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1.
为了找出青藏高原与东西部各分区大气热源的变化规律,利用美国国家环境预报中心的月平均温度场、比湿场、风场以及位势高度场的再分析格点资料,采用"倒算法"计算得到高原地区月平均大气热源原始格点资料,对比分析青藏高原全区与东西部各分区大气热源在1948~2011年的年际和年代际变化特征,证实青藏高原大气热源的时空分布具有显著的差异性,研究结果表明:青藏高原全区和东西各分区的大气热源均表现出明显的年际振荡特征。在变化周期方面,青藏高原全区大气热源存在14年的显著周期,高原东部地区大气热源存在16年的显著周期,高原西部地区大气热源存在8年的显著周期。在变化趋势方面,青藏高原西部地区和东部地区1989年前,大气热源变化趋势相同,1989年后,大气热源变化趋势相反。在大气热源各个季节的空间分布方面,青藏高原全区大气热源各个季节热源热汇分布特征不同,春季西部地区出现热源中心,夏季东部地区出现热源中心,秋季东部地区出现热汇中心,冬季出现西部地区热源中心和东部地区热汇中心共存;在变化趋势突变检测方面,青藏高原全区大气热源在1989年存在显著的突变,西部地区大气热源1976年左右存在显著的突变,东部地区大气热源在1990年左右存在显著的突变。 相似文献
2.
青藏高原-热带印度洋地区大气热源的时空变化特征 总被引:1,自引:0,他引:1
为了寻求青藏高原一热带印度洋地区大气热源空间变化的敏感区,进一步深入研究季风的形成、变异和预测,利用NCEP1979-2008年的再分析资料计算分析了青藏高原一热带印度洋地区30年来不同季节大气热源分布的气候特征,并且利用经验正交函数分解研究了该区大气热源在夏、冬季的时空变化特征。结论如下:春季大气热源有明显的经向差异;夏季的热源明显比春季的热源强度强,范围广,热源最强中心在孟加拉湾北部大陆边缘;秋季热源区域明显南缩,热源强度较夏季明显减弱;冬季大气热源呈西西南一东东北方向分布,大气热源位置继续南移。对于夏季,前3个模态分别反映了青藏高原一热带印度洋地区大气热源的纬向差异型、经向差异型、西北一东南分布型。对于冬季,前3个模态分别反映了青藏高原一热带印度洋地区大气热源的经向差异主导型、经向差异型、纬向差异型。 相似文献
3.
《广东海洋大学学报》2019,(6)
【目的】综述前人对青藏高原大气热源的研究成果,探究大气热源与南海夏季风的关系。【方法】归纳高原大气热源研究进展,采用诊断分析方法探究高原热源的时空分布及与南海夏季风的关系。【结果】1)青藏高原夏季(冬季)大气是热(冷)源,冷热源的季节转换发生在3月,热源强度7月达到最大;2)热源中潜热贡献最大;3)不同资料和方法在描述热源时空分布时存在一定不确定性;4)高原夏季大气热源与南海夏季风呈明显负相关。基于大气热源,构造南海-青藏高原夏季海陆热力性质差异指数,该指数显示1980―2016年海陆热力性质差异有年代际减小的趋势。 相似文献
4.
利用NECP/NCAR月平均再分析资料,研究1951~2010年夏季青藏高原主体大气热源分布、对东亚地区的环流影响及其与同期中国降水的关系.针对高原加热局地特征明显的特点,采用旋转经验正交函数等方法探讨不同类型的热源分布以及对东亚地区大气环流的影响.结果表明,当加热中心位于高原东南侧时,青藏高原夏季风加强,南亚高压偏南偏东,西太平洋副热带高压西伸加强,而东亚中高纬地区两脊一槽的经向环流分布形势明显,有利于中国长江流域的降水而不利于华南华北的降水发展.当加热中心位于高原中北部与西南地区时,青藏高原夏季风减弱,南亚高压偏西,西太副高明显偏东偏弱,中高纬环流的纬向特征明显,有利于中国地区北方降水而不利于南方地区的降水. 相似文献
5.
