热红外遥感浙江地表热环境分布研究

吴文渊; 金城; 庞毓雯; 赵丽佳; 宋瑜; 胡潭高; 张登荣; 徐俊锋

doi:10.11834/jrs.20197339

遥感应用 | 浏览量 : 0 下载量: 103 CSCD: 5 更多指标

PDF
导出
分享
收藏
专辑

热红外遥感浙江地表热环境分布研究
Distribution characteristics of surface thermal environment in Zhejiang province based on thermal infrared remote sensing
2019年23卷第4期页码：796-808
纸质出版日期： 2019-7 ，

录用日期： 2018-3-14
DOI： 10.11834/jrs.20197339

扫描看全文

吴文渊, 金城, 庞毓雯, 赵丽佳, 宋瑜, 胡潭高, 张登荣, 徐俊锋. 2019. 热红外遥感浙江地表热环境分布研究. 遥感学报, 23(4): 796–808

Wu W Y, Jin C, Pang Y W, Zhao L J, Song Y, Hu T G, Zhang D R and Xu J F. 2019. Distribution characteristics of surface thermal environment in Zhejiang province based on thermal infrared remote sensing. Journal of Remote Sensing, 23(4): 796–808
吴文渊, 金城, 庞毓雯, 赵丽佳, 宋瑜, 胡潭高, 张登荣, 徐俊锋. 2019. 热红外遥感浙江地表热环境分布研究. 遥感学报, 23(4): 796–808 DOI： 10.11834/jrs.20197339.

Wu W Y, Jin C, Pang Y W, Zhao L J, Song Y, Hu T G, Zhang D R and Xu J F. 2019. Distribution characteristics of surface thermal environment in Zhejiang province based on thermal infrared remote sensing. Journal of Remote Sensing, 23(4): 796–808 DOI： 10.11834/jrs.20197339.

摘要

全球气候变暖与人类戚戚相关，研究发现不仅是城市的热岛效应引起了局部区域的地表热环境分布差异，很多地质构造、岩性、土壤、植被等地质及自然地理因素也有影响。本研究选取浙江省作为研究区，利用Landsat 8 OLI/TIRS遥感影像反演地表温度，分析冬季地表热环境分布及其影响因子。结果表明，断裂带附近地表热环境受到断裂带分布影响；岩石和土壤通过不同的地表覆被类型影响地表温度。地表热环境分布与断裂带等自然因素存在一定相关性。

Abstract

Land surface thermal environment is an important factor in the surface ecological environment and is related to human survival and society development. Similar to the heat island effect in urban areas

some high temperatures are detected beside active faults in the region of natural surface and are affected by the lithology

soil

and vegetation. Therefore

these geological and geographical factors impact the land surface thermal environment. In our research

we investigated the distribution characteristics of surface thermal environment in Zhejiang Province on the basis of land surface temperature through thermal infrared remote sensing of Landsat 8 OLI/TIRS images. We analyzed the effects of fault activity

lithology

soil

and vegetation on the land surface thermal environment by using multiple linear regression analysis. Results showed that the active faults could cause thermal anomalies within a certain distance

the rocks and soils could affect land surface temperature depending on their cover types

and the vegetation coverage could reduce the effect of high temperature in the surface thermal environment. In conclusion

the proposed method is effective for tectonic activity monitoring and can serve as a scientific basis of research on ecological environment.

关键词

热红外遥感地表热环境断裂带

Keywords

inferred remote sensingsurface thermal environmentfault zones

references

Allis R G, Nash G D and Johnson S D. 1999. Conversion of thermal infrared surveys to heat flow: comparisons from Dixie Valley, Nevada, and Wairakei, New Zealand. Geothermal Resources Council Transactions, 23: 499–504

Artis D A and Carnahan W H. 1982. Survey of emissivity variability in thermography of urban areas. Remote Sensing of Environment, 12(4): 313–329

Becker F and Li Z L. 1995. Surface temperature and emissivity at various scales: definition, measurement and related problems. Remote Sensing Reviews, 12(3/4): 225–253

陈志强, 陈健飞. 2006. 基于NDBI指数法的城镇用地影像识别分析与制图. 地球信息科学, 8(2): 137–140

Chen Z Q and Chen J F. 2006. Investigation on extracting the space information of urban land-use from high spectrum resolution image of ASTER by NDBI method. Geo-Information Science, 8(2): 137–140

