中国产区苹果越冬冻害的风险评估

doi:10.11849/zrzyxb.20160728

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自然资源学报 ›› 2017, Vol. 32 ›› Issue (5) : 829-840. DOI: 10.11849/zrzyxb.20160728

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中国产区苹果越冬冻害的风险评估

屈振江¹, 周广胜^2,*

作者信息 +

The Risk Assessment of Winter Injury in Main Apple-producing Regions of China

QU Zhen-jiang¹, ZHOU Guang-sheng²

Author information +

文章历史 +

摘要

越冬期冻害是影响苹果种植分布和质量形成的主要气象灾害之一。论文利用1961—2014年2 084个气象站点资料和冻害调查数据,基于二分类Logistic回归分别建立了越冬期初冬冻害和极端低温冻害发生的概率预测模型,并按照风险极低、低、中度、高、极高等5个等级进行了空间划分。结果表明：建立的初冬冻害和极端低温冻害风险概率预测模型均通过了Hosmer-Losmer检验,独立样本的预测准确率分别达到了83.6%和91.4%。中国产区苹果的越冬冻害主要以初冬冻害为主,覆盖了除黄河故道和云南产区外的大部分果区,而极端低温冻害主要分布在纬度或海拔较高的环渤海湾北部产区、黄土高原西北部和北疆。两种冻害的高风险区域面积基本相当,中度以上风险面积较大的省份依次为甘肃、辽宁、河北和山西,但苹果种植面积最大的陕西和山东遭遇两种冻害特别是极端低温冻害的风险概率总体较低。

Abstract

Winter injury is one of the main meteorological disasters that affect apple’s growing distribution and quality. Existing research mainly studies the injuries caused by extremely low temperatures during deep dormancy of apples, mostly using the mean temperature of the coldest month, the frequency of extreme minimum temperatures as indicators to assess the risk and divide the boundaries of apple’s distribution. However, cold resistance of fruit trees is different during different dormant phases, and is closely related with the cold-resistance exercises in fall. The probabilistic forecasting models of early winter injury and extreme winter cold injury are established with the binary Logistic regression, on basis of the data of 2 084 meteorological stations and the winter injuries happened during 1981-2010. The space is divided into five risk’s degrees as very low, low, moderate, high and very high. The classification standard of the probability of winter injury was referred from the classification criteria in the IPCC report. The results show that: the probabilistic forecasting models of early winter injury and extreme winter cold injury passed the Hosmer-Losmer test, and the prediction accuracies of independent samples reached 83.6% and 91.4% respectively. Early winter injury depends mainly on time of the first frost day and the time interval between the first frost day and the first day that the lowest temperature is lower than -15 ℃. The extreme winter cold injury is affected by the average temperature of the coldest month and the cold accumulated temperature when the daily minimum temperature is lower than -20 ℃. The freezing injury caused by short-term extreme low temperature is of small occurrence probability and limited influence scope. The extreme low-temperature injury in winter is mainly caused by continuous intimidation of strong and low temperature. Early winter injury is the main freezing injury in apple-producing regions of China, which happens in most apple-producing regions except the ancient Yellow River region and Yunnan producing region. But extreme winter cold injuries mainly happen in high latitude or high altitude regions, including the northern Bohai Gulf, the northwest of the Loess Plateau and Northern Xinjiang. High risk areas of early winter injury and extreme winter cold injury are almost equal. Gansu is the province that has the largest area of risks with moderate degree and above, followed by Liaoning, Hebei and Shanxi. On the other hand, there are low risks of winter injury, especially for extreme winter cold injury, in Shaanxi and Shandong where there are the largest planting areas of apple.

