太湖富营养化水体比辐射率测量及MODIS水体温度反演应用

doi:10.7523/j.issn.2095-6134.2019.06.009

摘要/Abstract

摘要： 比辐射率是遥感温度反演的重要参数，水体成分变化会改变水体热辐射物理性质，对比辐射率造成影响。目前研究水体成分对水体比辐射率影响的研究比较缺乏。利用搭配PIKE积分球的Nicolet iS50傅里叶红外光谱仪测定不同浓度浮游藻类、悬浮物对水体比辐射率的影响，提出一种二类水体比辐射率的计算模型，基于该公式计算MODIS影像在分裂窗算法中的比辐射率响应与太湖表面温度，并进行空间分析与精度评价。实验结果表明：蓝藻与悬浮物对水体比辐射率都有影响，悬浮物影响更显著；在综合考虑叶绿素a和悬浮物的条件下，与传统水温反演结果相比，偏差最大可达1.21 ℃；在较低浓度的悬浮颗粒物条件下，浮游藻类叶绿素a浓度对温度反演的最大偏差达0.86 ℃，在较低浮游藻类叶绿素a浓度条件下，悬浮颗粒物浓度对温度反演的最大偏差达0.98 ℃。真实性检验结果表明，蓝藻和悬浮物浓度对温度反演的最大影响值达到0.78 ℃，多数验证点的影响值在0.53~0.78 ℃之间。研究表明，引入蓝藻与悬浮物浓度的比辐射率校正函数能够有效降低水体表面温度的遥感反演误差。

关键词: 叶绿素a浓度, 悬浮物浓度, 比辐射率, 表面温度反演

Abstract: Emissivity of the surface target is an important parameter for remote sensing surface temperature retrieval, and the changes of water constituents bring about changes of water physical property and influence emissivity. However, studies on influences of water body constituent on emissivity are rare at the present. In this study, we determined the influences of blue-green algae and suspended sediments on water body emissivity using the Nicolet iS50 FT-IR spectrometer of Thermos Scientific Co. Ltd with an integrating sphere of the PIKE technologies, and proposed a method to obtain case II water emissivity. Based on the classic split window method and the MODIS datasets, we compared the water surface temperature retrieved using the proposed emissivity with the temperature retrieved using the widely-used water emissivity. Analysis indicates that blue-green algae and suspend solid do have influences on water body emissivity, and suspend solid has greater influence. The maximum influence on surface temperature retrieval is 1.21℃ when we take blue-green algae and suspend solid into a comprehensive consideration. The maximum influence of blue-green algae is 0.86℃ when suspend solid concentration is low. The maximum influence of suspend solid is 0.98℃ when blue-green algae concentration is low. In the actual retrieval and authenticity test, the concentrations of blue-green algae and suspended solid are low, the overall maximum influence on surface temperature retrieval is 0.78℃, and the impacts at most of the validation samples are between 0.53℃ and 0.78℃. Experiment shows that the introduction of emissivity correction function based on the chlorophyll-a concentrations of the blue-green algae and suspended sediments considerably reduces errors in water surface temperature retrieval.

Key words: concentration of the chlorophyll a, concentration of suspended sediments, emissivity, surface temperature retrieval

中图分类号:

TP79

阎福礼, 林亚森, 王世新, 周艺. 太湖富营养化水体比辐射率测量及MODIS水体温度反演应用[J]. 中国科学院大学学报, 2019, 36(6): 784-793.

YAN Fuli, LIN Yasen, WANG Shixin, ZHOU Yi. Water body emissivity measurement in Taihu Lake and its application in the watersurface temperature retrieval using the MODIS datasets[J]. , 2019, 36(6): 784-793.

