| Literature DB >> 28761981 |
Qing-Hai Song1,2, Yun Deng3,4,5, Yi -Ping Zhang6,7, Xiao-Bao Deng3,4, You-Xing Lin3,8,5, Li-Guo Zhou3,8,5, Xue-Hai Fei3,8,5, Li-Qing Sha3,8, Yun-Tong Liu3,8, Wen-Jun Zhou3,8, Jin-Bo Gao3,8,5.
Abstract
Canopy temperature is a result of the canopy energy balance and is driven by climate conditions, plant architecture, and plant-controlled transpiration. Here, we evaluated canopy temperature in a rubber plantation (RP) and tropical rainforest (TR) in Xishuangbanna, southwestern China. An infrared temperature sensor was installed at each site to measure canopy temperature. In the dry season, the maximum differences (Tc - Ta) between canopy temperature (Tc) and air temperature (Ta) in the RP and TR were 2.6 and 0.1 K, respectively. In the rainy season, the maximum (Tc - Ta) values in the RP and TR were 1.0 and -1.1 K, respectively. There were consistent differences between the two forests, with the RP having higher (Tc - Ta) than the TR throughout the entire year. Infrared measurements of Tc can be used to calculate canopy stomatal conductance in both forests. The difference in (Tc - Ta) at three gc levels with increasing direct radiation in the RP was larger than in the TR, indicating that change in (Tc - Ta) in the RP was relatively sensitive to the degree of stomatal closure.Entities:
Keywords: Climate change; Rainforest; Rubber plantation; Surface temperature; Tropical
Mesh:
Year: 2017 PMID: 28761981 DOI: 10.1007/s00484-017-1375-4
Source DB: PubMed Journal: Int J Biometeorol ISSN: 0020-7128 Impact factor: 3.787