使用2001年和2003年NCEP/NCAR再分析资料计算夏季亚洲季风区大气热源(汇),再用BUTTER-WORTH带通滤波器对原始热源(汇)场进行带通滤波,得到2001与2003年夏季30-60天的大气热源(汇)的低频分量,然后分析两年夏季东亚各区域大气热源(汇)及其低频变化特征、传播特征和传播差异,得出以下结论:(1)2001年呈连续带状分布;2003年热源中心分布零散且位置显著东移,热源(汇)强度比2001年减弱;(2)2001年和2003年低频分量的平均分布有明显差异,且旱年低频分量强度远大于涝年;(3)2001年低频振荡向北传播范围仅到20°N-30°N的华南至江南地区,而2003年低频振荡多数可达30°N以北的江淮流域;(4)2001年低频分量纬向传播均为自西向东,而2003年在6-8月期间自东向西传播,5月和9月则主要由西向东传播。因此,江淮流域典型旱涝年分2001年和2003年在低频分量的配置和低频波的传播上存在明显差异,这可能正是导致这两年气候巨大差异的原因之一。 相似文献
6.
积雪深度是表征积雪特征的重要参数,也是区域气候变化最敏感的响应因子之一。利用1979-2010年逐日中国雪深长时间序列数据集,采用GIS空间分析和地统计方法,分析了青藏高原积雪深度的时空变化规律及异常空间分布特征。结果表明:近32年来,青藏高原雪深呈显著增加趋势,增加速率为0.26 cm/10a,其中,昆仑高寒荒漠地带雪深增加最为明显,增加速率达0.73 cm/10a;20世纪80年代至90年代青藏高原雪深呈逐步增加趋势,21世纪初变化平稳;青藏高原4个季节雪深变化均呈现为上升趋势,尤以冬季增加最为明显,增加速率达0.57 cm/10a。青藏高原东南、西部和南部为雪深分布高值区;逐像元回归分析表明,高原雪深呈增加趋势的像元数占全区像元总数的67.1%,其中有91.3%为轻度和中度增加,主要分布在高原北部和西部;最大雪深变化基本维持在-0.1~0.1 cm/a(45.47%)之间,在昆仑北翼山地、柴达木山地、羌塘高寒地带南部等局部地区最大雪深有增加趋势,主要是轻度增加,面积比例为36.66%。果洛那曲高寒地带、青南高寒地带和羌塘高寒地带为青藏高原积雪深度异常变化敏感区。 相似文献
7.
采用1948-2007年共60年的NCEP/NCAR资料,计算了夏季青藏高原地区的可降水量,并采用小波分析方法对可降水量的变化特征进行分析.结果表明:夏季青藏高原上有一个明显的"湿池",湿池有3个可降水量中心,分别位于高原西南部、高原南侧和高原东南部.湿池3个中心的可降水量变化有着明显的年代际特征,高原西南部以13.9a的周期变化最为明显,高原南侧9.2a的周期变化最为明显,高原东南部时间尺度2.6a的周期变化最为明显.趋势分析表明,高原西南部的可降水量可能开始增加,而高原南侧和高原东南部的可降水量应该依然处于偏少的阶段. 相似文献
8.
青藏高原冬季降水的气候特征认识对高原冬季雪灾的防御有着重要意义。基于青藏高原54个气象站1971~2010年冬季(12~2月)逐月降水量资料,利用现代统计方法分析了青藏高原冬季降水的时空分布特征及突变现象,利用经验正交函数(EOF)和旋转经验正交函数(REOF)概括出高原冬季降水的6种主要空间分布型以及区域性特征进行分析。结果表明:冬季降水分布不均匀,偏东偏南部降水量相对较多,冬季降水在12月最少,2月最多;EOF对青藏高原地区冬季降水分解为6种模态,全区一致型、南北部型、东西部型、川西型、高原腹地型和西部型模态;EOF第1模态时间系数表明高原大部分地区冬季降水在20世纪90年代有显著增加、且存在14年左右的周期变化特征。REOF分析表明,高原地区冬季降水的局地特征显著,而高原腹地与中东部地区变化特征显示了高原冬季降水的主要变化特征,与EOF分析第1模态的变化特征较为一致。 相似文献
9.