参考文献

[1] Prata A J. Land surface temperatures derived from the advanced very high resolution radiometer and the along-track scanning radiometer:1. Theory[J]. Journal of Geophysical Research Atmospheres,1994,99(D6):13 025-13 058.
[2] Qin Z,Dall'Olmo G,Karnieli A,et al. Derivation of split window algorithm and its sensitivity analysis for retrieving land surface temperature from NOAA-advanced very high resolution radiometer data[J]. Journal of Geophysical Research Atmospheres,2001,106(D19):22 655-22 670.
[3] Wu X,Smith W L. Emissivity of rough sea surface for 8-13 μm:modeling and verification[J]. Applied Optics,1997,36(12):2 609-2 619.
[4] Davies J A,Robinson P J,Nunez M. Field determinations of surface emissivity and temperature for lake ontario[J]. Journal of Applied Meteorology,2010,10(4):811-819.
[5] 秦伯强,胡维平,陈伟民. 太湖水环境演化过程与机理[M]. 北京:科学出版社,2004.
[6] 秦伯强. 太湖地区水资源和水环境面临的问题、原因与建议[C]. 中国水利学会. 太湖高级论坛交流文集. 2004:135-149.
[7] 秦伯强,朱广伟,杨宏伟,等. 新方法、新理论为太湖环境治理和生态修复提供科技支撑[J]. 中国科学院院刊,2017,32(6):654-660.
[8] 袁旭音,许乃政,陶于祥,等. 太湖底泥的空间分布和富营养化特征[J]. 华东地质,2003(1):20-28.
[9] 胡开明,王水,逄勇. 太湖不同湖区底泥悬浮沉降规律研究及内源释放量估算[J]. 湖泊科学,2014,26(2):191-199.
[10] 孔繁翔,马荣华,高俊峰,等. 太湖蓝藻水华的预防、预测和预警的理论与实践[J]. 湖泊科学,2009,21(3):314-328.
[11] 王得玉,冯学智,马荣华. 太湖二类水体水色遥感的大气校正问题探讨[J]. 南京邮电大学学报(自然科学版),2012,32(2):13-18.
[12] Brivio P A,Giardino C,Zilioli E. Determination of chlorophyll concentration changes in Lake Garda using an image-based radiative transfer code for Landsat TM images[J]. International Journal of Remote Sensing,2001,22(2/3):487-502.
[13] 周艺,周伟奇,王世新,等. 遥感技术在内陆水体水质监测中的应用[J]. 水科学进展,2004,15(3):312-317.
[14] 俞宏,蔡启铭,吴敬禄. 太湖水体吸收系数与散射系数的特征研究[J]. 水科学进展,2003,14(1):46-49.
[15] 马荣华,戴锦芳. 结合Landsat ETM与实测光谱估测太湖叶绿素及悬浮物含量[J]. 湖泊科学,2005,17(2):97-103.
[16] 祝令亚,王世新,周艺,等. 应用MODIS监测太湖水体叶绿素a浓度的研究[J]. 遥感信息,2006(2):25-28.
[17] 祝令亚,王世新,周艺,等. 应用MODIS影像估测太湖水体悬浮物浓度[J]. 水科学进展,2007,18(3):444-450.
[18] 覃志豪,Arnon Karnieli. 用NOAA-AVHRR热通道数据演算地表温度的劈窗算法[J]. 国土资源遥感,2001(2):33-42.
[19] McMillin L M. Estimation of sea surface temperatures from two infrared window measurements with different absorption[J]. Journal of Geophysical Research,1975,80(36):5 113-5 117.
[20] 王祥. 基于国产自主卫星的海表温度红外遥感机理与算法研究[D]. 辽宁大连:大连海事大学,2013.
[21] 魏寒艳. 基于MODIS数据的海表温度反演研究[D]. 合肥:中国科学技术大学,2017.
[22] 覃志豪,高懋芳,秦晓敏,等. 农业旱灾监测中的地表温度遥感反演方法:以MODIS数据为例[J]. 自然灾害学报,2005,14(4):64-71.
[23] 买佳阳,蒋雪中. 2000年以来长江河口海表温度变化MODIS分析[J]. 遥感学报,2015,19(5):818-826.
[24] 郭甜甜,陈圣波,陆天启. 基于MODIS数据的多时相海表温度反演:以海南岛西南部近海海域为例[J]. 热带海洋学报,2017,36(1):9-14.
[25] Gao M,Qin Z,Xu B. Estimation of the basic parameters for deriving surface temperature from MODIS data[J]. Arid Zone Research,2007,24(1):113-119.