中国北方苹果主产省降水分布特征分析

doi:10.3969/j.issn.1000-6362.2020.05.001

摘要/Abstract

摘要： 利用1970-2017年7个中国苹果主产省及周边210个气象站逐日降水资料和1km分辨率的数字高程数据，采用基于样条函数插值理论的专业气象插值软件ANUSPLIN对降水数据进行空间插值。结合地理信息系统软件ArcGIS和变异系数、气候倾向率等相关数理统计方法，分析苹果主产省的降水时空分布特征；并根据适宜苹果栽培的年降水量区间和苹果主产区降水分布情况探析苹果关键生育期适宜降水量。结果表明：苹果主产省年平均降水量与关键生育期平均降水量均具有南高北低、东高西低的空间分布特征，约51.7%的区域年降水量为500.0~800.0mm，其中，主产区的年降水量基本在500.0～800.0mm。萌芽-幼果期、果实膨大期和着色-成熟期平均降水量对年平均降水量的贡献率分别为0.114～0.385、0.428～0.712和0.000～0.270。研究区降水时间分配与苹果需水规律较吻合，但降水量变异系数较大，基本在0.15以上。从气候倾向率看，大多数区域降水量的变化趋势不显著，除着色-成熟期外，各时段降水量变化通过0.05水平显著性检验的区域不足1.0%。结合苹果主产区和苹果适宜栽培的年降水量值，初步判定苹果萌芽-幼果期、果实膨大期和着色-成熟期的适宜降水量范围分别为66.2～170.2mm、238.4～527.9mm和69.0～200.8mm。

关键词: , 苹果, 降水, 适宜降水量, 果实膨大期, ANUSPLIN

Abstract: Water overabundance or shortage both affect apple growth and fruit quality. Precipitation is the main water source in apple production in Northern China. Thus, analysis on the spatial and temporal variations in precipitation in main apple producing provinces of Northern China under the setting of climate change is of great significance to guide the rational layout of apple industry. Based on the daily precipitation data measured at 210 meteorological stations from 1970 to 2017 and the digital elevation model of 1km resolution in seven major apple producing provinces (Liaoning, Hebei, Shandong, Shanxi, Henan, Shaanxi and Gansu) and their surrounding areas within 100 kilometers in China, the professional meteorological interpolation software ANUSPLIN, which is based on spline interpolation method, was used to interpolate precipitation data. Then, the refined meteorological grid data of 0.02°×0.02°resolution were obtained. Combined with the geographic information system software ArcGIS and related mathematical statistics methods (e.g., the variation coefficient and climate tendency rate), the calculation and spatial expression of various statistics were carried out on the basis of grid data to analyze the spatial-temporal distribution characteristics of precipitation in major apple producing provinces. The suitable precipitation in the key growth periods of apple were explored according to the annual precipitation range (500.0-800.0mm) which is suitable for apple cultivation and to the distribution of precipitation in the main apple producing areas. The results showed that both the average annual precipitation in the main apple producing provinces and the average precipitation in the key growth periods had the same spatial distribution, i.e. high in the south and low in the north, and high in the east and low in the west. The annual precipitation in about 51.7% of the interest area was between 500.0-800.0mm, and the precipitation in the main apple producing areas was basically 500.0-800.0mm. There were about 55.2%, 51.2% and 40.9% of the study area in the wet year, the normal year and the dry year respectively, where the annual precipitation was between 500.0-800.0mm. The contribution rates of the average precipitation in germination and young fruit period, fruit expanding period and coloring and maturity period to the annual average precipitation were 0.114-0.385, 0.428-0.712 and 0.000-0.270, respectively. The precipitation in fruit expanding period is more than that in other two periods. And the contribution rate of precipitation in coloring and maturity period was higher than that in germination and young fruit period in most areas. The distribution of precipitation time was consistent with apple water requirement. But the variation coefficient of precipitation was generally above 0.15. In terms of climate tendency rate, the precipitation variation trends were not obvious in most regions, except for the coloring and maturity period where 6.3% and 7.9% of the study region showed a significant increase (P<0.05) and a significant decrease (P<0.05), less than 1.0% of the study region passed the 0.05 level significance test in other growth periods. Combined with the temporal and spatial distribution of precipitation in each growth period in main apple producing area and annual precipitation values that was suitable for apple cultivation, it was preliminarily determined that the suitable precipitation ranges of apple in the germination and young fruit period, fruit expanding period and coloring and maturity period of apple were 66.2-170.2mm, 238.4-527.9mm and 69.0-200.8mm, respectively. There were some differences in the precipitation range of main apple producing areas in each province, but they were basically within the above-mentioned precipitation range.

