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[1]杜波波,阿拉腾图娅,包刚,等.基于CASA模型模拟锡林郭勒草原净初级生产力[J].水土保持研究,2021,28(05):293-300.
　DU Bobo,Alatengtuya,BAO Gang,et al.Simulation of Net Primary Productivity of Xilingol Grassland Based on CASA Model[J].Research of Soil and Water Conservation,2021,28(05):293-300.

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基于CASA模型模拟锡林郭勒草原净初级生产力

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 28 期数: 2021年05期页码: 293-300 栏目: 出版日期: 2021-08-20

Title:: Simulation of Net Primary Productivity of Xilingol Grassland Based on CASA Model

文章编号:: 1005-3409(2021)05-0293-08

作者:: 杜波波¹,阿拉腾图娅^2,3,包刚^2,3,王宁¹,林克剑¹; (1.中国农业科学院草原研究所,呼和浩特 010010; 2.内蒙古师范大学地理科学学院,呼和浩特 010022; 3.内蒙古自治区遥感与地理信息系统重点实验室,呼和浩特 010022)

Author(s):: DU Bobo¹,Alatengtuya^2,3,BAO Gang^2,3,WANG Ning¹,LIN Kejian¹; (1.Institute of Grassland Research of CAAS,Hohhot 010010,China; 2.College of Geographical Science,Inner Mongolia Normal University,Hohhot 010022,China; 3.Inner Mongolia Key Laboratory of Remote Sensing and Geograph Information System,Hohhot 010022,China)

关键词:: CASA模型; 锡林郭勒草原; 植被净初级生产力; 最大光能利用率

Keywords:: CASA model; Xilingol grasslands; net primary productivity; maximum light use efficiency

分类号:: TP79; P426.68

文献标志码:: A

摘要:: 随着气候变暖,生态环境发生了巨大的变化,植被净初级生产力(Net Primary Productivity,NPP)作为反映生态质量的重要指标被广泛应用于生态监测。为探究2001—2018年锡林郭勒草原生长季NPP对气候变化的响应,利用CASA模型对锡林郭勒草原NPP进行模拟。结果表明:过去18年,锡林郭勒草甸草原NPP显著性增加,4种植被类型的NPP年际变化较大; NPP东西差异明显,从东向西递减,与区域的植被类型高度吻合。温度和降水是导致NPP时空变化的主要因素,整体上NPP与温度呈显性著负相关(r=-0.629,p=0.05,N=18),与降水呈显著性正相关关系(r=0.913,p<0.001,N=18); 对不同植被类型而言,降水和温度对NPP的影响也存在差异:草甸草原、荒漠草原受温度和降水量共同作用,而典型草原、沙地植被主要受降水量的影响,与温度的相关性较低,且不显著。从空间上看,研究区大部分地区受降水的影响,受温度影响的区域主要集中在研究区西部、中间北部以及东北地区,植被类型主要为荒漠草原、小部分典型草原及部分草甸草原。

Abstract:: With the change of climate,the global ecological environment has changed greatly. Net primary productivity(NPP),as an important index to reflect the ecological quality,has been widely used in the ecological monitoring. In order to investigate the response of NPP to climate change in growing season in Xilingol grassland from 2001 to 2018,the NPP of Xilingol grassland was simulated by CASA model. The results show that,in the past 18 years,the NPP in the grassland of the Xilingol meadow had the significant increase,and the interannual variation of NPP in the four types of vegetation was larger; the difference of NPP was obvious,decreasing from the east to the west,and was agreement with the vegetation type. The temperature and precipitation were the main factors causing NPP space-time variation,and the overall NPP was negatively correlated with the temperature dominant(r=-0.629,p=0.05,N =18),which was positively correlated with the precipitation significance(r =0.913,p< 0.001,N =18). For different vegetation types,the effects of precipitation and temperature on NPP were also different. Meadow grassland and desert grassland were affected by temperature and precipitation,while typical grassland and sandy land vegetation were mainly affected by precipitation,and the correlation with temperature was low and not significant. From the perspective of space,most areas of the whole area were affected by precipitation. The areas affected by temperature mainly concentrated on the desert grassland in the west,the typical grassland in the middle and the grassland in the northeast of the research area.

参考文献/References:

