数量化模型估算观赏植物需冷量研究进展

doi:10.11924/j.issn.1000-6850.casb17060022

摘要/Abstract

摘要： 植物在抵抗和适应不良环境时会产生生长缓慢或暂时停顿的休眠现象，打破休眠时所需的有效低温时数称为植物的需冷量。本研究综述了不同需冷量模型并分析了应用情况及效果。Utah模型是目前使用频率较高且效果较好的估算模型，动力学模型是理论最完善且适用范围最广的估算模型，但仍未推广应用，尤其是国内鲜有报道。需冷量估算模型研究对象主要为休眠芽，对其他休眠器官（球根、种子等）的需冷量研究还不多。与果树等其他园艺作物相比，目前将冷量估算模型应用于观赏植物的研究较少，涉及到植物种类和休眠器官类型都较少。需冷量模型与低温小时数相比能更准确计量及预测解除休眠过程对低温的需求，应用于观赏植物品种区域规划、引种有更好的前景。同时，继续探索需冷量累积的过程中相关的生物学机制，优化需冷量模型使其在不同气候类型中的应用具有通用型是未来研究需要着力解决的问题。

关键词: 播期, 播期, 耐密植, 大豆, 主要农艺性状, 产量

Abstract: Dormancy is a phenomenon that plant grow slowly or reach a temporary pause. It occurs when plants are resisting to or adapting to environment stress. The time of effective low temperatures required for dormancy breaking is called the chilling requirement. In this study, different chilling estimating models as long as their application effects are summarized and analyzed. Currently, application of Utah model has a higher frequency and better effect. Dynamic model is considered to be most perfect in theory and has the widest application range. But it has not yet been popularized, especially in China. The main object for chilling estimating models is dormant bud while there is few report on the other dormant organs (bulbs and seeds etc.). Compared with other horticultural crops such as fruit trees, there is few study on the application of chilling estimating models to ornamental plants. Few plant varieties and dormant organs types have been covered in the existing studies. As the chilling estimating models are more accurate in measuring and predicting the chilling requirement during dormancy breaking compared with the chilling hours, it will have a better prospect for regional planning and introduction of ornamental plants. At the same time, exploration of the biological mechanisms involved in the accumulation of the chilling requirement, as well as optimization of the chilling estimating models for universal applications in different climate types are the problems that need to be solved in the future research.

高健洲,张逸璇,李秉玲,刘燕. 数量化模型估算观赏植物需冷量研究进展[J]. 中国农学通报, 2018, 34(19): 76-82.

高健洲,, and . Advances in Quantitative Model for Estimating Chilling Requirement of Ornamental Plants[J]. Chinese Agricultural Science Bulletin, 2018, 34(19): 76-82.