四川地区44年来气候季节划分及变化特征的研究 总被引:2,自引:0,他引:2
利用四川地区135个台站的逐日温度资料和曾庆存等[1]提出的季节划分方法讨论了四川各区域的气候季节划分和季节变化,结果表明:(1)1961~2004年期间,四川地区季节的四季分配很不均匀,冬夏季偏长,春秋季偏短;并且四川不同区域间的季节划分差异主要表现在春秋两季的时间长度上.(2)季节划分的年际变化表现为春季西部高原地区有两次时间长度增加和两次减少的变化特征,在两次时间长度增加的过程中出现了一次明显的季节长度突变;高原与盆地过渡区1996年以后春季长度年际差异显著减小,东部盆地地区近年来春季时间长度明显增加.(3)季节强度指数表明,冬季西部高原和中部高原与盆地的过渡地区变暖、夏季在1960~1970年代变冷的趋势;东部盆地冬季在1970年代中后期至1980年代强度变化剧烈、夏季则显示出1982年以前逐渐变冷、以后逐渐变暖的特征.(4)成都城市群表现出春秋过渡季节更加短暂、四季分配更不均匀、气候变化幅度增大的特征. 相似文献
10.
为了加强高原高空西风变化及其与降水关系的研究,利用NCEP/NCAR月平均再分析资料及中国160个测站月降水资料,采用线性倾向估计、小波分析、相关分析等方法,对青藏高原夏季200hPa西风近几十年的变化特征及其与中国降水的关系进行分析。结果表明:自1948年青藏高原夏季200hPa西风整体呈现显著增强趋势;且高原西风在20世纪50年代前期偏弱,在50年代中后期开始增强,并在80年代出现近62年的最大值,90年代末高原高空西风略有减弱,但不明显;小波分析表明高原200hPa西风具有2~4a的周期,且这一周期成分在50年代及70年代末至80年代前期这两个时段比较显著;高原西风的突变分析表明在1954年发生了一次较明显的增强突变。高原夏季200hPa西风与中国降水关系的分析表明:高原西风增强时在长江流域以北的中国大部分地区降水偏多,以江淮流域、川渝地区西部和东部省界以及中国西北、东北的部分地区表现显著,长江流域以南的大部分地区降水偏少,其中华南沿海及中国西南地区西南部降水偏少更加明显,降水场与大气环流有较好的配置关系。 相似文献
11.
The knowledge of contemporary climatic change over the Qinghai-Xizang (Tibet) Plateau (QXP) has been inadequate for a long
time due to lack of enough observational data. In this paper, on the basis of monthly temperature and precipitation data in
1961–1990 from 48 stations on the QXP, the temperature data are extended backward to 1901 with an empirical orthogonal function
(EOF) method, microscopic characteristics of contemporary climatic change over the QXP are analyzed, and the response of the
plateau climate to global warming is discussed in combination with atmospheric general circulation model (GCM) outputs. The
results show that the plateau climate, as a whole, has been warming since the early part of this century, that the precipitation
has generally been increasing during the recent 30 years, and that these climatic trends seem to be related to the enhanced
green-house effect induced by increasing CO2 concentration in the atmosphere.
This work is supported by the National and CAS (the Chinese Academy of Sciences) Tibet Research Project. 相似文献
12.
LAST GLACIATION AND MAXIMUM GLACIATION IN THE QINGHAI-XIZANG (TIBET) PLATEAU: A CONTROVERSY TO M. KUHLE,S ICE SHEET HYPOTHESIS 总被引:1,自引:0,他引:1
Since the late 1950's, many Chinese scientists have explored the remains of the Quaternary glaciation in the Qinghai-Xizang (Tibet) Plateau and its surrounding mountains. In the main, 3-4 glaciations have been recognized. The largest one occurred in the Late Middle Pleistocene with piedmont glaciers, ice caps and trellis valley glaciers in many high peak regions. But here is no evidence of a unified ice sheet covering the whole plateau as described by M. Kuhle. Due to the further uplifting of the Himalayas and Qinghai-Xizang Plateau the climate became progressively drier, diminishing the extension of glaciers during the Late Pleistocene. The elevation of the snow line during the Last Glaciation was about 4,000 m on the south, east and northeast edges of the plateau and ascended to 5500 m on the hinder northwest of the plateau. The thermal effect of the big plateau massif, the sharp increase of aridity from the southeast rim to the northwest inland area and the abrupt decrease of precipitation during the 相似文献
13.