Coolbaugh M F, Kratt C, Fallacaro A, Calvin W M and Taranik J V. 2007. Detection of geothermal anomalies using advanced spaceborne thermal emission and reflection radiometer (ASTER) thermal infrared images at Bradys Hot Springs, Nevada, USA. Remote Sensing of Environment, 106(3): 350–359

丁凤, 徐涵秋. 2006. TM热波段图像的地表温度反演算法与实验分析. 地球信息科学, 8(3): 125–130

Ding F, Xu H Q. 2006. Comparison of two new algorithms for retrieving land surface temperature from Landsat TM thermal band. Geo-Information Science, 8(3): 125–130

丁凤, 徐涵秋. 2008. 基于Landsat TM的3种地表温度反演算法比较分析. 福建师范大学学报(自然科学版), 24(1): 91–96

Ding F, Xu H Q. 2008. Comparison of three algorithms for retrieving land surface temperature from Landsat TM thermal infrared band. Journal of Fujian Normal University (Natural Science Edition), 24(1): 91–96

Gitelson A A, Kaufman Y J, Stark R and Rundquist D. 2002. Novel algorithms for remote estimation of vegetation fraction. Remote Sensing of Environment, 80(1): 76–87

Hanano M. 2000. Two different roles of fractures in geothermal development//Proceedings of World Geothermal Congress. Kyushu-Tohoku, Japan: World Geothermal Congress: 2597-2602

胡德勇, 乔琨, 王兴玲, 赵利民, 季国华. 2015. 单窗算法结合Landsat8热红外数据反演地表温度. 遥感学报, 19(6): 964–976

Hu D Y, Qiao K, Wang X L, Zhao L M and Ji G H. 2015. Land surface temperature retrieval from Landsat 8 thermal infrared data using mono-window algorithm. Journal of Remote Sensing, 19(6): 964–976

霍飞, 陈海山. 2010. 人为热源对城市热岛效应影响的数值模拟试验. 气象与减灾研究, 33(3): 49–55

Huo F and Chen H S. 2010. Numerical simulation of the effect of anthropogenic heat on UHI. Meteorology and Disaster Reduction Research, 33(3): 49–55

姜荣. 2016. 上海市城区热环境时空变化特征及其影响因素研究. 上海: 华东师范大学

Jiang R. 2016. Spatial Temporal Variation Characteristics and its Influencing factors of Thermal Environment in the Urban Area of Shanghai. Shanghai: East China Normal University

Jiménez-Muñoz J C and Sobrino J A. 2003. A generalized single-channel method for retrieving land surface temperature from remote sensing data. Journal of Geophysical Research: Atmospheres, 108(D22): 4688

Lee K. 1978. Analysis of thermal infrared imagery of the Black Rock Desert geothermal area. Colorado School of Mines Quarterly, 4(2): 31–44

卢善龙. 2008. 基于地质要素的金衢盆地环境数值模型的建立. 杭州: 浙江大学: 46-48

Lu S L. 2008. Numerical Environment Modeling of Jinqu Basin Based on the Geological Factors. Hangzhou: Zhejiang University: 46-48

卢善龙, 沈晓华, 邹乐君, 李长江, 章桂芳, 吴文渊, 刘瑛, 张重. 2009. 用于地表温度场与断裂构造关系分析的分段均值法——以江山—绍兴断裂金衢段为例. 地质学报, 83(2): 239–246

Lu S L, Shen X H, Zou L J, Li C J, Zhang G F, Wu W Y, Liu Y and Zhang Z. 2009. Subsection mean method for relation analysis of the land surface temperature field and the fault: a case study of the Jiangshan-Shaoxing fault between Jinhua and Quzhou of Zhejiang Province. Acta Geologica Sinica, 83(2): 239–246

卢善龙, 沈晓华, 邹乐君, 章桂芳, 吴文渊, 李长江, 毛燕军. 2008. 基于尺度分析的断层热信息遥感图像增强方法——以江山—绍兴断裂金衢段为例. 地球物理学报, 51(5): 1484–1493

Lu S L, Shen X H, Zou L J, Zhang G F, Wu W Y, Li C J and Mao Y J. 2008. Remote sensing image enhancement method of the fault thermal information based on scale analysis: a case study of Jiangshan-Shaoxing fault between Jinhua and Quzhou of Zhejiang Province, China. Chinese Journal of Geophysics, 51(5): 1484–1493

