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[1]蒋尚明,袁宏伟,崔毅,等.基于相对生长率的大豆旱灾系统敏感性定量评估研究[J].大豆科学,2018,37(01):92-100.[doi:10.11861/j.issn.1000-9841.2018.01.0092]
　JIANG Shang-ming,YUAN Hong-wei,CUI Yi,et al.Quantitative Evaluation of Soybean Drought System Sensitivity based on Relative Growth Rate[J].Soybean Science,2018,37(01):92-100.[doi:10.11861/j.issn.1000-9841.2018.01.0092]

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基于相对生长率的大豆旱灾系统敏感性定量评估研究

《大豆科学》[ISSN:1000-9841/CN:23-1227/S] 卷: 第37卷期数: 2018年01期页码: 92-100 栏目: 出版日期: 2018-01-20

Title:: Quantitative Evaluation of Soybean Drought System Sensitivity based on Relative Growth Rate

作者:: 蒋尚明 ¹; 袁宏伟 ¹; 崔毅 ²; 金菊良³; 4; 张宇亮⁵; 周玉良 ³; 4; （1.安徽省水利部淮河水利委员会水利科学研究院水利水资源安徽省重点实验室, 安徽合肥 230088; 2.天津大学水利工程仿真与安全国家重点实验室, 天津 300072; 3.合肥工业大学土木与水利工程学院, 安徽合肥 230009; 4.合肥工业大学水资源与环境系统工程研究所, 安徽合肥 230009; 5.河海大学水问题研究所, 江苏南京 210098）

Author(s):: JIANG Shang-ming ¹; YUAN Hong-wei ¹; CUI Yi ²; JIN Ju-liang ³; 4; ZHANG Yu-liang ⁵; ZHOU Yu-liang ³; 4; （1.Key Laboratory of Water Conservancy and Water Resources of Anhui Province, Water Resources Research Institute of Anhui Province and Huaihe River Commission, Ministry of Water Resources, Hefei 230088, China; 2. State Key Laboratory of Hydraulic Engineering Simulation and Safety, Tianjin University, Tianjin 300072, China; 3. School of Civil Engineering, Hefei University of Technology, Hefei 230009, China; ）

关键词:: 旱灾系统敏感性; 生长解析法; 相对生长率; 受旱胁迫度; 大豆受旱试验

Keywords:: Drought system sensitivity; Growth analysis method; Relative growth rate; Degree of drought stress; Soybean drought test

分类号:: S565.1;S274.3

DOI:: 10.11861/j.issn.1000-9841.2018.01.0092

文献标志码:: A

摘要:: 针对大豆旱灾系统敏感性定量评估的复杂性与重要性，依托新马桥农水综合试验站开展大豆防雨棚盆栽受旱胁迫专项试验，分析了大豆不同生育期受旱胁迫对根（冠）干物质积累及根冠比的影响，运用作物生长解析法构建了基于相对生长率（RGR）的大豆旱灾系统敏感性函数，实现对大豆旱灾系统敏感性的定量评估。结果表明：大豆苗期受旱胁迫会出现相对生长率较大幅度的降低，但随着受旱胁迫度的增大对大豆生长和干物质积累的抑制作用增强不明显，且受旱胁迫会激发自身适应受旱胁迫的机制而可能对后期生长发育有利，宜根据时机控制该生育期水分供给，保证苗全即可；大豆分枝期旱灾系统敏感性较强，但该生育期内轻度受旱胁迫对大豆生长发育影响不明显，宜保证该生育期水分供给高于轻度受旱胁迫（土壤含水率>田间持水含水率的55%），以保障大豆株壮、枝多；大豆花荚期是水分和养分需求最大的时期，该生育期旱灾系统较敏感，特别是重度受旱胁迫时系统敏感性最大，宜充分保证该生育期的水分供给（土壤含水率>田间持水含水率的75%），以保障大豆花多、荚多、粒多；大豆鼓粒成熟期由于营养生长基本停止、干物质积累几乎停滞，导致基于总干物质相对生长率旱灾系统敏感性最小，但该期是产量形成的关键期，宜保证该生育期尤其鼓粒期的水分供给（土壤含水率>田间持水含水率的75%），以保障完熟期粒多、粒重。

