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871.
872.
分析了40 a气温、降水及干旱指数的变化特征,结果表明:(1)近40 a石河子地区平均温度以0.3℃/10 a趋势上升,和全疆变化一致;该地区年、冬季、夏季气温总体呈上升趋势,20世纪60~70年代年、冬季、夏季气温呈降低的趋势,80~90年代气温呈增加趋势,80年代冬季升温比夏季升温明显,而90年代夏季升温比冬季明显。(2)降水总体趋势上升,降水增长率为12.5 mm/10 a,90年代平均降水比30 a均值偏多20.8%。(3)年平均干旱指数总体呈下降趋势,但趋势不明显,其减少率为-0.3/10 a。(4)石河子地区的温度、降水及干旱指数用M ann-kendall方法检验分别在不同年份发生了不同程度的突变。结果指出,石河子地区气候正在趋于暖、湿化,这对于本区绿洲的发展具有有利的一面。 相似文献
873.
874.
夏季青藏高原TBB低频振荡及其与华中地区旱涝的关系 总被引:4,自引:1,他引:4
利用17年(1980—1994年和1997—1998年)逐候GMS TBB资料,对华中地区夏季旱涝年的TBB候距平场进行了合成分析,研究了夏季青藏高原TBB的低频(10~20天和30~60天)振荡及其同华中地区旱涝的关系。结果表明,青藏高原东南部(27°~30°N,90°~100°E)是低频振荡最为活跃的地区,青藏高原东南部和华中地区TBB存在正相关关系,其相关程度涝年比旱年更为显著。对华中地区旱涝而言,青藏高原东南部的30~60天振荡比10~20天振荡敏感性要强。华中地区涝(旱)年,青藏高原东南部存在较强(弱)的低频(30~60天)TBB负值中心,其影响方式有的自西向东传播,有的同华中地区低频(30~60天)TBB同时加强或减弱。青藏高原低频(30~60天)TBB的负值位相有利于对流云团的生成和发展。 相似文献
875.
运用CSVD和联合CSVD等较新颖的统计方法,在去除/未去除ENSO影响的思路下,探讨了印度洋海温异常和南海夏季风建立迟早的关系,结果表明:在没有去除ENSO信号(外部作用)影响的情况下,全区一致型的海温异常分布对南海夏季风建立迟早起着重要的作用。当全区温度距平为正(负)时,南海夏季风建立较晚(早)。在去除了ENSO信号的影响后,非ENSO全区一致型和SIODM型是影响南海夏季风建立早晚的两个主要的印度洋海温分布型。对于非ENSO全区一致型的海温分布,当前期海温全区为负(正)距平时,南海夏季风建立较早(晚)。而对于SIODM型的海温分布,则当前期海温距平为西负东正(西正东负)的SIODM型时,南海夏季风建立较早(晚)。 相似文献
876.
江苏气温长期变化趋势及年代际变化空间差异分析 总被引:22,自引:1,他引:22
根据江苏省60个气象站1961-2001年的逐月气温资料,研究了江苏气温的长期变化趋势和年代际变化特征的空间差异。结果表明:1)近40a来江苏省年平均气温升高了约1℃,其中冬季3个月(12月一次年2月)升温最明显,夏季7、8月降温明显。各季节和年平均气温年代际变化具有一定的相似性,基本上是20世纪60年代有降低趋势,70年代到80年代前期趋势不明显,80年代后期和90年代气温快速升高,因此,年、春、秋、冬季最高温度出现在90年代。其中夏季气温在90年代后期又有所下降,夏季最高出现在60年代。2)长期变化趋势和年代际变化在空间上也有一定的差异,这种差异主要表现在温度变化幅度上,春、秋、冬和年平均气温在全省都是升高的,其中苏南和江苏北部的徐连地区春、冬季和年平均气温升高最明显,秋季苏南地区升温最明显;夏季大部分地区气温有下降趋势,其中东部沿海和西南部降温最明显,而北部部分地区则有弱的升温趋势。 相似文献
877.