参考文献

[1] 李合生. 现代植物生理学[M]. 第三版. 北京: 高等教育出版社, 2012.
[2] Jr. F. G. Dennis. Problems in Standardizing Methods for Evaluating the Chilling Requirements for the Breaking of Dormancy in Buds of Woody Plants[J]. Hortscience, 2003,38(3):347-350.
[3] Shirazi A M. Standardizing Methods for Evaluating the Chilling Requirements to Break Dormancy in Seeds and Buds (Including Geophytes): Introduction to the Workshop[J]. Hortscience, 2003,38(3):334-335.
[4] Weinberger J. Chilling requirements of peach varieties[J]. Proceedings American Society for Horticultural Science, 1950,56:122-128.
[5] Cesaraccio C, Spano D, Snyder R L, et al. Chilling and forcing model to predict bud-burst of crop and forest species[J]. Agricultural and Forest Meteorology, 2004,126(1–2):1-13.
[6] Richardson E. A model for estimating the completion of rest for Redhaven and Elberta peach trees[J]. HortScience, 1974,9(4):331-332.
[7] Gilreach P. Rest prediction model for low-chilling Sungold nectarine[J]. Journal of the American Society for Horticultural Science, 1981,106(4):426-429.
[8] Shaultout A. Rest completion prediction model for Starkrimson Delicious apples[J]. Journal of American Society for Horticultural Science, 1983,108(6):957-961.
[9] Linsley-Noakes G. Estimating daily positive Utah chill units from maximum and minimum temperatures[J]. Journal of the American Society for Horticultural Science, 1995,5(1):19-24.
[10] Gilreath P R. Rest Prediction Model for Low-chilling Sungold Nectarine[J]. Hortscience, 1981,4(106):426-429.
[11] Rhie Y H, Jung H H, Kim K S. Chilling requirement for breaking dormancy and flowering in Paeonia lactiflora ‘Taebaek’ and ‘Mulsurae’[J]. 2012,53(4):277-282.
[12] Fishman S. The temperature dependence of Dormancy Breaking in plants: Computer Simulation of Processes Studied Under Controlled Temperatures [J]. Journal of Theoretical Biology, 1987,126:309-321.
[13] Erez A. The Dynamic Model for Rest Completion in Peach Buds[J]. Acta Horticulturae, 1990(276):165-174.
[14] 沈元月, 郭家选, 贾克功. 桃品种自然休眠结束期及需冷量[J]. 莱阳农学院学报, 1998(01):8-11.
[15] 高东升, 束怀瑞, 李宪利. 几种适宜设施栽培果树需冷量的研究[J]. 园艺学报, 2001(04):283-289.
[16] 王力荣, 朱更瑞, 方伟超, 等. 桃品种需冷量评价模式的探讨[J]. 园艺学报, 2003(04):379-383.
[17] 汤志洪. 欧李冬季休眠特性的研究[D]. 山西农业大学, 2004.
[18] 韩浩章. 苏南地区主要落叶果树的需冷量及休眠解除生理机制的研究[D]. 南京农业大学, 2004.
[19] 刘波. 低温解除牡丹休眠过程中的需冷量及某些生理生化变化的研究[D]. 山东农业大学, 2004.
[20] 杨琳. 百合鳞茎休眠过程中需冷量的研究[D]. 西北农林科技大学, 2005.
[21] Rea R, Eccel E. Phenological models for blooming of apple in a mountainous region[J]. Int J Biometeorol, 2006,51(1):1-16.
[22] RUIZ D, CAMPOY J, EGEA J. Chilling and heat requirements of apricot cultivars for flowering[J]. Environmental and Experimental Botany, 2007,61(3):254-263.
[23] Alburquerque N, García-Montiel F, Carrillo A, et al. Chilling and heat requirements of sweet cherry cultivars and the relationship between altitude and the probability of satisfying the chill requirements[J]. Environmental and Experimental Botany, 2008,64(2):162-170.
[24] 张桂荣. 日本海棠促成栽培需冷量研究[J]. 北方园艺, 2008(09):115-117.
[25] PéREZ-LóPEZ D. Influence of temperature on the growth and development of olive (Olea europaea L.) trees[J]. Journal of Horticultural Science Biotechnology, 2008,83(2):171-176.
[26] 李先明. 不同梨品种需冷量研究_李先明[Z]. 秦仲麟. 2011126-129.
[27] Jianlu Z. The Dynamic Model Provides the Best Description of the Chill Process on ‘ Sirora ’ Pistachio Trees in Australia[J]. Horticultural Science, 2011,46(3):420-425.
[28] PARKER A K, DE CORTáZAR-ATAURI I G, VAN LEEUWEN C, et al. General phenological model to characterise the timing of flowering and veraison of Vitis vinifera L.[J]. Australian Journal of Grape and Wine Research, 2011,17(2):206-216.
[29] 伊兴凯. 冬季温度变化对砀山酥梨休眠和芽萌发的影响[D]. 安徽农业大学, 2012.
[30] 陈茂铨. 12个桃品种的花芽休眠需冷量和开花需热量_陈茂铨[J]. 林业科学, 2012,48(1):86-90.
[31] 李文贵, 邓家林, 张全军, 等. 新泉梨等5个梨品种需冷量的测定分析[J]. 南方农业学报, 2014,45(06):1035-1038.
[32] 杨亚会, 李庆卫. 部分梅花品种的需冷量研究[J]. 北京林业大学学报, 2013(S1):47-51.
[33] 张佳平. 芍药在杭州栽培的耐热评价及地下芽休眠机理研究[D]. 浙江大学, 2015.
[34] 章镇, 高志红, 盛炳成, 等. 葡萄不同品种需冷量研究初报[J]. 中国果树, 2002(3):15-17.
[35] 崔萍, 曹尚银, 姜建福. 枣、石榴、无花果需冷量测定试验初报[J]. 经济林研究, 2009,27(1):91-93.
[36] Baldocchi D, Wong S. Accumulated winter chill is decreasing in the fruit growing regions of California[J]. Climatic Change, 2008,87(S1):153-166.
[37] Pérez F J, Orme O J N, Reynaert B, et al. Use of the Dynamic Model for the Assessment of Winter Chilling in a Temperate and a Subtropical Climatic Zone of Chile[J]. 2008,68(2).
[38] Rebecca Darbyshire L W I G. Winter chilling trends for deciduous fruit trees in Australia[J]. Agricultural and Forest Meteorology, 2011,151(8):1074-1085.
[39] H H. Effects of climatic change on trees from cool and temperate regions an ecophysiological approach to modeling of bud burst phenology[J]. Canadian Journal of Botany, 2011,73(2):183-199.
[40] 庄维兵, 章镇, 侍婷, 等. 落叶果树需冷量及其估算模型研究进展[J]. 果树学报, 2012(03):447-453.