Abstract:: In allusion to the complexity and importance of quantitative evaluation for soybean drought system sensitivity, relying on agricultural water comprehensive test station of Xinmaqiao to carry out special soybean potted drought stress tests with anti canopy. Analysis of drought stress of soybean at different growth stages on dry matter accumulation of root and shoot and root-shoot ratio. The sensitivity function of soybean drought system based on relative growth rate (RGR) was constructed by crop growth analysis method. And then to achieve a quantitative assessment of the sensitivity of soybean drought system.The results indicate that soybean seedlings under drought stress will be a relatively large growth rate of the reduction. But with the increase of drought stress, the inhibition of soybean growth and dry matter accumulation was not obvious. And drought stress can stimulate itself to adapt to the mechanism of drought stress beneficial to the late growth and development. Appropriate control of water supply at seedling stage to ensure that all seedlings. Soybean drought system is more sensitive in branching period. But the growth period of mild drought stress on soybean growth effect is not obvious. It is necessary to ensure that the water supply during branching period is higher than the mild drought stress， then the soil moisture can content more than 55% of field capacity moisture content to protect soybeans thrive. Soybean flowering-poding period requires the most in water and nutrient, the drought system sensitivity of this growth period is also relatively large, especially when serious drought stress system sensitivity is the largest. It is necessary to fully guarantee the water supply during flowering-poding period that the soil moisture content more than 75% field capacity moisture content. Because the vegetative growth and the accumulation of dry matter are almost stagnant in soybean mature period, the drought system sensitivity is minimal that base on the relative growth rate of total dry matter. But soybean mature period is the critical period of soybean yield formation, it is necessary to fully guarantee the water supply during soybean mature period that the soil moisture content more than 75% of field capacity moisture content.

参考文献/References:

［1］ Shahid S, Behrawan H. Drought risk assessment in the west part of Bangladesh［J］. Natural Hazard,2008,46(3): 391-413.?

［2］金菊良,宋占智,崔毅,等. 旱灾风险评估与调控关键技术研究进展［J］. 水利学报, 2016,47(3): 389-412.(Jin J L, Song Z Z, Cui Y, et al. Research progress on the key technologies of drought risk assessment and control ［J］. Journal of Hydraulic Engineering, 2016,47(3): 389-412.)

［3］张继权,刘兴明,严登华. 综合灾害风险管理导论［M］. 北京: 北京大学出版社,2012.(Zhang J Q, Liu X , Yan D H. Introduction of integrated disaster risk management ［M］. Beijing: Peking University Press, 2012.)

［4］金菊良,郦建强,周玉良,等. 旱灾风险评估的初步理论框架［J］. 灾害学,2014,29(3): 1-10.(Jin J L, Li J Q, Zhou Y L, et al. Theoretical framework of drought risk assessment ［J］. Journal of Catastrophology, 2014,29(3): 1-10.)

［5］商彦蕊. 灾害脆弱性概念模型综述［J］. 灾害学,2013,28(1): 112-116.(Shang Y R. Review on concept model of disaster vulnerability ［J］. Journal of Catastrophology, 2013,28(1): 112-116.)

［6］马晓群,姚筠,许莹. 安徽省农作物干旱损失动态评估模型及其试用［J］.灾害学,2010,25(1): 13-17.(Ma X Q, Yao Y, Xu Y. A model for dynamic assessment of crop yield losses from drought and its tryout in Anhui province ［J］. Journal of Catastrophology, 2010,25(1): 13-17.)

［7］ Huang J Y, Liu Y, Ma L, et al. Methodology for the assessment and classification of regional vulnerability to natural hazards in China: The application of a DEA model ［J］. Natural Hazards,2013,65(1): 115-134.

［8］裴欢,王晓妍,房世峰. 基于DEA的中国农业旱灾脆弱性评价及时空演变分析［J］. 灾害学,2015,30(2): 64-69.(Pei H, Wang X Y, Fang S F. Study on temporal-spatial evolution of agricultural drought vulnerability of China based on DEA model ［J］. Journal of Catastrophology, 2015,30(2): 64-69.)

