Application of typical psammophytes canopy temperature in the diagnosis of soil moisture status
HE Yingying, YU Minghan, DING Guodong, GAO Guanglei, ZHAO Yuanyuan, SAI Ke
1. School of Soil and Water Conservation, Key Laboratory of State Forestry Administration on Soil and Water Conservation, Beijing Forestry University, 100083, Beijing, China;
2. Beijing Forestry University, Engineering Research Center of Forestry Ecological Engineering, Ministry of Education, 100083, Beijing, China;
3. Yanchi Ecology Research Station of the Mu Us Desert, 751500, Yanchi, Ningxia, China
Abstract:[Background] Water is an important limiting factor for crop growth and development, water shortage is one of the most frequently encountered adversity with plant growth in arid regions, under the stress of adversity, a series of physiological changes usually occur in plants, the change of canopy temperature is the most direct manifestation of many physiological and biochemical processes of crops and is determined by the heat balance and the water vapour movement in the soil-crop-atmosphere cycle. Canopy temperature has been widely used in agriculture to evaluate the degree of drought as an important indicator of the amount and effectiveness of plant water.[Methods] Three typical psammophytes of Caragana korshinskii, Salix psammophila, and Artemisia ordosicaas were choosen to be planted under 4 soil moisture treatments, each plant dug up 40 seedlings that were about 30 cm tall and had basically the same growth. The soil moisture treatments were defined account for A (5%-20%), B (20%-40%), C (40%-60%), D (60%-100%) of the field water holding capacity. Determination of plant canopy temperature, soil moisture content, air temperature, air humidity, poor water saturation pressure index, analysis of the plant canopy temperature under different soil moisture conditions, characteristics and differences, and to explore the psammophyte canopy temperature of meteorological factors and the response regularity of soil moisture.[Results] Main results were as follows:1) in the same monitoring time, under the same background of meteorological conditions, the lower the soil moisture content of the plant, the higher the canopy temperature at the noon; 2) in the daily scale, the temperature of the canopy is influenced by meteorological factors and soil moisture as the daily cycle of meteorological factors changes, the correlation analysis shows that the influence of meteorological factors on canopy temperature is more significant than that of soil; 3) by calculating the sensitivity of plant canopy temperature and meteorological factor response under different soil moisture conditions, it was found that with the decrease of soil moisture content, the sensitivity of the temperature of C. korshinskii, S. psammophila, A. ordosicaas canopy to the response of meteorological factors increased. That is, the sensitivity coefficient of the temperature data of canopy temperature based on the temperature data of the canopy temperature based on the multiple time points on the daily scale can determine the soil moisture status of the plant. The lower the soil moisture content, the smaller the sensitivity of plant canopy temperature to meteorological factors.[Conculsions] This study proved that using plant canopy temperature can be achieved for the determination of soil moisture condition of plants, and the field of vegetation water management provides a new convenient and effective way.
豆胜,马成仓,陈登科.4种常见双子叶植物蒸腾作用与叶温关系的研究[J].天津师范大学学报(自然版),2008,28(2):11. DOU Sheng, MA Chengcang, CHEN Dengke. On the relationship between the transpiration rate and the leaf temperature of four dicotyledon plants[J]. Journal of Tianjin Normal University(Natural Science Edition), 2008, 28(2):11.
[2]
张立伟,张智郡,刘海军,等.基于冠层温度的玉米缺水诊断研究[J].干旱地区农业研究,2017,35(3):94. ZHANG Liwei, ZHANG Zhijun, LIU Haijun, et al. Research on water deficit diagnosis of maize based on canopy temperatures[J]. Agricultural Research in the Arid Areas, 2017, 35(3):94.
[3]
徐银萍. 旱地冬小麦扬花至灌浆期冠层温度与籽粒产量和水分利用效率的关系[D].兰州:甘肃农业大学, 2007:3. XU Yinping. Relationship between canopy temperature with grain yield ang water use effiency of dryland winter wheat from blooming to grain filling stage[D]. Lanzhou:Gansu Agricultural University, 2017:3.
[4]
于明含,高广磊,丁国栋,等.植物体温研究综述[J].生态学杂志,2015,34(12):3533. YU Minghan, GAO Guanglei, DING Guodong, et al. A review on body temperature of plants[J]. Chinese Journal of Ecology, 2015, 34(12):3533.
[5]
李丽,申双和,永秀李,等.不同水分处理下冬小麦冠层温度、叶片水势和水分利用效率的变化及相关关系[J].干旱地区农业研究,2012,30(2):68. LI Li, SHEN Shuanghe, YONG Xiuli, et al. Variation and interrelationship of winter wheat canopy temperature, leaf water potential and water use efficiency under different water treatments[J]. Agricultural Research In The Arid Areas, 2012, 30(2):68.
[6]
于明含.典型固沙植物冠层温度和气孔导度特征及其对土壤水分的响应[D].北京:北京林业大学,2016:8. YU Minghan.Canopy temperature and stomatal conductance characteristics of typical sand-fixation plants and their responses to soil moisture[D]. Beijing:Beijing Forestry University, 2016:8.
