15(6):898.
[5] 宋颖,高明秀,王卓然,等.环渤海山东区耕地NPP时空变化特征及其驱动因子探测[J].环境科学,2024,45(8):4733-4743.SONG Y,GAO M X,WANG Z R,et al.Spatiotemporal variation characteristics and driving factors of cultivated land NPP in the Shandong area around the Bohai Sea[J].Environmental Science,2024,45(8):4733-4743.
[6] 肖晶,饶良懿.2001—2020年乌梁素海流域植被NPP时空变化及驱动因素分析[J].环境科学,2024,45(8):4744-4755.XIAO J,RAO L Y.Spatiotemporal variation characteristics and driving factors of vegetation NPP in the Wuliangsu Lake Basin from 2001 to 2020[J].Environmental Science,2024,45(8):4744-4755.
[7] CHEN G Z,ZHANG K Q,ZHANG X D,et al.Enhancing terrestrial net primary productivity estimation with EXP-CASA:A novel light use efficiency model approach[J].Remote Sensing of Environment,2025,326:114790.
[8] HAO L,WANG S,CUI X P,et al.Spatiotemporal dynamics of vegetation net primary productivity and its response to climate change in Inner Mongolia from 2002 to 2019[J].Sustainability,2021,13(23):13310.
[9] ZHENG Z T,ZHU W Q,ZHANG Y J.Seasonally and spatially varied controls of climatic factors on net primary productivity in alpine grasslands on the Tibetan Plateau[J].Global Ecology and Conservation,2020,21:e00814.
[10] 方浩玲,程先富,秦丽.安徽省植被净初级生产力估算—基于改进的CASA模型.生态学报,2024,44(4):1601-1612.FANG H L,CHENG X F,QIN L.Estimation of net primary productivity of vegetation in Anhui Province based on improved CASA Model.Acta Ecologica Sinica,2024,44(4):1601-1612.
[11] 石智宇,王雅婷,赵清,等.2001—2020年中国植被净初级生产力时空变化及其驱动机制分析[J].生态环境学报,2022,31(11):2111-2123.SHI Z Y,WANG Y T,ZHAO Q,et al.The spatiotemporal changes of NPP and its driving mechanisms in China from 2001 to 2020[J].Ecology and Environmental Sciences,2022,31(11):2111-2123.
[12] CAO Y,LI H W,LIU Y L,et al.Regional contribution and attribution of the interannual variation of net primary production in the Yellow River Basin,China[J].Remote Sensing,2023,15(21):5212.
[13] 杨楠,王凌雨,朱琳,等.黄河流域近十年 NPP 变化特征及驱动因子分析[J].应用基础与工程科学学报,2023,31(2):280-295.YANG N,WANG L Y,ZHU L,et al.NPP variation characteristics and driving factors of the Yellow River valley in the last decade[J].Journal of Basic Science and Engineering,2023,31(2):280-295.
[14] ZHANG Y Z,GONG J,YANG J X,et al.Evaluation of future trends based on the characteristics of net primary production (NPP) changes over 21 years in the Yangtze River Basin in China[J].Sustainability,2023,15(13):10606.
[15] 籍健勋,童新,段利民,等.内蒙古河套灌区所在流域植被NPP时空动态特征及其驱动力分析[J].环境科学,2025,46(7):4392-4402.JI J X,TONG X,DUAN L M,et al.Characterization of spatial and temporal dynamics of vegetation NPP and its driving force in the watershed of Hetao Irrigation District,Inner Mongolia[J].Environmental Science,2025,46(7):4392-4402.
[16] 王劲峰,徐成东.地理探测器:原理与展望[J].地理学报,2017,72(1):116-134.WANG J F,XU C D.Geodetector:Principle and prospective[J].Acta Geographica Sinica,2017,72(1):116-134.
[17] SONG Y Z,WANG J F,GE Y,et al.An optimal parameters-based geographical detector model enhances geographic characteristics of explanatory variables for spatial heterogeneity analysis:Cases with different types of spatial data[J].GIScience & Remote Sensing,2020,57(5):593-610.
[18] GU Z P,CHEN X W,RUAN W F,et al.Quantifying the direct and indirect effects of terrain,climate and human activity on the spatial pattern of kNDVI-based vegetation growth:A case study from the Minjiang River Basin,Southeast China[J].Ecological Informatics,2024,80:102493.