Distribution and fractionation mechanism of stable carbon isotope of coalbed methane 总被引:1,自引:0,他引:1
The stable carbon isotope values of coalbed methane range widely, and also are gener- ally lighter than that of gases in normal coal-formed gas fields with similar coal rank. There exists strong carbon isotope fractionation in coalbed methane and it makes the carbon isotope value lighter. The correlation between the carbon isotope value and Ro in coalbed methane is less obvious. The coaly source rock maturity cannot be judged by coalbed methane carbon isotope value. The carbon isotopes of coalbed methane become lighter in much different degree due to the hydrodynamics. The stronger the hydrodynamics is, the lighter the CBM carbon isotopic value becomes. Many previous investigations indicated that the desorption-diffusion effects make the carbon isotope value of coalbed methane lighter. However, the explanation has encountered many problems. The authors of this arti- cle suggest that the flowing groundwater dissolution to free methane in coal seams and the free methane exchange with absorbed one is the carbon isotope fractionation mechanism in coalbed methane. The flowing groundwater in coal can easily take more 13CH4 away from free gas and com- paratively leave more 12CH4. This will make 12CH4 density in free gas comparatively higher than that in absorbed gas. The remaining 12CH4 in free gas then exchanges with the adsorbed methane in coal matrix. Some absorbed 13CH4 can be replaced and become free gas. Some free 12CH4 can be ab- sorbed again into coal matrix and become absorbed gas. Part of the newly replaced 13CH4 in free gas will also be taken away by water, leaving preferentially more 12CH4. The remaining 12CH4 in free gas will exchange again with adsorbed methane in the coal matrix. These processes occur all the time. Through accumulative effect, the 12CH4 will be greatly concentrated in coal. Thus, the stable carbon isotope of coalbed methane becomes dramatically lighter. Through simulation experiment on wa- ter-dissolved methane, it had been proved that the flowing water could fractionate the carbon isotope of methane, and easily take heavy carbon isotope away through dissolution. 相似文献
878.
V. Čermák J. Šafanda L. Bodri M. Yamano E. Gordeev 《Studia Geophysica et Geodaetica》2006,50(4):675-695
To reconstruct the recent climate history in Kamchatka, a series of repeated precise temperature logs were performed in a
number of boreholes located in a broad east-west strip (between 52 and 54°N) in the central part of Kamchatka west of Petropavlovsk-Kamchatski.
Within three years more than 30 temperature logs were performed in 10 holes (one up to six logs per hole) to the depth of
up to 400 metres. Measured temperature gradients varied in a broad interval 0 to 60 mK/m and in some holes a sizeable variation
in the subsurface temperatures due to advective heat transport by underground water was observed. Measured data were compared
with older temperature profiles obtained in the early eighties by Sugrobov and Yanovsky (1993). Even when older data are of
poorer precision (accuracy of about 0.1 K), they presented valuable information of the subsurface temperature conditions existing
20–25 years ago. Borehole observations and the inverted ground surface temperature histories (GSTHs) used for the paleoclimate
reconstruction were complemented with a detailed survey of meteorological data. Namely, the long-term surface air temperature
(SAT) and precipitation records from Petropavlovsk station (in operation since 1890) were used together with similar data
from a number of local subsidiary meteo-stations operating in Central Kamchatka since 1950. Regardless of extreme complexity
of the local meteorological/climate conditions, diversity of borehole sites and calibration of measuring devices used during
the whole campaign, the results of the climate reconstruction supported a general warming of about 1 K characteristic for
the 20th century, which followed an inexpressive cooler period typical for the most of the 19th century. In the last three
to four decades the warming rate has been locally increasing up to 0.02 K/year. It was also shown that the snow cover played
a dominant role in the penetration of the climate “signal” to depth and could considerably smooth down the subsurface response
to the changes occurred on the surface. 相似文献
879.
Expeditions to Muztagata (in the eastern Pamirs) during the summer seasons of 2002 and 2003 collected precipitation samples
and measured their oxygen isotopes. The δ
18O in precipitation displays a wide range, varying from −17.40‰ to +1.33‰ in June-September 2002 and from −22.31‰ to +4.59‰
in May-August 2003. The δ
18O in precipitation correlates with the initial temperature of precipitation during the observing periods. The positive correlation
between δ
18O and temperature suggests that δ
18O can be used as an indicator of temperature in this region. The δ
18O values in fresh-snow samples collected from two snow events at different elevations on the Muztagata Glacier show a strong
“altitude effect”, with a ratio of nearly −0.40% per 100 m from 5500 m to 7450 m. 相似文献
880.
This paper focuses on interpreting the different spatial relationships between NDVI and T
s, a triangular or a trapezoid, and on analyzing transformation conditions, the physical and ecological meanings of the vegetation
index-surface temperature space as well. Further, we use the Temperature-Vegetation Dryness Index (TVDI) to explain the existent
meaning of a triangular space after NDVI reaches its saturated state by employing the relationships between NDVI, LAI and
evapotranspiration. The specific relations between NDVI and T
s are useful for describing, validating and updating land surface models. 相似文献