Since the late 1950’s, many Chinese scientists have explored the remains of the Quaternary glaciation in the Qinghai-Xizang
(Tibet) Plateau and its surrounding mountains. In the main, 3–4 glaciations have been recognized. The largest one occurred
in the Late Middle Pleistocene with piedmont glaciers, ice caps and trellis valley glaciers in many high peak regions. But
here is no evidence of a unified ice sheet covering the whole plateau as described by M. Kuhle. Due to the further uplifting
of the Himalayas and Qinghai-Xizang Plateau the climate became progressively driver, diminishing the extension of glaciers
during the Late Pleistocene. The elevation of the snow line during the Last Glaciation was about 4,000 m on the south, east
and northeast edges of the plateau and ascended to 5500 m on the hinder northwest of the plateau. The thermal effect of the
big plateau massif, the sharp increase of aridity from the southeast rim to the northwest inland area and the abrupt decrease
of precipitation during the Ice Age largely account for the distribution of the Quaternary glaciers in the Qinghai-Xizang
Plateau. The neglect of Chinese literature may be one of the causes accounting for M. Kuhle’s misinterpretation on the environment
of the Quaternary glaciations in the Qinghai-Xizang Plateau. 相似文献
14.
PALEOSOLSANDTHEIRREFLECTIONOFTHEENVIRONMENTALCHANGESINTHENORTHEASTREGIONOFTHEQINGHAI-XIZANGPLATEAU徐叔鹰,潘保田PALEOSOLSANDTHEIRREF... 相似文献
15.
Based on field investigations, laboratory analyses and 14C dating, this paper discusses the laws of the formation and development of the paleosols in the northeast region of the Qinghai-Xizang
Plateau since Late Pleistocene. The authors reconstruct basic conditions of climate, vegetation, soil and natural zones during
the three periods in which the paleosols were formed, i.e. the last interglacial of the Late Pleistocene, warm stage of Late
Glacial and the Optimum of Holocene. Finally, this paper discusses the relationship between the paleosols and the uplift of
the Qinghai-Xizang Plateau. 相似文献
16.
The Qinghai-Xizang (Tibet) Plateau area was subjected to twice uplift and planation in the Tertiary. Intense uplifting of
the plateau area has given rise to drastic changes and differentiation of physical environment on the plateau and the surrounding
area since 3.4 Ma B.P. Significant environmental changes with dry tendency in interior of the plateau had occurred during
the last 150 ka B.P. By comparative study on several mountains of the plateau, two systems of the structure-type of the altitudinal
belt are identified and nine groups are subdivided. A distribution model with close relevance to highland uplift effect has
been generalized. A number of striking geo-ecological phenomen and their spatial pattern such as moisture corridor, dry valleys,
high-cold meadow zone, and high-cold arid core area are investigated and discussed. Based on the thermal conditions, moisture
regimes and variation in landforms of the plateau is sequentially demarcated. A tentative scheme of 2 temperature belts, 10
natural zones and 28 physical districts has been proposed not including southern slopes of the East Himalayas. The Qinghai-Xizang
Plateau is sensitive to “green house effect”, showing close relation with global change. Characteristics of temperature and
precipitation on the plateau during the last 2000 years, and response of glaciers, snow deposit and permafrost on the plateau
to global change are dealt with in the present paper.
Under the auspices of Chinese National Key Project for Basic Research (G1998040800) and CAS project on the Qinghai-Xizang
Plateau (KZ951 - A1 - 204, KZ95T - 06) 相似文献
17.