[19] 周建伟,罗君.嘉陵江流域生态系统服务价值与生态风险时空分异特征及关联性[J].重庆师范大学学报(自然科学版),2023,40(5):72-83.ZHOU J W,LUO J.Spatial-temporal differentiation characteristics and correlation of ecosystem service value and ecological risk of Jialing River Basin[J].Journal of Chongqing Normal University (Natural Science),2023,40(5):72-83.
[20] 罗旭玲,王世杰,白晓永,等.西南喀斯特地区石漠化时空演变过程分析[J].生态学报,2021,41(2):680-693.LUO X L,WANG S J,BAI X Y,et al.Analysis on the spatio-temporal evolution process of rocky desertification in Southwest Karst area[J].Acta Ecologica Sinica,2021,41(2):680-693.
[21] DING Z,LIU Y,WANG L C,et al.Effects and implications of ecological restoration projects on ecosystem water use efficiency in the karst region of Southwest China[J].Ecological Engineering,2021,170:106356.
[22] 徐勇,黄雯婷,窦世卿,等.2000—2020年西南地区植被NDVI对气候变化和人类活动响应特征[J].环境科学,2022,43(6):3230-3240.XU Y,HUANG W T,DOU S Q,et al.Responding mechanism of vegetation cover to climate change and human activities in southwest China from 2000 to 2020[J].Environmental Science,2022,43(6):3230-3240.
[23] DUAN X,CHEN B,ZHANG T X,et al.Habitat quality evolution and multi-scenario simulation based on land use change in the Jialing River Basin[J].Sustainability,2024,16(16):6968.
[24] 潘鹏飞,潘飞燕,张海旭,等.渭河流域净初级生产力遥感反演及变化归因分析[J].水利水电技术(中英文),2025,56(4):70-81.PAN P F,PAN F Y,ZHANG H X,et al.Remote sensing inversion of net primary productivity and change attribution analysis in the Weihe River Basin[J].Water Resources and Hydropower Engineering,2025,56(4):70-81.
[25] 吴丰昌.我国水体污染控制与治理成效、科技支撑与展望[J].水利发展研究,2023,23(12):1-8.WU F C.Effectiveness,scientific and technological support,and prospects for water pollution control and management in China[J].Water Resources Development Research,2023,23(12):1-8.
[26] 李国英.进一步全面深化水利改革为推动水利高质量发展、保障我国水安全作出新的贡献:在2025年全国水利工作会议上的讲话[J].水利发展研究,2025,25(1):1-12.LI G Y.Further comprehensively deepen water conservancy reform to promote high-quality development of water conservancy and safeguard national water security:A speech at the 2025 national water conservancy work conference[J].Water Resources Development Research,2025,25(1):1-12.
[27] 李国英.为以中国式现代化全面推进强国建设、民族复兴伟业提供有力的水安全保障:在2024年全国水利工作会议上的讲话[J].水利发展研究,2024,24(1):1-10.LI G Y.Improved water security for China’s efforts to build itself into a stronger country and rejuvenate the Chinese nation on all fronts by pursuing Chinese modernization:Speech at the 2024 National Water Conservancy Work Conference[J].Water Resources Development Research,2024,24(1):1-10.
[28] 王天雯,罗明良,白雷超.嘉陵江流域生态系统服务动态变化及权衡协同分析[J].生态环境学报,2025,34(6):888-901.WANG T W,LUO M L,BAI L C.Dynamic changes and trade-off-synergy analysis of ecosystem services in the Jialing River Basin[J].Ecology and Environmental Sciences,2025,34(6):888-901.
[29] LIU C,SHI S,WANG T,et al.Analysis of net primary productivity variation and quantitative assessment of driving forces:A case study of the Yangtze River Basin [J].Plants,2023,12(19):3412.
[30] ZHANG F Y,ZHANG Z X,KONG R,et al.Changes in forest net primary productivity in the Yangtze River Basin and its relationship with climate change and human activities[J].Remote Sensing,2019,11(12):1451.
[31] 向晓宇.嘉陵江流域植被NPP时空变化与驱动力研究[D].成都:成都理工大学,2021.XIANG X Y.Study on the SPATIO-TEMPORAL VARIATION and Driving Force of Vegetation NPP in Jialing River Basin[D].Chengdu:Chengdu University of Technology,2021.
