极端高温对小麦叶片温度与光合速率的影响

doi:10.17521/cjpe.2026.0042

• •

极端高温对小麦叶片温度与光合速率的影响

王瑞琦, 吉秋平, 罗雨, 何龙鑫, 郑海峰, 徐彦森, 冯兆忠

南京信息工程大学, 210044

收稿日期:2026-01-27 修回日期:2026-03-30 接受日期:2026-04-30
基金资助:
江苏省碳达峰碳中和科技创新专项(BE2023400)

Responses of wheat leaf temperature and photosynthesis to heat

Wang Ruiqi, Ji Qiuping, Luo Yu, He Longxin, Zheng Haifeng, Xu Yansen, Feng Zhaozhong

, Nanjing University of Information Science & Technology 210044,

Received:2026-01-27 Revised:2026-03-30 Accepted:2026-04-30
Supported by:
the Jiangsu Provincial Special Program for Scientific and Technological Innovation in Carbon Peak and Carbon Neutrality(BE2023400)

摘要/Abstract

摘要： 气候变化导致极端高温事件频发，严重危害小麦生长。已有研究关注了极端高温对小麦光合过程的影响，但关于其对叶片温度影响及相关调控机制的研究仍相对较少。本研究以江淮地区主栽的农麦77、农麦88和扬麦39为试验材料，依托田间模拟极端高温试验平台，设置正常环境温度（对照）和极端高温两个处理，通过连续监测叶片温度、气孔导度日变化、饱和光合速率和相对叶绿素含量，揭示极端高温对不同小麦品种叶片温度与光合速率的响应差异。结果表明，极端高温处理期间空气温度平均升高了2.7 ℃，但并未显著改变小麦叶片温度，导致叶片温度与空气温度差显著降低。极端高温条件下，农麦77、农麦88和扬麦39的平均气孔导度（gs）分别较对照提高了 59.3%、56.7% 和32.4%。从日变化特征看，13:00和15:00时段小麦gs的增幅最大，分别达到67.4% 和26.1%。在辐射减弱与气温升高的耦合处理下，极端高温通过显著提高gs增强叶片蒸腾速率，表明小麦可能通过增强蒸腾作用来缓解高温对叶片的不利影响。极端高温对相对叶绿素含量和叶片饱和光合速率无显著影响，但显著降低了叶片尺度的水分利用效率。综上，小麦叶片对本研究情景下的极端高温表现出较强适应性，主要通过增强蒸腾速率、提高潜热通量以维持叶片温度和光合速率的相对稳定，但以水分消耗增加与水分利用效率降低为代价。

关键词: 极端高温, 小麦, 叶片温度, 光合速率, 气孔导度

Abstract: Aims Climate change has led to a marked increase in the frequency of extreme heat events, posing a serious threat to wheat growth. Existing studies have investigated the effects of extreme heat on the photosynthetic processes of wheat, whereas studies on its effects on leaf temperature and the underlying regulatory mechanisms remain relatively limited. Methods In this study, three widely cultivated wheat cultivars in the Jianghuai region—Nongmai 77, Nongmai 88, and Yangmai 39—were used as experimental materials. A field-based experimental platform simulating extreme heat conditions was employed, with two treatments established: normal ambient temperature (control) and extreme heat. Continuous measurements of leaf temperature, diurnal variations in stomatal conductance, photosynthetic rate, and relative chlorophyll content were conducted to elucidate cultivar-specific responses of leaf temperature and photosynthesis to extreme heat. Important findings The results showed that mean air temperature increased by 2.7 °C; however, wheat leaf temperature did not change significantly, resulting in a significant reduction in the leaf-to-air temperature difference during the extreme heat treatment. Under extreme heat conditions, the mean stomatal conductance (gs) of Nongmai 77, Nongmai 88, and Yangmai 39 increased by 59.3%, 56.7%, and 32.4%, respectively, compared with the control. Diurnal analysis indicated that the largest increases in gs occurred at 13:00 and 15:00, with increments of 67.4% and 26.1%, respectively. Under the coupled conditions of reduced radiation and elevated air temperature, extreme heat significantly increased stomatal conductance (gs) and leaf transpiration rate, suggesting that wheat may alleviate the adverse effects of high temperature on leaves by enhancing transpiration. Extreme heat had no significant effects on relative chlorophyll content or saturated photosynthetic rate, but it significantly reduced leaf-scale water use efficiency. Overall, wheat leaves exhibited strong acclimation to the extreme heat conditions examined in this study, primarily by enhancing transpiration and increasing latent heat flux to maintain relatively stable leaf temperature and photosynthetic rate, albeit at the cost of increased water consumption and reduced water use efficiency.