导出引用

屈振江, 周广胜. 中国产区苹果越冬冻害的风险评估[J]. 自然资源学报, 2017, 32(5): 829-840 https://doi.org/10.11849/zrzyxb.20160728

QU Zhen-jiang, ZHOU Guang-sheng. The Risk Assessment of Winter Injury in Main Apple-producing Regions of China[J]. JOURNAL OF NATURAL RESOURCES, 2017, 32(5): 829-840 https://doi.org/10.11849/zrzyxb.20160728

中图分类号： S661.1

参考文献

[1] PERRY T O. Dormancy of trees in winter [J]. Science, 1971, 171(3966): 29-36.
[2] WEISER C J. Cold resistance and injury in woody plants [J]. American Association for the Advancement of Science, 1970, 169(3952): 1269-1278.
[3] IPCC. Climate change 2013: The physical science basis [M/OL]. Cambridge: Cambridge University Press, in press. 2013-09-30. http://www.climatechange2013.org/images/uploads/WGIAR5_WGI-12Doc2b_FinalDraft_All.pdf.
[4] 沙万英, 邵雪梅, 黄玫. 20 世纪80 年代以来中国的气候变暖及其对自然区域界线的影响 [J]. 中国科学(D辑), 2002, 32(4): 317-326. [SHA W J, SHAO X M, HUANG M. Climate warming and its impact on natural regional boundaries in China in the 1980s. Science in China (Series D), 2002, 32(4): 317-326. ]
[5] 龚志强, 王晓娟, 崔冬林, 等. 区域性极端低温事件的识别及其变化特征 [J]. 应用气象学报, 2012, 23(2): 195-204. [GONG Z Q, WANG X J, CUI D L, et al. The identification and changing characteristics of regional low temperature extreme events. Journal of Applied Meterological Science, 2012 , 23(2): 195-204. ]
[6] 周远明, 李世奎. 我国大苹果经济栽培北界的探讨 [J]. 中国果树, 1985(1): 6-10. [ZHOU Y M, LI S K. On cultivation of the north side of the big apple economy in our country. China Fruits, 1985(1): 6-10. ]
[7] 李勇, 杨晓光, 张海林, 等. 全球气候变暖对中国种植制度可能影响Ⅶ. 气候变暖对中国柑桔种植界限及冻害风险影响 [J]. 中国农业科学, 2011, 44(14): 2876-2885. [LI Y, YANG X G, ZHANG H L, et al. The possible effects of global warming on cropping systems in China Ⅶ. The possible effects of climate warming on geographical shift in northern limit of citrus planting areas and the risk analysis of freezing injury in China. China Agriculture Science, 2011, 44(14): 2876-2885. ]
[8] 柏秦凤, 王景红, 郭新, 等. 基于县域单元的陕西苹果越冬冻害风险分布 [J]. 气象, 2013, 39(11):1507-1513. [BAI Q F, WANG J H, GUO X, et al. Research on apple wintering frost damage risk distribution based on county level in Shaanxi Province. Meteorological Monthly, 2013, 39(11): 1507-1513. ]
[9] BIGRS F J, D’AOUST A L. Influence of photoperiod on shoot and root frost tolerance and bud phenology of white spruce seedlings ( Piceaglauca ) [J]. Canadian Journal of Forest Research, 1993, 23(2): 219-228.
[10] LINDEN L. Re-analyzing historical records of winter injury in Finnish apple orchards [J]. Canadian Journal of Plant Science, 2001, 81(3): 479-485.
[11] 杨建民, 周怀军, 王文凤. 果树霜冻害研究进展 [J]. 河北农业大学学报, 2000, 23(3): 54-58. [YANG J M, ZHOU H J, WANG W F .The advance in frost injury research of fruit trees. Journal of Agricultural University of Hebei, 2000, 23(3): 54-58. ]