[7]
赵刚,樊廷录,李尚中,等.不同品种冬小麦冠层温度与抗旱性和水分利用效率的关系研究[J].农业现代化研究,2010,31(3):334. ZHAO Gang, FAN Tinglu, LI Shangzhong, et al. Study of relationship of canopy temperature with drought resistance and water use efficiency on different genotype winter wheat[J]. Research of Agricultural Modernization, 2010, 31(3):334.
[8]
YU Minghan, DING Guodong, GAO Guanglei, et al. How the plant temperature links to the air temperature in the desert plant Artemisia ordosica[J]. Plos One, 2015, 10(8):12.
[9]
FRANKLIN K A, KNIGHT H. Unravelling plant temperature signalling networks[J].New Phycologist, 2010, 185(1):8.
[10]
YU Minghan, DING Guodong, GAO Guanglei, et al. Using plant temperature to evaluate the response of stomatal conductance to soil moisture deficit[J]. Forests, 2015, 6(10):3748.
[11]
冯佰利,王长发,苗方,等.抗旱小麦的冷温特性研究[J].西北农林科技大学学报(自然科学版),2002,30(2):6. FENG Baili, WANG Changfa, MIAO Fang,et al. The characteristics of drought-resistant wheat with low temperature[J]. Journal of Northwest A&F University (Natural Science Edition), 2002, 30(2):6.
[12]
任学敏,朱雅,王小立,等.花生冠层温度日变化及其与地表温度和光照度的关系[J].西北农林科技大学学报(自然科学版), 2015,43(1):77. REN Xuemin, ZHU Ya, WANG Xiaoli, et al. Relationships between diurnal changes of peanut canopy temperature and surface temperature and illuminance[J]. Journal of Northwest A&F University (Natural Science Edition), 2015, 43(1):77.
[13]
邓强辉,潘晓华,石庆华,等.作物冠层温度的研究进展[J].生态学杂志, 2009,28(6):1162. DENG Qianghui, PAN Xiaohua, SHI Qinghua, et al. Research advances on crop canopy temperature[J]. Chinese Journal of Ecology, 2009, 28(6):1162.
[14]
郭晓楠,查天山,贾昕,等.典型沙生灌木生态系统凝结水量估算[J].北京林业大学学报, 2016,38(10):80. GUO Xiaonan, ZHA Tianshan, JIA Xin, et al. Estimation of dewfall amount in a typical desert shrub ecosystem[J].Journal of Beijing Forestry University, 2016, 38(10):80.
[15]
高继平,隋阳辉,张文忠,等.水稻灌浆期冠层温度对植株生理性状及稻米品质的影响[J].中国水稻科学,2015,29(5):501. GAO Jiping, SUI Yanghui, ZHANG Wenzhong, et al. Effect of canopy temperature on physiological characteristic and grain quality at filling stage in rice[J]. Chinese Journal of Rice Science, 2015, 29(5):501.
[16]
刘明虎,徐军,孙飞,等.干旱区植物叶片大小对叶表面蒸腾及叶温的影响[J].植物生态学报,2013,37(5):436. LIU Minghu, XU Jun, SUN Fei, et al. Influence of leaf size of plant on leaf transpiration and temperature in arid regions[J]. Chinese Journal of Plant Ecology, 2013, 37(5):436.
[17]
高明超.水稻冠层温度特性及基于冠层温度的水分胁迫指数研究[D].沈阳:沈阳农业大学,2013:76. GAO Mingchao. A research on rice canopy temperature properties and in view of the water stress index of canopy temperature[D]. Shenyang:Shenyang Agricultural University, 2013:76.
[18]
梁银丽,张成娥.冠层温度-气温差与作物水分亏缺关系的研究[J].中国生态农业学报, 2000,8(1):24. LIANG Yinli, ZHANG Cheng'e. The relationship between discrepancy of canopy and air temperature and crop water deficiency[J]. Chinese Journal of Eco-Agriculture, 2000, 8(1):24.
[19]
孙宏勇,张喜英,陈素英,等.水分胁迫对冬小麦冠层结构及光合特性的研究[J]. 灌溉排水学报, 2005,24(2):31. SONG Hongyong,ZHANG Xiying, CHENG Suying, et al.Study oncharacters in winter wheat canopy structure under different soil water stress[J]. 2005, 24(2):31.
[20]
冯佰利,高小丽,赵琳,等.干旱条件下小麦冠层温度及其性状的关联研究[J].生态学杂志,2005,24(5):508. FENG Baili, GAO Xiaoli, ZHAO Lin, et al. Relationships between canopy temperature and biological characters of wheat under drought conditions[J]. Chinese Journal of Ecology, 2005, 24(5):508.
[21]
AGAM N, COHEN Y, BERNI J A J, et al. An insight to the performance of crop water stress index for olive trees[J].Agricultural Water Management, 2013, 118(118):79.
[22]
LU Chuangen, XIA Shijian, CHEN Jing, et al. Plant temperature and its simulation model of thermo-sensitive genic male sterile rice[J].Rice Science, 2008, 15(3):223.
[23]
张明艳,贾昕,查天山,等.油蒿(Artemisia ordosica)光系统Ⅱ光化学效率对去除降雨的响应[J].中国沙漠,2017,37(3):475. ZHANG Mingyan, JIA Xin, ZHA Tianshan, et al. PSⅡ photochemical efficiency of Artemisia ordosicain response to rainfall exclusion[J]. Journal of Desert Research, 2017, 37(3):475.