[1] 朴世龙,方精云,郭庆华.利用CASA模型估算我国植被净第一性生产力[J].植物生态学报,2001,25(5):603-608,644.
[2] 朱文泉,陈云浩,徐丹,等.陆地植被净初级生产力计算模型研究进展[J].生态学杂志,2005,24(3):296-300.
[3] 潘竟虎,李真.2001—2012年西北干旱区植被净初级生产力时空变化[J].生态学杂志,2015,34(12):3333-3340.
[4] Wen Y,Liu X,Bai Y,et al. Determining the impacts of climate change and urban expansion on terrestrial net primary production in China[J]. Journal of Environmental Management,2019,240:75-83.
[5] Ruimy A,Kergoat L,Bondeau A,et al. Comparing global models of terrestrial net primary productivity(NPP):analysis of differences in light absorption and light-use efficiency[J]. Global Change Biology,1999,5(S1):56-64.
[6] Zhu W,Pan Y,Liu X,et al. Spatio-temporal distribution of net primary productivity along the northeast China transect and its response to climatic change[J]. Journal of Forestry Research,2006,17(2):93-98.
[7] Kazanjian G,Velthuis M,Aben R,et al. Impacts of warming on top-down and bottom-up controls of periphyton production[J]. Scientific Reports,2018,8(1):1-12.
[8] 于德永,潘耀忠,姜萍,等.东亚地区植被净第一性生产力对气候变化的时空响应[J].北京林业大学学报,2005,27(2):96-101.
[9] Bao G,Bao Y,Qin Z,et al. Modeling net primary productivity of terrestrial ecosystems in the semi-arid climate of the Mongolian Plateau using LSWI-based CASA ecosystem model[J]. International Journal of Applied Earth Observation and Geoinformation,2016,46:84-93.
[10] 王亚林,龚容,吴凤敏,等.2001—2013年中国灌木生态系统净初级生产力的时空变化特征及其对气候变化的响应[J].植物生态学报,2017,41(9):925-937.
[11] 杨勇,李兰花,王保林,等.基于改进的CASA模型模拟锡林郭勒草原植被净初级生产力[J].生态学杂志,2015,34(8):2344-2352.
[12] Potter C S,Randerson J T,Field C B,et al. Terrestrial ecosystem production:a process model based on global satellite and surface data[J]. Global Biogeochemical Cycles,1993,7(4):811-841.
[13] 张圣微,申芮,陈哲,等.锡林郭勒草原植被生产力估算及其影响因素:以巴拉噶尔河流域为例[J].中国草地学报,2015,37(4):66-73.
[14] 彭少麟,郭志华,王伯荪.利用GIS和RS估算广东植被光利用率[J].生态学报,2000,20(6):903-909.
[15] 朱文泉,潘耀忠,张锦水.中国陆地植被净初级生产力遥感估算[J].植物生态学报,2007,31(3):413-424.
[16] Yu D,Shi P,Shao H,et al. Modelling net primary productivity of terrestrial ecosystems in East Asia based on an improved CASA ecosystem model[J]. International Journal of Remote Sensing,2009,30(18):4851-4866.
[17] 包刚,辛晓平,包玉海,等.内蒙古草原植被最大光能利用率取值优化研究[J].光谱学与光谱分析,2016,36(10):3280-3286.
[18] Zhang M,Lal R,Zhao Y,et al. Estimating net primary production of natural grassland and its spatio-temporal distribution in China[J]. Science of the Total Environment,2016,553:184-195.
[19] Sun C,Zhong X,Chen C,et al. Evaluating the grassland net primary productivity of southern China from 2000 to 2011 using a new climate productivity model[J]. Journal of Integrative Agriculture,2016,15(7):1638-1644.
[20] Zhang G,Kang Y,Han G,et al. Effect of climate change over the past half century on the distribution,extent and NPP of ecosystems of Inner Mongolia[J]. Global Change Biology,2011,17(1):377-389.
[21] Myneni R B,Keeling C D,Tucker C J,et al. Increased plant growth in the northern high latitudes from 1981 to 1991[J]. Nature,1997,386(6626):698-702.
[22] Zhao M,Running S W. Drought-induced reduction in global terrestrial net primary production from 2000 through 2009[J]. Science,2010,329(5994):940-943.
[23] Li C,Leal Filho W,Yin J,et al. Assessing vegetation response to multi-time-scale drought across inner Mongolia plateau[J]. Journal of Cleaner Production,2018,179:210-216.
[24] Shi Z,Lin Y,Wilcox K R,et al. Successional change in species composition alters climate sensitivity of grassland productivity[J]. Global Change Biology,2018,24(10):4993-5003.
[25] 张珺,任鸿瑞.人类活动对锡林郭勒盟草原净初级生产力的影响研究[J].自然资源学报,2017,32(7):1125-1133.
[26] Piao S,Fang J,Zhou L,et al. Changes in biomass carbon stocks in China's grasslands between 1982 and 1999[J]. Global Biogeochemical Cycles,2007,21(2):1-10.
[27] Liu W,Feng Q,Zhang F. Spatial-temporal variation characteristics of NPP in the Heihe River Basin,northwestern China,in a recent 10-year period calculated by casa model[J]. Journal of Coastal Research,2017,80:36-47.
[28] 张美玲,陈全功,闫培洁.中国天然草地净初级生产力时空分布[J].草地学报,2018,26(5):1124-1131.
[29] Li Y,Qin Y. The response of net primary production to climate change:A case study in the 400 mm annual precipitation fluctuation zone in China[J]. International Journal of Environmental Research and Public Health,2019,16(9):1497,https://doi.org/10,3390/ijerph16091497.
[30] Morel A C,Adu Sasu M,Adu-Bredu S,et al. Carbon dynamics,net primary productivity and human-appropriated net primary productivity across a forest-cocoa farm landscape in West Africa[J]. Global Change Biology,2019,25(8):2661-2677.

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备注/Memo

收稿日期:2020-10-15 修回日期:2020-11-03
资助项目:国家自然科学基金(41261099); 内蒙古自然科学(2017MS0402); 内蒙古自治区研究生教育创新计划(CXJJS1898); 内蒙古师范大学研究生科研创新基金(CXJJS1898); 新疆草原主要害虫智能识别与监测技术研究(1610332020026)
第一作者:杜波波(1993—),男,内蒙古包头市人,硕士,助理研究员,研究方向为资源与环境遥感。E-mail:dubobo@caas.cn
通信作者:阿拉腾图娅(1969—),女(蒙古族),内蒙古呼和浩特市人,硕士,教授,主要从事资源与环境遥感研究。E-mail:altty@imnu.edu.cn

更新日期/Last Update: 2021-08-20