[12] COLEMAN W K. A proposed winter-injury classification for apple trees on the northern fringe of commercial production [J]. Canadian Journal of Plant Science, 1992, 72: 507-516.
[13] REPO T, HÄNNINEN H, KELLOMÄKI S. The effects of long-term elevation of air temperature and CO 2 on the frost hardiness of Scots pine [J]. Plant Cell & Environment, 1996, 19(2): 209-216.
[14] BÉLANGER G, ROCHETTE P, CASTONGUAY Y, et al. Climate change and winter survival of perennial forage crops in eastern Canada [J]. European Journal of Clinical Nutrition, 2007, 61(5): 963-975.
[15] ROCHETTE P, BÉLANGER G, CASTONGUAY Y, et al. Climate change and winter damage to fruit trees in eastern Canada [J]. Canadian Journal of Plant Science, 2004, 84(4): 1113-1125.
[16] 邓欧, 李亦秋, 冯仲科, 等. 基于空间Logistic的黑龙江省林火风险模型与火险区划 [J]. 农业工程学报, 2012, 28(8): 200-205. [DENG O, LI Y Q, FENG Z K, et al. Model and zoning of forest fire risk in Heilongjiang Province based on spatial Logistic. Transactions of the CSAE, 2012, 28(8): 200-205. ]
[17] 王卫国, 潘竟虎, 李俊峰. 基于空间Logistic的山西省火灾风险评0价与火险区划 [J]. 草业科学, 2016, 33(4): 635-644. [WANG W G, PAN J H, LI J F. Assessment and zoning of fire risk in Shanxi Province based on spatial Logistic model. Pratacultural Science, 2016, 33(4): 635-644. ]
[18] 农业部. 苹果优势区域布局规划(2008—2015年) [J]. 农业工程技术(农产品加工业), 2010(3): 16-17. [Ministry of Agriculture. Apple advantages regional layout planning. Agriculture Engineering Technology, 2010(3): 16-17. ]
[19] 国家统计局. 中国农村统计年鉴2014 [M]. 北京: 中国统计出版社, 2015. [National Statistical Bureau of China. China Rural Statistical Yearbook 2014. Beijing: China Statistics Press, 2015. ]
[20] 任芝花, 刘小宁, 杨文霞. 极端异常气象资料的综合性质量控制与分析 [J]. 气象学报, 2005, 63(4): 526-533. [REN Z H, LIU X N, YANG W X. Complex quality control and analysis of extremely abnormal meteorological data. Acta Meteorologica Sinica, 2005, 63(4): 526-533. ]
[21] 中国气象局. 中国气象灾害大典 [M]. 北京: 气象出版社, 2008. [China Meterological Administration. China Meteorological Disaster Ceremony. Beijing: China Meteorological Press, 2008. ]
[22] BERVAES J C A M, KETCHIE D O, KUIPER P J C. Cold hardiness of pine needles and apple bark as affected by alteration of day length and temperature [J]. Physiologia Plantarum, 1978, 44(4): 365-368.
[23] ANNIKKI W, THOMAS M, E TAPIO P, et al. Independent activation of cold acclimation by low temperature and short photoperiod in hybrid aspen [J]. Plant Physiology, 2002, 129(4): 1633-1641.
[24] 刘国惠. 苹果树耐冻性及冻害频率分析 [J]. 北方果树, 1995(3): 27-29. [LIU G H. The apple tree frost resistance and freezing injury frequency analysis. Northern Fruits, 1995(3): 27-29. ]
[25] 杨雪, 张殿生, 张钢. 抗寒锻炼期间几种梨, 苹果枝条的抗寒性和电阻抗图谱比较 [J]. 西北农业学报, 2014, 23(4): 60-67. [YANG X, ZHANG D S, ZHANG G. Frost hardiness and electrical impedance spectroscopy of shoots in several pear and apple varieties during hardening. Acta Agriculturae Boreali-occidentalis Sinica, 2014, 23(4): 60-67. ]
