Assessment of the effects of the shelterbelt on the soil temperature at regional scale based on MODIS data

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• 作者：Rong-xin Deng (1) (2)
  Ying Li (1)
  Shu-wen Zhang (1)
  Wen-juan Wang (3)
  Xiao-liang Shi (1) (2)
  
• 关键词：regional scale ; remote sensing ; shelterbelt ; temperature effect
• 刊名：Journal of Forestry Research
• 出版年：2011
• 出版时间：March 2011
• 年：2011
• 卷：22
• 期：1
• 页码：65-70
• 全文大小：487KB
• 参考文献：1. Alavalapati JRR, Mercer DE, Montambault J. 2004. Agrogorestry systems and valuation methodologies: an overview. In: Alavalapati JRR, Mercer DE (eds.), / Valuing Agroforestry Systems: Methods and Applications, Springer Netherlands, pp 1-
  2. Brandle JR, Hodges L, Zhou XH. 2004. Windbreaks in North American agricultural systems. / Agrofor Syst, 61: 65-8 CrossRef
  3. Campi P, Palumbo AD, Mastrorilli M. 2009. Effects of tree windbreak on microclimate and wheat productivity in a Mediterranean environment. / Europ J Agronomy, 30: 220-27 CrossRef
  4. Cleugh HA. 1998. Effects of windbreaks on airflow, microclimates and crop yields. / Agrofor Syst, 41: 55-4 CrossRef
  5. Cleugh HA, Miller JM, Bohm M. 1998. Direct mechanical effects of wind on crops. / Agrofor Syst, 41: 85-12 CrossRef
  6. Fan ZP, Zeng DH, Zhu JJ, Jiang FQ, Yu XX. 2002. Advance in characteristics of ecological effects of farmland shelterbelts. / J Soil Water Conserv, 16(4): 130-33
  7. Garrett HEG. 1997. Agroforestry: an integrated land-use management system for production and farmland conservation. [United States Department of Agriculture Soil Conservation Service [USDASCS] Report 68-3A7S-3-134]. Fort Collins, CO: USDA-SCS.
  8. Jose S, Gordon AM. 2008. Ecological knowledge and agroforestry design: an introduction. In: Jose S, Gordon AM (eds.), / Toward Agroforestry Design: an ecological approach, Springer, Netherlands, pp 3-2
  9. McNaughton KG. 1988. Effects of windbreaks on turbulent transport and microclimate. / Agr Ecosyst Environ, 22/23: 17-0 CrossRef
  10. Mulati Y, Norio T. 2009. Effects of windbreak width in wind direction on wind velocity reduction. / J For Res, 20(3): 199-01 CrossRef
  11. Nelmes S, Belcher RE, Wood CJ. 2001. A method for routine characterization of shelterbelt. / Agric For Meteorol, 106: 303-15 CrossRef
  12. Netzband M, Stefanov WL, Redman CL. 2007. Remote sensing as a tool for urban planning and sustainability. In: Netzband M, Stefanov WL, Redman CL (eds.), Applied remote sensing for urban planning, Governance and Sustainability. Springer Berlin Heidelberg, pp: 1-3
  13. Wang HF, Lei JQ, Li SY, Fan JL, Li YG, Sun SG, Chang Q. 2008. Effect of the shelterbelt along the Tarim Desert Highway on air temperature and humidity. / Chin Science Bull, 53: 41-2 CrossRef
  14. Zhang SW, Zhang YZ, Li Y, Chang LP. 2006. / Analysis on spatial-temporal features of land use/land cover in northeastern China. Beijing: Science Press, 58-9.
  
• 作者单位：Rong-xin Deng (1) (2)
  Ying Li (1)
  Shu-wen Zhang (1)
  Wen-juan Wang (3)
  Xiao-liang Shi (1) (2)
  
  1. Northeast Institute of Geography and Agriculture Ecology, CAS, Changchun, 130012, China
  2. Graduated School of Chinese Academy of Science, Beijing, 100049, China
  3. Department of Resources and Environmental Sciences, Henan University of Finance and Economics, Zhengzhou, 450002, China
  

文摘

At present, the most researches on the protected effect of shelterbelt are on the basis of the two scales of forest belts and networks. However, with the further research on the global environmental change, more attention was paid to the regional climate effect of shelterbelt. In present study, we analyzed the temperature effect of the shelterbelt at regional scale by using the land surface temperature (LST) data from the moderate resolution imaging spectroradiometer (MODIS) at Yushu, Nong’an, Dehui, and Fuyu in Jilin Province of China from March to October in 2008. Results show that the shelterbelt can increase the soil temperature of the protected farmland as compared with no shelterbelt zone, with the increment of 0.57°C per day in fine shelterbelt and 0.38°C per day in the normal shelterbelt. Moreover, the correlation analysis of the air temperature, precipitation and the soil type and the shelterbelt effect shows that the air temperature and precipitation are negatively correlated with the shelterbelt effects, that is, the more the temperature and precipitation are, the less the effect produced. While the impact of the soil types on the shelterbelt’s effect is not very obvious as a whole. This paper draws significance in terms of analyzing the effects of the shelterbelt on the soil temperature at regional scale utilizing the remotely sensed data and GIS technique.