中国农业气象
中國農業氣象
중국농업기상
AGRICULTURAL METEOROLOGY
2015年
3期
254-262
,共9页
李翔翔%居辉%严昌荣%刘勤%李迎春
李翔翔%居輝%嚴昌榮%劉勤%李迎春
리상상%거휘%엄창영%류근%리영춘
降蒸差%潜在蒸散%时空变化%农业亚区%黄淮海平原
降蒸差%潛在蒸散%時空變化%農業亞區%黃淮海平原
강증차%잠재증산%시공변화%농업아구%황회해평원
Water deficit%Potential evapotranspiration%Spatio ̄temporal pattern%Sub ̄regions%Huang ̄Huai ̄Hai plain
基于黄淮海平原41个气象站点1961-2013年逐日气象数据,利用 Penman ̄Monteith 公式计算潜在蒸散量,采用降水量与潜在蒸散量差值即降蒸差表征区域水分盈亏状况,结合 ArcGIS 地统计分析、趋势分析及Morlet小波分析,探讨黄淮海平原各季降蒸差的时空变化特征。结果表明:黄淮海平原降蒸差呈南北差异分布,在-650~100mm 区间变化,南部高于北部。夏季降蒸差最高,秋、冬季次之,春季水分亏缺最严重,多年平均亏缺量为210.61mm,远高于其它季节。站点季节降蒸差的年际变化总体呈上升趋势。各农业亚区蒸散量差异不大,降蒸差差异主要由降水导致,鲁西平原鲁中丘陵水浇地旱地二熟区(Ⅵ区)降蒸差最高,为-21.63mm,海河低平原缺水水浇地二熟兼旱地一熟区(Ⅲ区)最低,为-560.42mm。6个亚区春季水分亏缺量分别占区域年总亏缺量的56.4%、51.7%、40.6%、59.7%、59.3%和66.1%。周期分析表明,黄淮海平原Ⅰ-Ⅳ各农业亚区春季降蒸差变化主周期皆为28a,黄淮平原南阳盆地水浇地旱地二熟区和江淮平原丘陵麦稻两熟区(Ⅴ和Ⅵ区)为10a,未来一段时间春季降蒸差将处于偏低期。黄淮海平原水分亏缺量季节性差异较大,干旱发生风险较高,尤以春旱发生频率较高。
基于黃淮海平原41箇氣象站點1961-2013年逐日氣象數據,利用 Penman ̄Monteith 公式計算潛在蒸散量,採用降水量與潛在蒸散量差值即降蒸差錶徵區域水分盈虧狀況,結閤 ArcGIS 地統計分析、趨勢分析及Morlet小波分析,探討黃淮海平原各季降蒸差的時空變化特徵。結果錶明:黃淮海平原降蒸差呈南北差異分佈,在-650~100mm 區間變化,南部高于北部。夏季降蒸差最高,鞦、鼕季次之,春季水分虧缺最嚴重,多年平均虧缺量為210.61mm,遠高于其它季節。站點季節降蒸差的年際變化總體呈上升趨勢。各農業亞區蒸散量差異不大,降蒸差差異主要由降水導緻,魯西平原魯中丘陵水澆地旱地二熟區(Ⅵ區)降蒸差最高,為-21.63mm,海河低平原缺水水澆地二熟兼旱地一熟區(Ⅲ區)最低,為-560.42mm。6箇亞區春季水分虧缺量分彆佔區域年總虧缺量的56.4%、51.7%、40.6%、59.7%、59.3%和66.1%。週期分析錶明,黃淮海平原Ⅰ-Ⅳ各農業亞區春季降蒸差變化主週期皆為28a,黃淮平原南暘盆地水澆地旱地二熟區和江淮平原丘陵麥稻兩熟區(Ⅴ和Ⅵ區)為10a,未來一段時間春季降蒸差將處于偏低期。黃淮海平原水分虧缺量季節性差異較大,榦旱髮生風險較高,尤以春旱髮生頻率較高。
기우황회해평원41개기상참점1961-2013년축일기상수거,이용 Penman ̄Monteith 공식계산잠재증산량,채용강수량여잠재증산량차치즉강증차표정구역수분영우상황,결합 ArcGIS 지통계분석、추세분석급Morlet소파분석,탐토황회해평원각계강증차적시공변화특정。결과표명:황회해평원강증차정남북차이분포,재-650~100mm 구간변화,남부고우북부。하계강증차최고,추、동계차지,춘계수분우결최엄중,다년평균우결량위210.61mm,원고우기타계절。참점계절강증차적년제변화총체정상승추세。각농업아구증산량차이불대,강증차차이주요유강수도치,로서평원로중구릉수요지한지이숙구(Ⅵ구)강증차최고,위-21.63mm,해하저평원결수수요지이숙겸한지일숙구(Ⅲ구)최저,위-560.42mm。6개아구춘계수분우결량분별점구역년총우결량적56.4%、51.7%、40.6%、59.7%、59.3%화66.1%。주기분석표명,황회해평원Ⅰ-Ⅳ각농업아구춘계강증차변화주주기개위28a,황회평원남양분지수요지한지이숙구화강회평원구릉맥도량숙구(Ⅴ화Ⅵ구)위10a,미래일단시간춘계강증차장처우편저기。황회해평원수분우결량계절성차이교대,간한발생풍험교고,우이춘한발생빈솔교고。
Water shortage is recognized as the most serious problem for agriculture production in Huang ̄Huai ̄Hai plain (3H plain) and the changing characteristics for water resources in context of climate change remains unknown yet. Based on measured meteorological data obtained from 41 stations located in 3H plain,potential evapotranspiration was calculated by applying Penman ̄Monteith equation,and water deficit was described as the difference of precipitation and potential evapotranspiration at the same period. Finally, the spatial and temporal variation characteristics of water deficit in four seasons over 3H plain were analyzed by using Kendall ̄Theil robust line method,Mann ̄Kendall trend test and Morlet wavelet function. Results showed that multi ̄year average water deficit was negative in most part of 3H plain and varied between  ̄650mm and 100mm with the spatial variation pattern of decreasing gradually from south to north. Among four seasons,spring was presented as the most serious water situation with the shortage of 210. 61mm in multi ̄year average,which was higher than any other seasons. Trend analysis of seasonal multi ̄year average water deficit among 41 stations generally shown an upward trend except in autumn where only stations surrounding Jing ̄Jin ̄Ji district increased. Annual water deficit variation among 6 sub ̄regions was - 391. 45, - 510. 11, - 560. 42, - 427. 21,-284. 19 and -21. 63mm in respectively and this variation was mainly induced by precipitation. For seasonal difference in 6 sub ̄regions, spring amounts for the highest water shortage period which occupied annual water shortage at 56. 4% , 51. 7% , 40. 6% , 59. 7% , 59. 3% and 66. 1% , respectively. Spring water deficit showed higher period, lower period alternately with the main period of 28 years for these six regions, 10 years for region V and VI. The seasonal and spatial difference of water deficit in 3H plain indicated a high drought risks with spatio ̄temporal variability, especially in spring season. Thus, effective climate changing adoption needs water resources be operated rationally and agriculture irrigation arrangements with seasonal.