Key words: Heat, wheat, leaf temperature, photosynthesis, stomatal conductance

王瑞琦, 吉秋平, 罗雨, 何龙鑫, 郑海峰, 徐彦森, 冯兆忠. 极端高温对小麦叶片温度与光合速率的影响. . DOI: 10.17521/cjpe.2026.0042

Wang Ruiqi, Ji Qiuping, Luo Yu, He Longxin, Zheng Haifeng, Xu Yansen, Feng Zhaozhong. Responses of wheat leaf temperature and photosynthesis to heat. Chinese Journal of Plant Ecology. DOI: 10.17521/cjpe.2026.0042

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2026.0042

[1]	王睿, 贾会丽, 常玉良, 林茂, 栗国梁, 武帅楷, 苏原, 董宽虎, 王常慧. 不同水平氮添加下晋北赖草叶片化学计量特征及其对光合的影响[J]. 植物生态学报, 2026, 50(2): 429-441.
[2]	李少伟, 何永涛, 孙维, 戴尔阜. 2016-2020年拉萨河谷典型农田生态系统长期监测样地作物收获期性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1321-1328.
[3]	朱喜, 何志斌, 杜明武, 赵丽雯, 吴丹丹. 2004-2010年河西走廊中段绿洲农田生态系统长期监测样地作物性状和产量数据集[J]. 植物生态学报, 2025, 49(8): 1312-1320.
[4]	赵洪贤, 刘鹏, 史曼英, 徐铭泽, 贾昕, 田赟, 查天山. 毛乌素沙地典型固沙植物黑沙蒿和赖草叶片氮分配对最大净光合速率的影响[J]. 植物生态学报, 2025, 49(3): 460-474.
[5]	张小雨, 贾国栋, 余新晓, 孙立博, 蒋涛. 不同退化程度小叶杨人工林冠层气孔导度特征及其环境响应[J]. 植物生态学报, 2024, 48(9): 1143-1156.
[6]	王嘉仪, 王襄平, 徐程扬, 夏新莉, 谢宗强, 冯飞, 樊大勇. 北京市行道树绒毛梣的水力结构对城市不透水表面比例的响应[J]. 植物生态学报, 2023, 47(7): 998-1009.
[7]	冯旭飞, 雷长英, 张玉洁, 向导, 杨明凤, 张旺锋, 张亚黎. 棉花花铃期叶片氮分配对光合氮利用效率的影响[J]. 植物生态学报, 2023, 47(11): 1600-1610.
[8]	马艳泽, 杨熙来, 徐彦森, 冯兆忠. 四种常见树木叶片光合模型关键参数对臭氧浓度升高的响应[J]. 植物生态学报, 2022, 46(3): 321-329.
[9]	熊淑萍, 曹文博, 曹锐, 张志勇, 付新露, 徐赛俊, 潘虎强, 王小纯, 马新明. 水平结构配置对冬小麦冠层垂直结构、微环境及产量的影响[J]. 植物生态学报, 2022, 46(2): 188-196.
[10]	林雍, 陈智, 杨萌, 陈世苹, 高艳红, 刘冉, 郝彦宾, 辛晓平, 周莉, 于贵瑞. 中国干旱半干旱区生态系统光合参数的时空变异及其影响因素[J]. 植物生态学报, 2022, 46(12): 1461-1472.
[11]	叶子飘, 于冯, 安婷, 王复标, 康华靖. 植物气孔导度对CO₂响应模型的构建[J]. 植物生态学报, 2021, 45(4): 420-428.
[12]	陈胜楠, 陈左司南, 张志强. 北京山区油松和元宝槭冠层气孔导度特征及其环境响应[J]. 植物生态学报, 2021, 45(12): 1329-1340.
[13]	宋慧清, 倪鸣源, 朱师丹. 乔木与木质藤本的水力与光合性状的差异: 以热带森林崖豆藤属和买麻藤属为例[J]. 植物生态学报, 2020, 44(3): 192-204.
[14]	王景旭, 黄华国, 林起楠, 王冰, 黄侃. 红外热成像监测云南松切梢小蠹虫害: 针叶尺度观测[J]. 植物生态学报, 2019, 43(11): 959-968.
[15]	朱启林, 向蕊, 汤利, 龙光强. 间作对氮调控玉米光合速率和光合氮利用效率的影响[J]. 植物生态学报, 2018, 42(6): 672-680.