Key words: Apple, Precipitation, Suitable precipitation, Fruit expanding period, ANUSPLIN

中图分类号:

邱美娟，刘布春，刘园，张玥滢，王珂依，庞静漪. 中国北方苹果主产省降水分布特征分析[J]. 中国农业气象, 2020, 41(05): 263-274.

QIU Mei-juan, LIU Bu-chun, LIU Yuan, ZHANG Yue-ying, WANG Ke-yi, PANG Jing-yi. Analysis on Distribution Characteristics of Precipitation in Major Production Provinces of Apple in Northern China[J]. Chinese Journal of Agrometeorology, 2020, 41(05): 263-274.

参考文献

[1] 张存杰,高学杰,赵红岩.全球气候变暖对西北地区秋季降水的影响[J].冰川冻土,2003,25(2):157-164. Zhang C J,Gao X J,Zhao H Y.Impact of global warming on autumn precipitation in Northwest China[J].Journal of Glaciology and Geocryology,2003,25(2):157-164.(in Chinese) [2] 智协飞,张玲,潘嘉露,等.我国南方冬季气候变暖前后极端降水事件分析[J].热带气象学报,2011,27(2):166-172. Zhi X F,Zhang L,Pang J L,et al.An analysis of the winter extreme precipitation events on the background of southern China climate warming[J].Journal of Tropical Meteorology, 2011,27(2):166-172.(in Chinese) [3] 任利利,殷淑燕,靳俊芳.1960-2011年汉江上游降水量变化特征和区域差异[J].中国农业气象,2014,35(4):365-372. Ren L L,Yin S Y,Jin J F.Variation and regional difference of annual precipitation in the upper reaches of Hanjiang river during 1960-2011[J].Chinese Journal of Agrometeorology, 2014,35(4):365-372.(in Chinese) [4] Duan Y W,Wu P L,Chen X L,et al.Assessing global warming induced changes in summer rainfall variability over eastern China using the latest hadley centre climate model HadGEM3-GC2[J].Advances in Atmospheric Sciences,2018, 35(8):1077-1093. [5] 赵政阳.中国果树科学与实践·苹果[M].西安:陕西科学技术出版社,2015. Zhao Z Y.Science and practice of fruit trees in China·Apple[M].Xi·an:Shaanxi Science and Technology Publishing House,2015.(in Chinese) [6] 国家统计局.中国统计年鉴[M].北京:中国统计出版社,2018. National Bureau of Statistics of China.China statistical yearbook[M].Beijing:China Statistics Press,2018.(in Chinese) [7] 马孝义,王文娥,康绍忠,等.陕北、渭北苹果降水产量关系与补灌时期初步研究[J].中国农业气象,2002,23(1):25-28. Ma X Y,Wang W E,Kang S Z,et al.The relationship between apple production and rainfall and the compensation irrigation period in North Shaanxi and Weibei[J].Chinese Journal of Agrometeorology,2002,23(1):25-28.(in Chinese) [8] 段晓凤,张磊,金飞,等.气象因子对苹果产量、品质的影响研究进展[J].中国农学通报,2014,30(7):33-37. Duan X F,Zhang L,Jin F,et al.Research progress of effects of meteorological facts on apple yield and quality[J].Chinese Agricultural Science Bulletin,2014,30(7):33-37.(in Chinese) [9] 任国玉,吴虹,陈正洪.我国降水变化趋势的空间特征[J].应用气象学报,2000,11(3):322-330. Ren G Y,Wu H,Chen Z H.Spatial patterns of change trend in rainfall of China[J].Quarterly Journal of Applied Meteorology, 2000,11(3):322-330.(in Chinese) [10] 王麒翔,范晓辉,王孟本.近50年黄土高原地区降水时空变化特征[J].生态学报,2011,31(19):5512-5523. Wang Q X,Fan X H,Wang M B.Precipitation trends during 1961-2010 in the Loess Plateau region of China[J].Acta Ecologica Sinica,2011,31(19):5512-5523.(in Chinese) [11] 王利娜,朱清科,仝小林,等.黄土高原近50年降水量时空变化特征分析[J].干旱地区农业研究,2016,34(3):206-212. Wang L,Zhu Q K,Tong X L,et al.Characteristic analysis of temporal and spatial variation of precipitation during recent 50 years in Loess Plateau[J].Agricultural Research In The Arid Areas,2016,34(3):206-212.(in Chinese) [12] 段丽瑶,杨艳娟,李明财.近50年环渤海湾地区夏季降水时空变化特征[J].高原气象,2013,31(1):243-249. Duan L Y,Yang Y J,Li M C.Spatial-temporal changes of summer precipitation in the Bohai rim in recent 50 years[J]. Plateau Meteorology,2013,31(1):243-249.