[32] 邓小菲,杜华明,王雪梅,等.涪江流域植被净初级生产力时空变化及对气候的响应[J].重庆师范大学学报(自然科学版),2024,41(3):47-58.DENG X F,DU H M,WANG X M,et al.Spatio-temporal variation of net primary productivity of vegetation and its response to climate in Fujiang River Basin[J].Journal of Chongqing Normal University (Natural Science),2024,41(3):47-58.
[33] ZHOU Y Y,YUE D X,LI C,et al.Identifying the spatial drivers of net primary productivity:A case study in the Bailong River Basin,China[J].Global Ecology and Conservation,2021,28:e01685.
[34] 汪士为,吴伟.近31年嘉陵江流域生态环境质量时空演变及驱动因子探测[J].水土保持研究,2024,31(1):427-439.WANG S W,WU W.Spatiotemporal variation of ecological environmental quality and its response to different driving factors in Jialing River Basin in recent 31 years[J].Research of Soil and Water Conservation,2024,31(1):427-439.
[35] ZHANG Y,HU Q W,ZOU F L.Spatio-temporal changes of vegetation net primary productivity and its driving factors on the Qinghai-Tibetan Plateau from 2001 to 2017[J].Remote Sensing,2021,13(8):1566.
[36] 王芳,汪左,张运.2000—2015年安徽省植被净初级生产力时空分布特征及其驱动因素[J].生态学报,2018,38(8):2754-2767.WANG F,WANG Z,ZHANG Y.Spatio-temporal variations in vegetation Net Primary Productivity and their driving factors in Anhui Province from 2000 to 2015[J].Acta Ecologica Sinica,2018,38(8):2754-2767.
[37] 徐勇,黄海艳,戴强玉,等.西南地区陆地植被生态系统NPP时空演变及驱动力分析[J].环境科学,2023,44(5):2704-2714.XU Y,HUANG H Y,DAI Q Y,et al.Spatial-temporal variation in net primary productivity in terrestrial vegetation ecosystems and its driving forces in southwest China[J].Environmental Science,2023,44(5):2704-2714.
[38] LU Z W,CHEN P W,YANG Y R,et al.Exploring quantification and analyzing driving force for spatial and temporal differentiation characteristics of vegetation net primary productivity in Shandong Province,China[J].Ecological Indicators,2023,153:110471.
[39] 彭大力,张斌,吴林蓬,等.龙川江流域近20年土壤侵蚀时空变化及驱动因素分析[J].水土保持学报,2024,38(4):29-37.PENG D L,ZHANG B,WU L P,et al.Analysis of spatial and temporal changes and driving factors of soil erosion in Longchuan River Basin in recent 20 years[J].Journal of Soil and Water Conservation,2024,38(4):29-37.
[40] 高翻翻,向洋,王诗媛,等.基于地理探测器和PLS-SEM的藏东南植被变化及驱动因子分析[J].环境科学与技术,2024,47(12):225-236.GAO F F,XIANG Y,WANG S Y,et al.Analysis of vegetation change and driving factors in southeastern Tibet based on geographical detector and PLS-SEM[J].Environmental Science & Technology,2024,47(12):225-236.
[41] HENSELER J,SARSTEDT M.Goodness of fit indices for partial least squares path modeling[J].Computational statistics,2013,28(2):565-580.
[42] JIA L,YU K,LI Z,et al.Spatiotemporal pattern of NPP and its response to climatic factors in the yangtze river economic belt [J].Ecological Indicators,2024,162:112017.
[43] 四川省农业农村厅.聚力整区域推进农田建设打造更高水平“天府粮仓”[J].中国农业综合开发,2024(9):11.whole region to promote farmland construction to build a higher level of “Tianfu Granary” [J].Agricultural ComPrehensive Development in China,2024,(9):11.
[44] JIA L,YU K X,LI Z B,et al.Spatiotemporal pattern of NPP and its response to climatic factors in the Yangtze River Economic Belt[J].Ecological Indicators,2024,162:112017.
[45] 李红英,张存桂,汪生珍,等.近40年青藏高原植被动态变化对水热条件的响应[J].生态学报,2022,42(12):4770-4783.LI H Y,ZHANG C G,WANG S Z,et al.Response of vegetation dynamics to hydrothermal conditions on the Qinghai-Tibet Plateau in the last 40 years[J].Acta Ecologica Sinica,2022,42(12):4770-4783.
