光谱学与光谱分析 |
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Study on the Correlation of Spectral Characteristic and Nitrogen Content of the Soil in Citrus Orchard of Three Gorges Reservoir Area |
YI Shi-lai1, 2, 3,DENG Lie1, 2, 3,HE Shao-lan1, 2, 3,ZHENG Yong-qiang1, 2, 3,XIE Rang-jin1, 2, 3,ZHANG Xuan1, 2, 3 |
1. Citrus Research Institute, Southwest University, Chongqing 400712,China 2. Citrus Research Institute, Chinese Academy of Agricultural Sciences, Chongqing 400712, China 3. National Engineering Research Center for Citrus Technology, Chongqing 400712, China |
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Abstract The relationship between the spectrum characteristics and nitrogen content of soils in citrus orchard of the Three Gorges Reservoir Area was studied by analyzing the visible-near infrared spectrum. The results showed that the soil reflectivity increased lineally as the wavelength increases across the visible spectrum and reached a stable plateau in the short wavelength near-infrared region(780-1 750 nm)without much fluctuation. In the long wavelength near-infrared region (1 750-2 400 nm)the reflectivity of the soils was higher with higher fluctuation. There were three strong absorbance peaks around 1 416, 1 913 and 2 209 nm, respectively, in the long wavelength infrared region. Soil available nitrogen content and total nitrogen content were positively correlated with soil light reflectivity but negatively correlated with catoptric-spectrum values reciprocal logarithm. At 541 nm of visible light region, a high positive correlation was found between the available nitrogen content and the first derivative of the soil reflective spectrum with a correlation coefficient of +0.605** and the best fitting equation was y=2E+09x2-3E+06x+890.49, where R2=0.5,and x is the first derivative of the soil reflective spectrum. At 1 909 nm of the near-infrared long wavelength region, the correlation between the total nitrogen content and the reciprocal-log values of the reflective spectrum of the soils was the best with a correlation coefficient of -0.612**, and the best fitting equation was y=1.372 1x2-2.107 5x+0.859 2, where R2=0.4, and x is the reciprocal values of the log reflective spectrum of the soils.
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Received: 2008-04-16
Accepted: 2008-07-18
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Corresponding Authors:
YI Shi-lai
E-mail: yishilai@126.com;liedeng@163.com
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