1981—2010年长江中下游地区单季稻生殖生长期对气候变化和技术进步的响应

doi:10.3724/SP.J.1006.2023.22026

作物学报 ›› 2023, Vol. 49 ›› Issue (5): 1305-1315.doi: 10.3724/SP.J.1006.2023.22026

1981—2010年长江中下游地区单季稻生殖生长期对气候变化和技术进步的响应

刘二华¹^,²^,³(), 周广胜¹^,²^,³^,⁴^,^*(), 武炳义², 宋艳玲¹^,³, 何奇瑾⁴, 吕晓敏¹^,³, 周梦子¹^,³

¹中国气象科学研究院, 北京 100081
²复旦大学大气科学研究院, 上海 200439
³中国气象科学研究院与郑州大学生态气象联合实验室, 河南郑州 450001
⁴中国农业大学资源与环境学院, 北京 100193

收稿日期:2022-04-30 接受日期:2022-10-10 出版日期:2023-05-12 网络出版日期:2022-10-31
通讯作者: *周广胜, E-mail: zhougs@cma.gov.cn
作者简介:E-mail: leh4179@163.com
基金资助:
国家重点研究计划项目(2018YFA0606103);国家自然科学基金重点项目(42130514);国家自然科学基金重点项目(4213000565);中国气象科学研究院基本科研业务费专项(2020Z004)

Response of reproductive growth period length to climate warming and technological progress in the middle and lower reaches of the Yangtze River during 1981-2010 in single-cropping rice

LIU Er-Hua¹^,²^,³(), ZHOU Guang-Sheng¹^,²^,³^,⁴^,^*(), WU Bing-Yi², SONG Yan-Ling¹^,³, HE Qi-Jin⁴, LYU Xiao-Min¹^,³, ZHOU Meng-Zi¹^,³

¹State Key Laboratory of Severe Weather, Chinese Academy of Meteorological Sciences, Beijing 100081, China
²Institute of Atmospheric Sciences, Fudan University, Shanghai 200439, China
³Joint Eco-Meteorological Laboratory of Chinese Academy of Meteorological Sciences and Zhengzhou University, Zhengzhou 450001, Henan, China
⁴College of Resources and Environmental Sciences, China Agricultural University, Beijing 100193, China

Received:2022-04-30 Accepted:2022-10-10 Published:2023-05-12 Published online:2022-10-31
Contact: *E-mail: zhougs@cma.gov.cn
Supported by:
National Key Research and Development Program of China(2018YFA0606103);National Natural Science Foundation of China(42130514);National Natural Science Foundation of China(4213000565);Basic Research Fund of Chinese Academy of Meteorological Sciences(2020Z004)

摘要/Abstract

摘要：

作物生殖生长期长度与作物产量和品质密切相关。为深入探究作物生殖生长期长度(reproductive growth period lengths, RGLs)对气候变化和技术进步的响应, 基于1981—2010年长江中下游地区单季稻生殖生长期和气象数据, 量化不同RGLs (孕穗期—抽穗期(booting to heading, BDHD)、抽穗期—乳熟期(heading to milking, HDMS)、乳熟期—成熟期(milking to maturity, MSMD)和孕穗期—成熟期(booting to maturity, BDMD))对平均温度(mean temperature, TEM)、累积降水量(cumulative precipitation, PRE)和累积日照时数(cumulative sunshine duration, SSD)的敏感性, 并分离气候变化和技术进步对不同RGLs的影响。结果表明, 1981—2010年长江中下游地区单季稻BDMD呈延长趋势(0.24 d a^-1), 其中, HDMS延长趋势最明显(0.16 d a^-1)。气候因子中高温和寡照不利于单季稻不同RGLs延长, 其中, TEM对BDHD、HDMS和MSMD变化趋势的平均相对贡献分别为-50.0%、-50.7%和-21.9%, SSD对BDHD、HDMS和MSMD变化趋势的平均相对贡献分别为-47.2%、-48.7%和-67.6%。技术进步弥补了气候变化对不同RGLs变化趋势的不利影响。研究表明, 技术进步可能是当前单季稻稳产高产和趋利避害的主要手段, 未来可以采用较长生殖生长期和耐热性品种来适应持续的气候变化。

关键词: 单季稻, 气候变化, 生殖生长期, 技术进步

Abstract:

Crop growth period length is closely linked to climate change and technological progress. Even though the extensive researches conducting on crop growth period length variation and its response to climate change, particularly temperature change, the response of reproductive growth periods lengths (RGLs) to climate change and technological progress remains unclear. Based on the reproductive growth periods and meteorological data of single-cropping rice in the middle and lower reaches of the Yangtze River (MLYR) during 1981?2010, the trends of the RGLs (including booting to heading (BDHD), heading to milking (HDMS), milking to maturity (MSMD), and booting to maturity (BDMD)) and climatic variations were analyzed. In addition, to explore the confounding effects of climate change and technological progress on the RGLs, the sensitivities of the RGLs to mean temperature (TEM), cumulative precipitation (PRE), and cumulative sunshine duration (SSD) were measured. The results showed that the BDMD had an extension trend (0.24 d a^-1), among which the extension trend in the HDMS (0.16 d a^-1) was the most obvious in RGLs, while the extension trends of BDHD (0.03 d a^-1) and MSMD (0.05 d a^-1) were not significant. High temperature and low sunshine duration were unfavorable to the extension of the RGLs. The mean relative contributions of TEM to the BDHD, HDMS, and MSMD were -50.0%, -50.7%, and -21.9%, which were -47.2%, -48.7%, and -67.6% in terms of SSD, respectively. Technological progress compensated for the adverse impacts of climate change on the trends of different RGLs. These results suggested that cultivar selection and agronomic management were the effective adaptation strategies benefiting for the stable and high yield of single-cropping rice. Single-cropping rice cultivar with longer RGLs and heat-tolerant may be suitable to cope with the continuous climate change in the future.

Key words: single-cropping rice, climate change, reproductive growth period lengths, technological progress

刘二华, 周广胜, 武炳义, 宋艳玲, 何奇瑾, 吕晓敏, 周梦子. 1981—2010年长江中下游地区单季稻生殖生长期对气候变化和技术进步的响应[J]. 作物学报, 2023, 49(5): 1305-1315.

LIU Er-Hua, ZHOU Guang-Sheng, WU Bing-Yi, SONG Yan-Ling, HE Qi-Jin, LYU Xiao-Min, ZHOU Meng-Zi. Response of reproductive growth period length to climate warming and technological progress in the middle and lower reaches of the Yangtze River during 1981-2010 in single-cropping rice[J]. Acta Agronomica Sinica, 2023, 49(5): 1305-1315.

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生殖生长阶段 Reproductive growth periods lengths (RGLs)	平均温度敏感性Mean temperature sensitivity (β₁)	累积降水量敏感性Cumulative precipitation sensitivity (β₂)	累积日照时数敏感性Cumulative sunshine duration sensitivity (β₃)	决定系数 Determination coefficient (R²)
分蘖期-孕穗期 Tillering−Booting (TDBD)	-3.74^**	0.010^**	0.09^**	0.65
孕穗期-抽穗期 Booting−Heading (BDHD)	-0.77^**	0.010^**	0.07^**	0.59
抽穗期-乳熟期 Heading−Milking (HDMS)	-1.00^**	0.008^**	0.08^**	0.50
乳熟期-成熟期 Milking−Maturity (MSMD)	-1.17^**	0.007^*	0.07^**	0.80
孕穗期-成熟期 Booting−Maturity (BDMD)	-2.08^**	0.008^**	0.04^**	0.72

生殖生长阶段 Reproductive growth periods lengths (RGLs)	平均温度敏感性Mean temperature sensitivity (β₁)	累积降水量敏感性Cumulative precipitation sensitivity (β₂)	累积日照时数敏感性Cumulative sunshine duration sensitivity (β₃)
分蘖期-孕穗期Tillering−Booting (TDBD)	-0.40^**	0.08^*	0.74^**
孕穗期-抽穗期Booting−Heading (BDHD)	-0.47^**	0.16^**	0.65^**
抽穗期-乳熟期Heading−Milking (HDMS)	-0.43^**	0.10^*	0.65^**
乳熟期-成熟期Milking−Maturity (MSMD)	-0.52^**	0.09^*	0.55^**
孕穗期-成熟期Booting−Maturity (BDMD)	-0.54^**	0.12^**	0.32^**

1981—2010年长江中下游地区单季稻生殖生长期对气候变化和技术进步的响应

Response of reproductive growth period length to climate warming and technological progress in the middle and lower reaches of the Yangtze River during 1981-2010 in single-cropping rice

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