毛克彪, 覃志豪. 2004. 大气辐射传输模型及MODTRAN中透过率计算. 测绘与空间地理信息, 27(4): 1–3

Mao K B and Qin Z H. 2004. The transmission model of atmospheric radiation and the computation of transmittance of MODTRAN. Geomatics and Spatial Information Technology, 27(4): 1–3

毛克彪, 唐华俊, 周清波, 陈仲新, 陈佑启, 覃志豪. 2007. 用辐射传输方程从MODIS数据中反演地表温度的方法. 兰州大学学报(自然科学版), 43(4): 12–17

Mao K B, Tang H J, Zhou Q B, Chen Z X, Chen Y Q and Qin Z H. 2007. Retrieving land surface temperature from MODIS data by using radiance transfer equation. Journal of Lanzhou University (Natural Sciences), 43(4): 12–17

Noorollahi Y, Itoi R, Fujii H and Tanaka T. 2007. GIS model for geothermal resource exploration in Akita and Iwate prefectures, northern Japan. Computers and Geosciences, 33(8): 1008–1021

Noorollahi Y, Itoi R, Fujii H and Tanaka T. 2008. GIS integration model for geothermal exploration and well siting. Geothermics, 37(2): 107–131

Pan G X, Li L Q, Wu L S and Zhang X H. 2004. Storage and sequestration potential of topsoil organic carbon in China’s paddy soils. Global Change Biology, 10(1): 79–92

潘根兴, 李恋卿, 张旭辉, 代静玉, 周运超, 张平究. 2003. 中国土壤有机碳库量与农业土壤碳固定动态的若干问题. 地球科学进展, 18(4): 609–618

Pan G X, Li L Q, Zhang X H, Dai J Y, Zhou Y C and Zhang P J. 2003. Soil organic carbon storage of China and the sequestration dynamics in agricultural lands. Advance in Earth Sciences, 18(4): 609–618

潘根兴, 赵其国. 2005. 我国农田土壤碳库演变研究: 全球变化和国家粮食安全. 地球科学进展, 20(4): 384–393

Pan G X and Zhao Q G. 2005. Study on evolution of organic carbon Stock in agricultural soils of China: facing the challenge of global change and food security. Advances in Earth Science, 20(4): 384–393

Prol-Ledesma R M. 2000. Evaluation of the reconnaissance results in geothermal exploration using GIS. Geothermics, 29(1): 83–103

Qin Z, Karnieli A and Berliner P. 2001. A mono-window algorithm for retrieving land surface temperature from Landsat TM data and its application to the Israel-Egypt border region. International Journal of Remote Sensing, 22(18): 3719–3746

覃志豪, 李文娟, 徐斌, 陈仲新, 刘佳. 2004. 陆地卫星TM6波段范围内地表比辐射率的估计. 国土资源遥感, 16(3): 28–32, 36, 41

Qin Z H, Li W J, Xu B, Chen Z X and Liu J. 2004. The estimation of land surface emissivity for Landsat TM6. Remote Sensing For Land and Resources, 16(3): 28–32, 36, 41

瞿瑛, 刘素红, 夏江周. 2010. 照相法测量冬小麦覆盖度的图像处理方法研究. 干旱区地理, 33(6): 997–1003

Qu Y, Liu S H and Xia J Z. 2010. Image processing methods to determine the fractional vegetation cover of winter wheat using digital camera. Arid Land Geography, 33(6): 997–1003

Raynolds M K, Comiso J C, Walker D A and Verbyla D. 2008. Relationship between satellite-derived land surface temperatures, arctic vegetation types, and NDVI. Remote Sensing of Environment, 112(4): 1884–1894

Sobrino J A, Jiménez-Muñoz J C and Paolini L. 2004. Land surface temperature retrieval from Landsat TM 5. Remote Sensing of Environment, 90(4): 434–440

Sobrino J A, Raissouni N and Li Z L. 2001. A comparative study of land surface emissivity retrieval from NOAA data. Remote Sensing of Environment, 75(2): 256–266

王莹. 2013. 沈阳市城市热环境时空变化遥感研究. 长春: 吉林大学

Wang Y. 2013. Temporal and Spatial Changes of Urban Thermal Environment Remote Sensing Research in Shenyang City. Changchun: Jilin University

Weng Q H, Lu D S and Schubring J. 2004. Estimation of land surface temperature-vegetation abundance relationship for urban heat island studies. Remote Sensing of Environment, 89(4): 467–483

