Study on Relationship Between Canopy Temperature of Walnut and Atmospheric Temperature at Different Altitudes in Southern Hebei Province

doi:10.11924/j.issn.1000-6850.casb2025-0830

Abstract

Abstract:

To explore the relationship between canopy temperature of walnut and atmospheric temperature in southern Hebei province, this study took Kangyuan Walnut base in Shahe City, southern Hebei Province as the research object, monitored the characteristics of canopy temperature changes in key growth stages of walnut at different altitudes, and used statistical analysis methods to conduct regression analysis on the data of canopy temperature and atmospheric temperature. The results indicated that the canopy temperature at different altitudes was highly positively correlated with the atmospheric temperature, with correlation coefficients ranging from 0.91 to 0.98 and coefficients of determination all exceeding 0.75, showing high positive correlation. When the atmospheric temperature is 35-39℃, there is little difference between the atmospheric temperature and the maximum canopy temperature of walnut. When the atmospheric temperature is higher than 40℃, the maximum canopy temperature is 2.8℃ higher than the atmospheric temperature. The minimum temperature of the canopy is most sensitive to the influence of altitude, and the low temperature period is from 4:00 to 6:30. The time and date of the minimum temperature of the walnut canopy are lagging behind that of the atmospheric temperature, and the minimum temperature is about 2.7℃ lower than the atmospheric temperature. The research will provide scientific support for the early warning of low temperature freezing damage and high temperature sunburn risk in agricultural meteorological service.

Key words: walnut, canopy temperature, atmospheric temperature, altitude

ZHAO Yubing, SUN Dian, XU Shuang, YANG Lina, ZHANG Ziyao, SUN Donglei. Study on Relationship Between Canopy Temperature of Walnut and Atmospheric Temperature at Different Altitudes in Southern Hebei Province[J]. Chinese Agricultural Science Bulletin, 2025, 41(36): 132-141.

Figures/Tables 14

References 21

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地点	要素	方程	Pearson相关系数	决定系数
AL220	平均气温	y=0.886x+1.082	0.981	0.962
AL230		y=0.897x+1.243	0.982	0.965
AL240		y=0.910x+0.144	0.913	0.832
AL220	最高气温	y=0.922x+3.425	0.942	0.887
AL230		y=0.873x+2.026	0.962	0.924
AL240		y=0.934x+1.755	0.938	0.880
AL220	最低气温	y=0.984x-3.156	0.954	0.909
AL230		y=0.922x+0.594	0.955	0.911
AL240		y=0.919x+0.047	0.928	0.859

地点	要素	方程	Pearson相关系数	决定系数
AL220	平均气温	y=0.886x+1.082	0.981	0.962
AL230		y=0.897x+1.243	0.982	0.965
AL240		y=0.910x+0.144	0.913	0.832
AL220	最高气温	y=0.922x+3.425	0.942	0.887
AL230		y=0.873x+2.026	0.962	0.924
AL240		y=0.934x+1.755	0.938	0.880
AL220	最低气温	y=0.984x-3.156	0.954	0.909
AL230		y=0.922x+0.594	0.955	0.911
AL240		y=0.919x+0.047	0.928	0.859

温度类型	变异系数/%
冠层最低温	43
冠层平均温	27
冠层最高温	24

温度类型	变异系数/%
冠层最低温	43
冠层平均温	27
冠层最高温	24