[46] ZHANG M Y,WANG K L,LIU H Y,et al.Vegetation inter-annual variation responses to climate variation in different geomorphic zones of the Yangtze River Basin,China[J].Ecological Indicators,2023,152:110357.
[47] CHEN S S,MA M H,WU S J,et al.Topography intensifies variations in the effect of human activities on forest NPP across altitude and slope gradients[J].Environmental Development,2023,45:100826.
[48] QIU H H,HU B Q,ZHANG Z.Impacts of land use change on ecosystem service value based on SDGs report:Taking Guangxi as an example[J].Ecological Indicators,2021,133:108366.
[49] 张炜,刘亦飞,沈明星,等.长江流域植被净初级生产力时空动态特性及影响因素分析[J].水利水电技术(中英文),2022,53(10):165-176.ZHANG W,LIU Y F,SHEN M X,et al.Spatiotemporal variation of net primary productivity and response to climatic factors in the Yangtze River Basin[J].Water Resources and Hydropower Engineering,2022,53(10):165-176.
[50] 冯婉.基于CASA模型和CMIP6模式的长江流域植被NPP时空分异及预测[D].重庆:西南大学,2022.FENG W.Spatio-Temporal Differentiation and Prediction of Vegetation NPP in the Yangtze River Basin Based on CASA Model and CMP6 model[D].Chongqing:Southwest University,2022.
[51] 孔维华.长江流域植被固碳时空变化及其影响因素[D].杨凌:西北农林科技大学,2024.KONG W H.Spatial and Temporal Changes in Carbon Sequestration by Vegetation in the Yangtze River Basin and Its Influencing Factors[D].Yangling:Northwest A & F University,2024.
[52] 武爱彬,陈辅国,尤海舟,等.京津冀地区植被净初级生产力时空变化特征及影响因素分析[J/OL].环境科学,2025:1-19.[2025-03-07].https://link.cnki.net/doi/10.13227/j.hjkx.2024 11179.WU A B,CHEN F G,YU H Z,et al.Characterization of spatial and temporal changes in net primary productivity of vegetation in the Beijing-Tianjin-Hebei region and analysis of influencing factors[J/OL].Environmental Science,1-19.[2025-03-07].https://doi.org/10.13227/j.hjkx.202411179.
[53] 张仲芝,赵俊三,陈国平,等.基于OPGD模型的昆明市植被NPP时空演变及驱动机制[J].水土保持学报,2025,39(2):298-308.ZHANG Z Z,ZHAO J S,CHEN G P,et al.Spatiotemporal evolution of NPP and its influencing factors in Kunming City based on the OPGD model[J].Journal of Soil and Water Conservation,2025,39(2):298-308.
[54] GONG J,JIN T T,LIU D Q,et al.Are ecosystem service bundles useful for mountainous landscape function zoning and management?A case study of Bailongjiang watershed in western China[J].Ecological Indicators,2022,134:108495.
[55] WANG Y X,GONG J,ZHU Y H.Integrating social-ecological system into watershed ecosystem services management:A case study of the Jialing River Basin,China[J].Ecological Indicators,2024,160:111781.
[56] LUO Q L,ZHOU J F,ZHANG Y,et al.What is the spatiotemporal relationship between urbanization and ecosystem services?A case from 110 cities in the Yangtze River Economic Belt,China[J].Journal of Environmental Management,2022,321:115709.
[57] DAI T R,DAI X A,LU H,et al.The impact of climate change and human activities on the change in the net primary productivity of vegetation:Taking Sichuan Province as an example[J].Environmental Science and Pollution Research,2024,31(5):7514-7532.
基本信息:
DOI:10.13928/j.cnki.wrahe.2025.08.005
中图分类号:X171.1;Q948
引用信息:
[1]戴前坤,杨海青,郭子钰,等.嘉陵江流域植被NPP时空演变及驱动因素探究[J].水利水电技术(中英文),2025,56(08):61-77.DOI:10.13928/j.cnki.wrahe.2025.08.005.
基金信息:
西华师范大学博士启动项目(21E021); 国家自然科学基金项目(42104089)
2025-06-24
2025-06-24
2025-06-24