吴博文, 刘汉生. 2015. 输电线路工程水土保持监测实践及防治效果. 中国水土保持(3): 62–64

Wu B W and Liu H S. 2015. Water and soil conservation monitoring practices and prevention effects of transmission line engineering. Soil and Water Conservation in China(3): 62–64

Wu W Y, Zou L J, Shen X H, Lu S L, Su N and Kong F L. 2012b. Thermal anomalies associated with faults: a case study of the Jinhua-Quzhou Basin of Zhejiang Province, China. International Journal of Remote Sensing, 33(6): 1850–1867

Wu W Y, Zou L J, Shen X H, Lu S L, Su N, Kong F L and Dong Y P. 2012a. Thermal infrared remote-sensing detection of thermal information associated with faults: a case study in western Sichuan Basin, China. Journal of Asian Earth Sciences, 43(1): 110–117

谢苗苗, 周伟, 王仰麟, 常青. 2008. 城市土地利用的热环境效应研究——以宁波城区为例. 北京大学学报(自然科学版), 44(5): 815–821

Xie M M, Zhou W, Wang, Y L and Chang Q. 2008. Thermal environment effect of land use in urban area: a case study in Ningbo urban area. Acta Scientiarum Naturalium Universitatis Pekinensis, 44(5): 815–821

徐涵秋. 2005. 利用改进的归一化差异水体指数(MNDWI)提取水体信息的研究. 遥感学报, 9(5): 589–595

Xu H Q. 2005. A study on information extraction of water body with the modified normalized difference water index (MNDWI). Journal of Remote Sensing, 9(5): 589–595

杨学森. 2015. 基于单通道算法的Landsat8卫星数据地表温度反演研究. 北京: 中国地质大学(北京): 10-11

Yang X S. 2015. Research on the Single-Channel Algorithm for Land Surface Temperature Retrieval from Landsat8 Data. Beijing: China University of Geosciences (Beijing): 10-11

叶琦, 赵萍, 孙静. 2012. 基于MODIS/NDVI与EVI的皖江流域植被覆盖比较分析. 长江流域资源与环境, 21(3): 361–368

Ye Q, Zhao P and Sun J. 2012. Comparative analysis of vegetation coverage along the Yangtze River in Anhui Province based on MODIS/NDVI and EVI. Resources and Environment in the Yangtze Basin, 21(3): 361–368

Yousefi H, Ehara S and Noorollahi Y. 2007. Geothermal potential site selection using GIS in Iran//Proceedings of the 32nd Workshop on Geothermal Reservoir Engineering. Stanford, CA: Stanford University: 174-182

张旗, 金惟俊, 李承东, 王元龙. 2009. 中国东部燕山期大规模岩浆活动与岩石圈减薄: 与大火成岩省的关系. 地学前缘, 16(2): 21–51

Zhang Q, Jin W J, Li C D and Wang Y L. 2009. Yanshanian large-scale magmatism and lithosphere thinning in eastern China: relation to large igneous province. Earth Science Frontiers, 16(2): 21–51

张仁华. 1999. 对于定量热红外遥感的一些思考. 国土资源遥感, 11(1): 1–6

Zhang R H. 1999. Some thinking on quantiative thermal infrared remote sensing. Remote Sensing for Land and Resources, 11(1): 1–6

张霞, 张兵, 郑兰芬, 童庆禧, 汪骏发, 舒嵘, 薛永祺. 2000. 航空热红外多光谱数据的地物发射率谱信息提取模型及其应用研究. 红外与毫米波学报, 19(5): 361–365

Zhang X, Zhang B, Zheng L F, Tong Q X, Wang J F, Shu R and Xue Y Q. 2000. Study on the retrieval of emissivity spectra from airborne thermal infrared data. Journal of Infrared and Millimeter Waves, 19(5): 361–365

张小伟, 何月, 蔡菊珍, 李正泉. 2010. 基于GIS的浙江省土地利用/覆盖与地表温度的关系. 中国农业气象, 31(2): 295–299

Zhang X W, He Y, Cai J Z and Li Z Q. 2010. GIS-based analysis on the relationship between land use/cover and land surface temperature in Zhejiang Province. Chinese Journal of Agrometeorology, 31(2): 295–299

张志华, 李雅卓, 李钟模. 2003. 岩石、土壤、农作物关系浅议. 化工矿产地质, 25(1): 37–40

Zhang Z H, Li Y Z and Li Z M. 2003. A sequence of rock, soil and crop. Geology of Chemical Minerals, 25(1): 37–40

文章被引用时，请邮件提醒。

提交

暂无数据