不同碱化程度土壤对其上覆植被冠层光谱特征的影响

doi:10.3964/j.issn.1000-0593(2014)03-0782-05

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摘要：通过实地光谱测量，研究了不同碱化程度土壤上向日葵在不同生育期冠层光谱反射率、红边参数及与对应的土壤碱化度和pH之间的关系。结果表明，不同碱化程度土壤上向日葵生育期冠层反射光谱具有绿色植物的光谱反射特征，随着向日葵生育期的推进，向日葵冠层光谱反射率逐渐增大，到开花期在809 nm处形成一个高的反射峰。在近红外短波范围，向日葵光谱反射率随碱化程度的减轻而增大。用红边一阶微分光谱特征参数分析，向日葵冠层反射光谱红边位置在整个生育期处于702～720 nm之间，并随着碱化程度的加重，红边位置和红边斜率呈“蓝移”现象;而在同一碱化程度水平上，随向日葵生育期的推进，红边位置和红边斜率均出现先“红移”后“蓝移”的现象。相关分析和回归分析显示，土壤碱化度、pH与红边位置均呈极显著正相关和二次多项式关系，R²值分别为0.745 6和0.615 3。

关键词：碱化程度;光谱反射率;红边参数;向日葵;相关分析

Abstract：The relationship between alkalinity and pH of the soil, reflectance spectra and red-edge parameters of the sunflower canopy in different growth periods under different alkalinity soil were analyzed, respectively. The results showed that the spectral reflectance of the sunflower canopy in different stage under different alkalinity soil is the same as the spectral reflectance characters of the other greenery canopy. Along with the advancement of the sunflower growth period, sunflower canopy spectral reflectance increases gradually at different stages, the spectral reflectance is higher at flowering stage than 7-leaf stage and budding stage, and there exists a high reflection peak at 809nm at flowering period. At the same time, the spectral reflectance is affected by salinity-alkalinity stress at different stages, in the near infrared shortwave band, the spectral reflectance of the sunflower canopy in different stage increases with the decreases in soil alkalinity. When the derivatives are applied to determine the wavelength of the red-edge, there is a shift phenomenon of the red edge. The red edges were at 702～720 nm during every growth period of the sunflower. The “blue shift” phenomenon is also emerged for red edge position and red edge sloped with the increase in the soil alkalinity. Conversely, at the same growth periods, the red edge positions and red edge slope move to longer wave bands with the decrease in soil alkalinity. There is a “red shift” phenomenon before flowering period and “blue shift” phenomenon after flowering period for the red edge position and red edge slope of canopy spectrum at the same soil alkalinity. Respectively. The red edges at different growth stages of the sunflower show very significant positive correlation and quadratic polynomial to alkalinity and pH of the soil. Therefore, we thought used the red edge features of greenery could indicate the soil alkalization degree, it providing scientific basis for monitoring soil alkalization degree by remote sensing.

Key words：Alkalinity;Spectral reflectance;Red-edge parameters;Sunflower;Correlation

收稿日期: 2013-05-21 修订日期: 2013-07-18

中图分类号:

S127，TP79

通讯作者: 张俊华 E-mail: zhangjunhua728@163.com

引用本文:

贾科利^1,2，张俊华^3* . 不同碱化程度土壤对其上覆植被冠层光谱特征的影响 [J]. 光谱学与光谱分析, 2014, 34(03): 782-786.
JIA Ke-li^1,2, ZHANG Jun-hua^3* . Impacts of Different Alkaline Soil on Canopy Spectral Characteristics of Overlying Vegetation . SPECTROSCOPY AND SPECTRAL ANALYSIS, 2014, 34(03): 782-786.

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[1] Ju Changhua, Tian Yongchao, Yao Xia, et al. Pedosphere, 2010, 20(5): 633.
[2] TANG Yan-lin, HUANG Jing-feng, WANG Xiu-zhen, et al(唐延林，黄敬峰，王秀珍，等). Scientia Agricultura Sinica(中国农业科学), 2004，37 (1) ：29.
[3] XIE Xiao-jin, SHEN Shuang-he, LI Ying-xue, et al(谢晓金，申双和，李映雪，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报)，2010, 2(3)：183.
[4] SUN Peng-sen, LIU Shi-rong, LIU Jing-tao, et al(孙鹏森，刘世荣，刘京涛，等). Acta Ecologica Sinica(生态学报)，2006, 26(11)：3826.
[5] YAN Yan, LIU Qin-huo, LIU Qiang, et al(闫岩，柳钦火，刘强，等). Journal of Remote Sensing(遥感学报)，2006, 10(5)：804.
[6] LIU Feng, LI Cun-jun, DONG Ying-ying, et al(刘峰，李存军，董莹莹，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报)，2011, 27(10): 101.
[7] QIAN Yong-lan, HOU Ying-yu, YAN Hao, et al(钱永兰，侯英雨，延昊，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报)，2012, 28(13): 166.
[8] HUANG Jing-feng, WANG Yuan, WANG Fu-min, et al(黄敬峰，王渊，王福民，等). Transaction of the Chinese Society of Agricultural Engineering(农业工程学报), 2006, 22(8): 22.
[9] YAO Xia, TIAN Yong-chao, LIU Xiao-jun, et al(姚霞，田永超，刘小军，等). Scientia Agricultura Sinica(中国农业科学)，2010, 43(13): 2661.
[10] Lamb D W, Steyn-Ross M, Schaare P, et al. International Journal of Remote Sensing, 2002, 23: 3619.
[11] JIANG Jin-bao, CHEN Yun-hao, HUANG Wen-jiang, et al(蒋金豹，陈云浩，黄文江，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报)，2008, 24(1): 35.
[12] Miller J R, Hare E W, Wu J. International Journal of Remote Sensing, 1990, 11: 1755.
[13] Guyot G, Baret F, Jacquemoud S. Fundamentals and Prospective Applications. Kluwer Academic Publishers(Dordrecht), 1992. 145.
[14] Baret F, Jacquemoud S, Guyot G, et al. Remote Sensing of Environment, 1992, 41: 133.
[15] Dawson T P, Curran P J. IEEE Transaction on Geoscience and Remote Sensing, 2003, 41(4): 9l6.
[16] Cho M A, Skidmore A K. Remote Sensing of Environment, 2006, 101: 181.
[17] GU Yan-fang, DING Sheng-yan, CHEN Hai-sheng, et al(谷艳芳，丁圣彦，陈海生，等). Acta Ecologica Sinica(生态学报)，2008, 28(6)：2690.
[18] XIE Xiao-jin, SHEN Shuang-he, LI Ying-xue, et al(谢晓金，申双和，李映雪，等). Transactions of the Chinese Society of Agricultural Engineering(农业工程学报)，2010，26(3)：183.
[19] REN Hong-yan, ZHUANG Da-fang, PAN Jian-jun, et al(任红艳, 庄大方, 潘剑君, 等). Chinese Journal of Soil Science(土壤通报), 2008, 39(6): 1326.
[20] ZHANG Jun-hua, ZHANG Jia-bao, QIN Sheng-wu(张俊华，张佳宝，钦绳武). Plant Nutrition and Fertilizer Science(植物营养与肥料学报), 2010, 16(4): 874.
[21] LIU Zhan-yu, HUANG Jing-feng, WU Xin-hong, et al(刘占宇，黄敬峰，吴新宏，等). Chinese Journal of Applied Ecology(应用生态学报), 2006, 17(6): 997.