共查询到16条相似文献,搜索用时 140 毫秒
1.
利用2010年6-7月鄂陵湖野外试验的近地层观测数据,分析了在不同天气条件下黄河源鄂陵湖地区辐射分量、地表能量分量、土壤温度和反照率的变化特征. 结果表明:不同天气条件下,辐射和地表能量各分量日变化差异较大,晴天、阴天和雨天的地表反照率依次递减,平均反照率约为0.21;观测期内,平均辐射贡献从大到小依次为向上长波、向下长波、向下短波、向上短波,日积分值分别为31.4 MJ·m-2、25.6 MJ·m-2、22.4 MJ·m-2、4.2 MJ·m-2,净辐射(12.5 MJ·m-2)占向下短波辐射的55.7%;平均地表能量和土壤温度的变化幅度较晴天小,感热、潜热、0 cm土壤热通量的平均日积分值分别占净辐射的21.2%、43.1%、8.2%;平均土壤温度变化幅度随深度增加逐渐减小,浅层土壤温度峰值较晴天低2 ℃,深层土壤温度相差不大. 云和降水的扰动削弱了向下短波辐射,导致平均感热通量和0 cm土壤热通量的峰值比晴天小,而平均潜热通量的峰值大于晴天. 由于湖泊水体巨大的热容量和水分供应,鄂陵湖地区的气温日较差较小,地表温度变化幅度变小,附近地表温度升高缓慢. 鄂陵湖区的地表能量平衡中,潜热通量占主导,感热和地表土壤热通量次之. 研究结果有助于理解气候变化背景下黄河源区湖泊的能量水分循环过程,为促进该地区光热资源的合理利用和畜牧业的可持续发展提供数据支持. 相似文献
2.
基于CLM模式的青藏高原土壤冻融过程陆面特征研究 总被引:3,自引:3,他引:0
使用位于青藏高原东部若尔盖站的观测数据驱动CLM3.5模式,设计一组去除模式中冻融过程的"退化试验",进行为期一年的模拟研究。通过对比原试验与敏感性试验模拟结果,初步分析冻融过程在土壤温度变化、各能量通量分配中的作用,得到以下结论:(1)冻融过程是土壤温度变化的"缓冲器",冻结过程向周围环境释放能量减缓了土壤降温的速率,使土壤温度不至降得太低,而消融过程从周围环境吸收能量减缓了土壤升温的速率,使土壤温度不至升高太多;(2)冻融过程改变了地表辐射通量,土壤冻结改变了地表反照率,改变了向上短波辐射,且由于冻结过程减缓了地表温度的下降,改变了地表向上长波辐射,进而改变了净辐射通量;(3)冻融过程显著地改变了陆面能量的分配,通过相变能量的释放和吸收增大了地气间能量的传输,显著地增大了地表土壤热通量,且通过改变地表温度和地表蒸发,改变了感热及潜热通量。在冻结过程及完全冻结阶段,感热及潜热通量均增大,但在消融过程阶段,感热及潜热通量均减小。冻融过程对土壤热通量及感热通量的影响在冻结过程及完全冻结阶段更为显著,而对潜热的影响则是在消融过程阶段更为显著。 相似文献
3.
夏季草原与戈壁地表能量分析 总被引:1,自引:0,他引:1
利用野外试验资料,比较分析了夏季祁连山区草原和河西走廊张掖戈壁地表能量特征,并探讨了环境因素与地表能量特征的关系。结果表明,在夏季典型晴天,山区草原的净辐射、潜热通量大于戈壁,而感热、土壤热通量小于戈壁;山区草原净辐射、潜热通量的日变化大于戈壁;而感热、土壤热通量的日变化小于戈壁。在山区草原,晴天潜热通量是土壤热通量的三倍多,感热通量与土壤热通量差异很小,净辐射主要用于蒸发、蒸腾;在戈壁,晴天土壤热通量和感热通量是潜热通量的近两倍,净辐射主要用于加热地表,并通过地表加热下层土壤和地面大气。两地均存在能量不平衡现象,草原感热、潜热、土壤热通量之和小于净辐射,戈壁感热、潜热、土壤热通量之和大于净辐射,戈壁能量不平衡大于草原。导致山区草原和戈壁地表净辐射特征差异的主要因素是太阳辐射,导致山区草原和戈壁地表能量分量特征差异的主要因素是陆面植被和水分,根本因素是陆面水分。
相似文献
4.
青藏高原唐古拉多年冻土区冻融循环过程中的能量平衡特征 总被引:1,自引:1,他引:0
青藏高原多年冻土区冻融循环过程对地表能量及其分配的影响研究相对较少,青藏高原唐古拉站多年冻土的实测资料,依据10 cm土壤温度划分浅层土壤冻融循环的各个阶段并结合能量闭合率、地表能量各通量等数据探讨浅层土壤冻融循环过程与地气间水热交换过程之间的影响。结果表明:浅层土壤冻融循环过程各阶段均受气候变化的影响,其融化过程起始时间提前同时冻结过程起始时间推后,完全融化阶段持续时间增加,且逐渐接近完全冻结阶段持续时间;在浅层土壤不同冻融状态下,能量闭合率差值较大,其中完全融化阶段能量闭合状况普遍好于完全冻结阶段;净辐射值在完全融化阶段高于完全冻结阶段,净辐射在完全冻结阶段主要转化为感热通量,在完全融化阶段主要转化为潜热通量,地表土壤热通量在完全融化阶段为正值,在完全冻结阶段为负值。 相似文献
5.