(in Chinese) [13] 郭军,李明财,段丽瑶.环渤海地区1961-2007年极端强降水时空变化特征[J].气候变化研究进展,2010,6(5):319-324. Guo J,Li M C,Duan L Y.Spatial-temporal variations of extremely heavy precipitation in the circum-Bohai sea region during 1961-2017[J].Advances in Climate Change Research,2010,6(5):319-324.(in Chinese) [14] 陶建,董建新,刘光亮,等.西南不同农业区气温和降水量沿海拔梯度的变化特征[J].中国农业气象,2016,37(4): 379-389. Tao J,Dong J X,Liu G L,et al.Characteristics of temperature and precipitation change along increasing elevations in different agriculture regions of Southwest China[J].Chinese Journal of Agrometeorology,2016,37(4):379-389.(in Chinese) [15] 夏阳,万雪丽,严小冬,等.中国西南地区春季降水的时空变化及其异常的环流特征[J].气象学报,2016,74(4):510-524. Xia Y,Wan X L,Yan X D,et al.Variations of spring precipitation over southwest China and characteristic circulations for precipitation anomalies[J].Acta Meteorologica Sinica,2016,74(4):510-524.(in Chinese) [16] 郑丽娜.近55a中国西北地区夏季降水的时空演变特征[J].海洋气象学报,2018,38(2):50-59. Zheng L N.Spatial and temporal variations of summer precipitation in Northwest China over the past 55 years[J].Journal of Marine Meteorology,2018,38(2):50-59. (in Chinese) [17] 孙悦,高继卿,杨晓光.西北各省季节降水变化及其贡献的差异分析[J].中国农业气象,2019,40(8):489-501. Sun Y,Gao J Q,Yang X G.Seasonal variation about the occurrence frequency of different types of precipitation and their relative contribution over Northwest China[J].Chinese Journal of Agrometeorology,2019,40(8):489-501.(in Chinese) [18] 刘勤,严昌荣,张燕卿,等.近50年黄河流域气温和降水量变化特分析[J].中国农业气象,2012,33(4):475-480. Liu Q,Yan C R,Zhang Y Q,et al.Variation of precipitation and temperature in Yellow River Basin during the last 50 years[J].Chinese Journal of Agrometeorology,2012,33(4): 475-480.(in Chinese) [19] 李玲萍,刘维成,杨梅,等.1971-2015年青藏高原东北边坡降水特征及主要影响因子分析[J].冰川冻土,2018,40(5): 916-924. Li L P,Liu W C,Yang M,et al.Precipitation characteristics and its affecting factors on the northeast slopes of Qinghai-Tibet Plateau from 1971 to 2015[J].Journal of Glaciology and Geocryology,2018,40(5):916-924.(in Chinese) [20] 周梦子,周广胜,吕晓敏,等.1.５和２℃升温阈值下中国温度和降水变化的预估[J].气象学报,2018,77(4):728-744. Zhou M Z,Zhou G S,Lu X M,et al.Projection of temperature and precipitation changes over China under global warming of 1.5 and 2℃[J].Acta Meteorologica Sinica,2018,77(4): 728-744.(in Chinese) [21] 陆秋农.我国苹果的分布区划与生态因子[J].中国农业科学,1980,(1):46-51. Lu Q N.The distribution and ecologic factors of apples in China[J].Agricultural Sciences in China,1980,(1):46-51.(in Chinese) [22] 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,(4):2-7. Li S K,Zhu J M,Zhou Y M,et al.Apple planting regionalization research in China[J].Shanxi Fuirts,1985,(4): 2-7.(in Chinese) [23] 刘延莉.延安地区苹果北扩气候区划及干旱风险评估[D].南京:南京信息工程大学,2014. Liu Y L.North expansion climate zoning and drought risk assessment of apple in Yanan[D].Nanjing:Nanjing University of Information Science & Technology,2014.(in Chinese) [24] 李青华,穆艳,王延平.黄土丘陵沟壑区山地苹果林蒸散特征[J].地球科学,2019,44(8):2818-2828. Li X H,Mu Y,Wang Y P.Evapotranspiration characteristics of apple forest in hilly-gully region of the Loess Plateau[j]. Earth Science,2019,44(8):2818-2828.(in Chinese) [25] 黄丽,范兴科.陕北矮化栽培山地苹果幼树需水规律预判[J].水土保持学报,2018,32(6):200-207. Huang L,Fan X K.Predicting the water requirement of dwarf planted apple sapling in northern Shaanxi[J].Journal of Soil and Water Conservation,2018,32(6):200-207.(in Chinese) [26] 周珊珊.渭北高原红富士苹果树蒸腾规律的研究[D].