［9］茆智,崔远来,李新健. 我国南方水稻水分生产函数试验研究［J］. 水利学报,1994(9): 21-31.(Mao Z, Cui Y L, Li X J. Study of water production function for rice in south China［J］. Journal of Hydraulic Engineering, 1994(9): 21-31.)

［10］韩松俊,刘群昌,王少丽,等. 作物水分敏感指数累积函数的改进及其验证［J］. 农业工程学报,2010,26(6):83-88.(Han S J, Liu Q C, Wang S L, et al. Improvement and verification of cumulative function of crop water sensitive index［J］. Transactions of the CSAE, 2010, 26(6): 83-88.)

［11］Todisco F, Mannocch F, Vergni L. Severity-duration-frequency curves in the mitigation of drought impact: An agricultural case study ［J］. Natural Hazards,2013,65(3): 1863-1881.

［12］赵青松,陈林,孙波,等. 基于Hadoop的云环境下作物生长模型算法的实现与测试［J］. 农业工程学报,2013,29(8):179-186.(Zhao Q S, Chen L, Sun B, et al. Algorithm implementation and tested of crop growth model based on Hadoop of cloud computing ［J］. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2013,29(8): 179-186.)

［13］赵姣,郑志芳,方艳茹,等. 基于动态模拟模型分析冬小麦干物质积累特征对产量的影响［J］. 作物学报,2013,39(2):300-308.(Zhao J, Zheng Z F, Fang Y R, et al. Effect of dry matter accumulation characteristics on yield of winter wheat analyzed by dynamic simulation model ［J］. Acta Agronomica Sinica, 2013,39(2):300-308.)

［14］乔嘉,朱金城,赵姣,等. 基于Logistic模型的玉米干物质积累过程对产量影响研究［J］. 中国农业大学,2011,16(5):32-38.(Qiao J, Zhu J C, Zhao J, et al. Study on the effect of dry matter accumulation process on maize yield based on Logistic model［J］. Journal of China Agricultural University, 2011,16(5):32-38.)

［15］杨惠杰,李义珍,杨仁崔,等. 超高产水稻的干物质生产特性研究［J］.中国水稻科学,2001,15(4):265-270.(Yang H J, Li Y Z, Yang R C, et al. Dry matter production characteristics of super high yielding rice［J］. Chinese Journal of Rice Science, 2001,15(4):265-270.)

［16］葛慧玲,龚振平,马春梅,等. 灌溉水平及灌溉间隔对大豆植株干物质积累的影响［J］. 灌溉排水学报,2017,36(5):30-35.(Ge H L, Gong Z P, Ma C M, et al. Effect of irrigation schedule of dry matter of the shoots of soybean［J］. Journal of Irrigation and Drainage, 2017,36(5):30-35.)

［17］宋微微,杜吉到,郑殿峰,等. 大豆干物质积累、分配规律的研究进展［J］. 大豆科学,2008,27(6):1062-1066.(Song W W, Du J D, Zheng D F, et al. Research progress on dry matter accumulation and distribution rules of soybean population［J］. Soybean Science, 2008,27(6):1062-1066.)

［18］沈融,章建新,苏广禄,等. 不同时期水分亏缺对高产大豆植株地上部分生长的影响［J］. 新疆农业大学学报,2011,34(4):297-301. (Shen R, Zhang J X, Su G L, et al. Effect of water deficit in different period on aerial part growth of high-yield soybean plant［J］. Journal of Xinjiang Agricultural University, 2011,34(4):297-301.)

［19］刘丽君,林浩,唐晓飞,等. 干旱胁迫对不同生育阶段大豆产量形态建成的影响［J］. 大豆科学,2011,30(3):405-412.(Liu L J, Lin H, Tang X F, et al. Drought stress influence soybean yield morphogenesis in different growth stages［J］. Soybean Science, 2011,30(3):405-412.)

［20］Boote K J. Effects of water stress on leaf area index, crop growth rate and dry matter accumulation of field-grown corn and soybean［J］. Field Crops Research, 2013, 21(89):171-187.