全球气候的不断变化使得生物生境受到极大影响。气温作为最基本的气候要素,其变化迁移会胁迫生物对此做出响应,造成生物群落的迁徙。气温变化速度将气温看作物质的运动,能够直观地表示气温时空变化特征,对研究生物分布地理界限变化具有重要的指导意义。本文利用1961-2013年的全国每月平均温度数据集,分析了过去50多年中国东北与华北地区之间气温变化速度的区域差异。结果表明:东北与华北两地区整体气温变化速度均值为5.60 km/year,速度范围主要集中于0~9 km/year之间,约占总数的90%。东北地区气温变化速度均值大于华北地区。其中,东北速度均值为5.85 km/year,华北为5.41 km/year。从区域内部来看,东北地区气温变化速度整体较高,三省中黑龙江与吉林速度较高,辽宁省速度变化相对较小。华北气温变化速度高值区域主要分布在内蒙古高原与河北、天津的小部分地区,其他地区的气温变化速度则相对较小。 相似文献
18.
Based on high-resolution tree-ring data from Dulan area of Qinghai Province, five spells have been divided: the warm period
before 230’s A. D., the cold period between 240’s A. D. and 800’s A. D., the significantly warm period between 810’s A. D.
and 1070’s, i. e. “Medieval Warm Period”, the cold period including the “Little Ice Age” 1420’ – 1870’s and the warming period
since 1880’s. All the eleven coldest or warmest decades and several great abrupt changes took place before the Middle Ages,
indicating that climatic system operated in great instability during the period 150’s – 1100’s A. D., Comparison of the tree-ring
data with other temperature proxy data from East China, Guliya ice core as well as the south of Qinghai-Xizang Plateau shows
that such great climatic events as Eastern Han warm period between the beginning of the 1st century and the previous fifty
years of the third century, the cold period covering the span of the Wei, the Jin, and the Southern and Northern dynasties,
the well-known “Medieval Warm Period” as well as the “Little Ice Age” appeared in these series such as East China and Dulan
area. Only the first two climatic events were recorded conspicuously in Guliya ice core while the “Medieval Warm Period” and
“Little Ice Age” is far weaker. Also, the well-defined “Medieval Warm Period” didn’t occurred in the south of Qinghai-Xizang
Plateau. The warming since the 20th century is the warmest in the last 2000 years Guliya ice core, the second in Dulan area
and East China, but it scarcely seems pronounced in the eastern part of Qinghai-Xizang Plateau.
Foundation item: Under the auspices of the projects of the Chinese Academy of Sciences (KZ951-A1-204-02 and KZ951-A1 402-03).
Biography: YANG Bao(1971–), male, a native of Yanggao County, Shanxi Province, Ph. D. His research interestinclude global
change. 相似文献
19.
Zhao Kuiyi 《中国地理科学(英文版)》1997,8(1):44-52
The southern part of the Qinghai-Xizang (Tibet) Plateau and its adjacent area are rich in mire flora. There are 51 families,
101 genera and 220 species. The geographical compositions of this region are very complex, consisting of the following-geographical
elements: tropic-subtropic elements approximating to 8.33% of the entire flora in the region, tropic-temperate elements 22.71%,
temperate elements 43.18%, cosmopolitan elements 9.85%, the Qinghai-Xizang endemic elements 14.39%, north polemountain elements
1.51%. Temperate elements in this region are dominant. The dominant species of mires, Carex lasiocarpa, in this region is also found in northeast China, Finland and North America. The origin of mires of this region is earlier
than northeast China and Finland. This shows that the southern part of the Qinghai-Xizang Plateau and its adjacent areas may
be the centre of the origin and distribution of temperate elements. 相似文献
20.
本文利用MODIS数据反演大气透射率,利用HJ-1B/CCD进行分类,并反演地表比辐射率.在此基础上,借鉴单窗算法,利用HJ-1B/IRS数据反演得到地表温度,并利用MODIS温度产品对反演结果进行了初步验证.最后利用热场变异指数进一步分析重庆的热岛空间分布特征,并对NDVI与NDBI对热岛效应的影响进行了分析.其结论... 相似文献