杨凌:西北农林科技大学,2011. Zhou S S.Transpiration of Fuji appple tree in the Weibei plateau[D].Yangling:Northwest A&F University,2011. (in Chinese) [27] 冯志文,姜远茂,田玉政,等.气象因子对红富士苹果树干茎流特性的影响[J].山东农业大学学报(自然科学版),2013, 44 (1):18-24. Feng Z W,Jiang Y M,Tian Y Z,et al.Research on stem sap flow character of Fuji apple trees and the response to main meteorological factors[J].Journal of Shandong Agricultural University,2013,44(1):18-24.(in Chinese) [28] 王景红,梁轶,柏秦凤.陕西主要果树气候适宜性与气象灾害风险区划图集[M].西安:陕西科学技术出版社,2012: 177-181. Wang J H,Liang Y,Bai Q F.Atlas of climate suitability and meteorological disaster risk zoning of major fruit trees in Shaanxi[M].Xi'an:Shaanxi Science and Technology Publishing House,2012:177-181.(in Chinese) [29] 刘志红,McVicar T R,van Niel T G,等.专用气候数据空间插值软件ANUSPLIN及其应用[J].气象,2008,(2):92-100. Liu Z H,McVicar T R,van Niel T G,et al.Introduction of the professional interpolation software for meteorology data:ANUSPLINN[J].Meteorological Monthly,2008,(2):92- 100.(in Chinese) [30] 钱永兰,吕厚荃,张艳红.基于ANUSPLIN软件的逐日气象要素插值方法应用与评估[J].气象与环境学报,2010,26(2): 7-15. Qian Y L,Lv H Q,Zhan Y H.Application and assessment of spatial interpolation method on daily meteorological elements based on ANUSPLIN software[J].Journal of Meteorology and Environment,2010,26(2):7-15.(in Chinese) [31] 贾洋,崔鹏.高山区多时间尺度Anusplin气温插值精度对比分析[J].高原气象,2018,37(3):757-766. Jia Y,Cui P.Contrastive analysis of temperature interpolation at different time scales in the alpine Rregion by Anusplin[J].Plateau Meteorology,2018,37(3):757-766.(in Chinese) [32] 李任君,高懋芳,李强,等.基于ANUSPLIN的降水空间插值方法研究[J].中国农业信息,2019,31(1):48-57. Li R J,Gao M F,Li Q,et al.Research on rainfall spatial interpolation method based on ANUSPLIN[J].China Agricultural Informatics,2019,31(1):48-57.(in Chinese) [33] 徐华军.气候变化背景下宁夏冬、春小麦产量和气象灾害特征比较研究[D].北京:中国农业大学,2015. Xu H J.Comparative study of winter and spring wheat’s yield and meteorological disaster characteristics in Ningxia under the background of climate change[D].Beijing:China Agricultural University,2015.(in Chinese) [34] 魏凤英.现代气候统计诊断与预测技术[M].北京:气象出版社,2007. Wei F Y.Modern climatological statistical diagnosis and prediction methods[M].Beijing:China Meteorological Press,2007.(in Chinese) [35] 张旭阳.陕西省苹果气候适宜性专题区划研究[D].西安:陕西师范大学,2010. Zhang X Y.Study on climate special division of apple in Shaanxi province[D].Xi’an:Shaanxi Normal University, 2010.(in Chinese) [36] 马尚谦,张勃,杨梅,等.基于EEMD的华北平原1901-2015年旱涝灾害分析[J].干旱区资源与环境,2019,33(3):64-70. Ma S Q,Zhang B,Yang M,et al.Analysis on drought and flood disasters in North China Plain from 1901 to 2015 based on EEMD[J].Journal of Arid Land Resources and Environment,2019,33(3):64-70.(in Chinese) [37] 田晶,周彦丽,张楠,等.张家口地区49年区域旱涝变化特征分析[J].农业灾害研究,2014,(9):24-28. Tian J,Zhou Y L,Zhang N,et al.Analysis on the variation characteristics of region-al of flood and drought in Zhangjiakou during 49 years[J].Journal of Agriculutral Catastrophology,2014,(9):24-28.(in Chinese) [38] 张玥滢,刘布春,邱美娟,等.气候变化背景下中国苹果适宜种植区北移西扩:基于高分辨率格点气象数据的区划分析[J].中国农业气象,2019,40(11):678-691. Zhang Y Y,Liu B C,Qiu M J,et al.Areas suitable for growing apples moved northward and westward in China under the background of climate change:climatic degionalization of apple based on high-resolution meteorological grid data[J].Chinese Journal of Agrometeorology,2019,40(11): 678-691.(in Chinese)