[26] 李世奎, 朱佳满, 周远明, 等. 我国苹果种植区划研究 [J]. 山西果树, 1985, 22(4): 2-6. [LI S K, ZHU J M, ZHOU Y M, et al. Apple planting regionalization research in China. Shanxi Fruits, 1985, 22(4): 2-6. ]
[27] 屈振江, 周广胜. 中国富士苹果种植的气候适宜性研究 [J]. 气象学报, 2016, 4(3): 479-490. [QU Z J, ZHOU G S. Climatic suitability of potential Fuji apple cultivation distribution in China. Acta Meteorologica Sinica, 2016, 74(3): 479-490. ]
[28] 高爱农, 姜淑荣, 赵锡温, 等. 苹果品种抗寒性测定方法的研究 [J]. 果树学报, 2000, 17(1): 17-21. [GAO A N, JIANG S R, ZHAO X W. Study on the hardiness of apple cultivars. Journal of Fruit Science, 2000, 17(1): 17-21. ]
[29] 郁俊谊, 张继澍. 秦冠和富士苹果临界致死低温测定 [J]. 陕西农业科学, 1994(2): 28. [YU J Y, ZHANG J S. To venturiainaequalis and Fuji apple critical low temperature measurement. Shaanxi Journal of Agricultural Sciences, 1994(2): 28. ]
[30] GUISAN A, EDWARDS T C, HASTIE T. Generalized linear and generalized additive models in studies of species distributions: Setting the scene [J]. Ecological Modelling, 2002, 157(2/3): 89-100.
[31] 刘新安, 于贵瑞, 范辽生, 等. 中国陆地生态信息空间化技术研究(Ⅲ)——温度、降水等气候要素 [J]. 自然资源学报, 2004, 19(6): 818-825. [LIU X A, YU G R, FAN L S , et al. Study on spatialization technology of terrestrial eco-information in China (III): Temperature and precipitation. Journal of Natural Resources, 2004, 19(6): 818-825. ]
[32] KENDALL M G. Rank Correlation Methods [M]. London: Griffin, 1975.
[33] 符淙斌, 王强. 气候突变的定义和检测方法 [J]. 大气科学, 1992, 16(4): 482-493. [FU C B, WANG Q. The definition and detection of the abrupt climatic change. Scientia Atmospherica Sinica, 1992, 16(4): 482-493. ]
[34] 魏凤英. 现代气候统计诊断与预测技术 [M]. 第2版. 北京: 气象出版社, 2007. [WEI F Y. Modern Climate Statistics Diagnosis and Prediction Technology. The Second Edition. Beijing: China Meteorological Press, 2007. ]
[35] ZHAO T B, GUO W D, FU C B. Calibrating and evaluating reanalysis surface temperature error by topographic correction [J]. Journal of Climate, 2008, 21(6): 1440-1446.
[36] 矫梅燕, 周广胜, 陈振林. 农业应对气候变化蓝皮书: 气候变化对中国农业影响评估报告(No 1) [M]. 北京: 社会科学文献出版社, 2014. [JIAO M Y, ZHOU G S, CHEN Z L. Blue Book of Agriculture for Addressing Climate Change: Assessment Report of Climatic Change Impacts on Agriculture in China. Beijing: Social Sciences Academic Pres, 2014. ]
[37] 张克俊. 山东等地苹果树冻害调查 [J]. 西北园艺, 1994(3): 9-10. [ZHANG K J. The survey of freezing injury for apple tree in Shandong. Northwest Gardening, 1994(3): 9-10. ]
[38] 周远明, 李世奎. 辽宁省1980—1981年苹果冻害调查分析 [J]. 辽宁农业科学, 1982(5): 37-40. [ZHOU Y M, LI S K. Investigation and analysis for cold damage of apple from 1980 to 1981 in Liaoning Province. Liaoning Agricultural Sciences, 1982(5): 37-40. ]
[39] 杨秋珍, 徐明, 李军. 对气象致灾因子危险度诊断方法的探讨 [J]. 气象学报, 2010, 68(2): 277-284. [YANG Q Z, XU M, LI J. A quantitative and objective approach to diagnosing the hazard degree of the meteorological disastrous factors. Acta Meteorologica Sinica, 2010, 68(2): 277-284. ]