［21］张立军,孙旭刚,王昌陵,等. 盆栽条件下水肥调控对大豆生长和产量的影响［J］. 大豆科学,2014,33(3):398-403.(Zhang L J, Sun X G, Wang C L, et al. Regulation effect of water and fertilizer on growth and yield in soybean under pot experiment condition［J］. Soybean Science,2014,33(3):398-403.)

［22］Singh H, Singh G. Dry matter accumulation, nodulation, yield attributes and yield of soybean (Glycine max L. Merrill) as affected by potassium and split application of nitrogen［J］. Indian Journal of Ecology, 2011, 38(2):206-210.

［23］石勇, 许世远, 石纯, 等. 自然灾害脆弱性研究进展［J］. 自然灾害学报, 2011, 20(2): 131-137.(Shi Y, Xu S Y, Shi C, et al. Progress in research on vulnerability of natural disasters ［J］. Journal of Natural Disasters, 2011, 20(2): 131-137.)

［24］Blackman V H. The compound interest law and plant growth［J］. Annals of Botany, 1919,33(3): 353-360.

［25］张秀如. 生长解析法及其在棉花科研中的初步应用［J］. 华中农学院学报,1984,3(4):1-8.(Zhang X R. Growth analysis method and its application in scientific research of cotton［J］. Journal of Huazhong Agricultural College, 1984,3(4):1-8.)

［26］Pommerening A, Muszta A. Methods of modelling relative growth rate［J］. Forest Ecosystems, 2015, 2(1):1-9.

［27］国家气象中心, 中国农业科学院农业资源与农业区划研究所, 等. GB/T 32136-2015农业干旱等级［S］. 北京: 中国标准出版社, 2015. (National Meteorological Center, Institute of Agricultural Resources and Agricultural Regionalization of the Chinese Academy of Agricultural Sciences, et al. GB/T 32136-2015 Grade of agricultual drought［S］. Beijing: China Standards Press, 2015.

［28］王书吉, 康绍忠, 李涛. 基于节水高产优质目标的冬小麦适宜水分亏缺模式［J］. 农业工程学报, 2015, 31(12): 111-118.(Wang S J, Kang S Z, Li T. Suitable water deficit mode for winter wheat basing objective of water saving as well as high yield and quality ［J］. Transactions of the Chinese Society of Agricultural Engineering (Transactions of the CSAE), 2015,31(12): 111-118.)

［29］李柏贞,周广胜. 干旱指标研究进展［J］. 生态学报,2014,34(5):1043-1052.(Li B Z, Zhou G S. Advance in the study on drought index ［J］. Acta Ecologica Sinica, 2014,34(5):1043-1052.)

［30］姚玉壁,张存杰,邓振镛,等. 气象、农业干旱指标综述［J］. 干旱地区农业研究,2007,25(1): 185-189,211.(Yao Y B, Zhang C J, Deng Z Y, et al. Overview of meteorological and agricultural drought indices［J］. Agricultural Research in the Arid Areas, 2007,25(1): 185-189,211.)

［31］汤广民,蒋尚明. 水稻的干旱指标与干旱预报［J］. 水利水电技术,2011,42(8): 54-58.(Tang G M, Jiang S M. Drought index and drought prediction for rice ［J］. Water Resources and Hydropower Engineering, 2011,42(8): 54-58.)

［32］胡立勇,丁艳锋. 作物栽培学［M］. 北京: 高等教育出版社,2008.(Hu L Y, Ding Y F. Crop cultivation ［M］. Beijing:Higher Education Press, 2008.)

备注/Memo

收稿日期：2017-08-24

基金项目：国家重点研发计划（2017YFD0301301）；国家自然科学基金(51409002, 51579059, 51579060)。

第一作者简介：蒋尚明(1983-)，男，硕士，工程师，主要从事农村水利系统工程研究。E-mail:jiangshangming@163.com。

通讯作者：金菊良(1966-),男，博士，教授，主要从事水资源系统工程研究。 E-mail:JINJL66@126.com。

更新日期/Last Update: 2018-03-13