基于能量平衡对额尔齐斯河流域融雪过程的研究 总被引:5,自引:5,他引:0
为定量描述额尔齐斯河流域积雪的消融过程,建立了利用基于能量平衡的积雪模型,对流域内库威积雪站2014年1月4日-3月28日积雪的积累和消融过程进行了模拟.结果表明:模型能够很好的模拟出融雪期净辐射能量的变化过程,对雪水当量的模拟结果也非常好,雪水当量的观测值和模拟值之间的Nash系数达到了0.989.在积雪的积累期,雪表的净辐射、感热、潜热通量的绝对值以及地表热通量明显低于积雪的消融期.在积累期,感热和潜热通量以及土壤热通量受到雪层厚度的影响.当雪水当量小于10 mm时,感热和潜热通量的绝对值偏高,土壤热通量的波动性也偏大.在积累期积雪的物质损失全部为升华损失,升华量为2.74 mm;在消融期,积雪的融化量为66.26 mm,升华量为2.04 mm.净辐射对积雪物质损失的贡献达到了83.1%,湍流通量对积雪物质损失的贡献达到16.9%.由于在融化期土壤热通量为正值,因此土壤热通量对融雪没有贡献. 相似文献
6.
基于2005—2016年青藏高原多年冻土区唐古拉和西大滩站的气象、涡动通量以及活动层资料,利用涡动相关法、气象梯度法和SHAW模型等方法探究了气候变化背景下高原多年冻土区地表能量通量变化规律及其对活动层的影响。结果表明:2005—2016年唐古拉和西大滩气温、地气温差有所升高,年降水量、10 cm土壤含水量及风速有所下降。2005年以来唐古拉和西大滩净辐射(Rn )与感热(H)呈增加趋势,潜热(LE)呈减小趋势,地表土壤热通量(G)变化较小。唐古拉和西大滩地表能量通量季节变化明显,但受海拔、纬度、坡向、土壤冻融过程、降水、下垫面状况等因素的影响,地表能量通量存在区域差异。研究时段内,唐古拉和西大滩地表冻结指数与土壤热通量呈负相关;融化指数、活动层厚度与土壤热通量呈正相关,融化期间土壤热通量积累量与融化深度的变化呈线性增加关系。 相似文献
7.
2009/2010年黄河源区高寒草甸下垫面能量平衡特征分析 总被引:1,自引:1,他引:0
以青藏高原黄河源玛多为实验区, 基于TRM-ZS1气象生态环境监测仪2009年11月1日至2010年10月31日辐射及能量通量观测数据, 采用波文比能量平衡法, 进行了该区域潜热和感热通量的估算, 分析了黄河源区高寒草甸下垫面辐射收支, 潜热、 感热和土壤热通量在不同季节的分配, 对该区域冬季地面加热场强度的变化进行了研究.结果表明: 该区域总辐射、 净辐射较强, 总辐射平均日积分值为18.06 MJ·m-2·d-1, 净辐射平均日积分值5.95 MJ·m-2·d-1, 曾观测到高达979.5 W·m-2的净辐射通量.全年地表平均反射率为0.30, 接近于荒漠和半荒漠下垫面的反射率.植物生长季土壤湿度和冬、 春季地面积雪是影响该区域地表反射率的两个最主要因素.该区域感热通量年积分值为742.68 MJ·m-2·a-1, 潜热通量年积分值为1 388.58 MJ·m2·a-1, 全年中地表以潜热方式传递热量为主.分季节分析, 冬季感热潜热强度相当, 春季以感热为主, 夏秋季则以潜热为主.土壤热通量年积分值为38.06 MJ·m-2·a-1, 全年热通量在热量平衡中约占1.8%, 但季节分配不平衡, 在冬季, 有|G|>H+LE, 土壤热通量是热平衡最大的分量.该区域地表全年向大气释放热量, 地表对大气而言是热源. 相似文献
8.
黑河下游绿洲地表辐射平衡及小气候特征分析 总被引:1,自引:0,他引:1
利用额济纳绿洲2004年5~10月微气象站观测资料,分析了该地区地表能量平衡及小气候特征.结果表明:在绿洲内太阳总辐射、光合有效辐射、净辐射有明显的季节变化及日变化,日峰值及月总量在7月份达到最高.地表能量平衡季节变化显著,5、8、9、10月份,地面能量交换基本以感热通量为主,Bowen比值在日间>4;6、7月份,潜热蒸发是能量平衡的主要部分,Bowen比基本<1.5~10月土壤热通量值始终较小,约占净辐射的15%~20%.绿洲内近地层风速基本在0~5 m·s-1之间,夜间风速变化很小,日间风速较大.随着土壤深度的增加,土壤温度变化趋势越来越缓慢,地表温度波动变化最大,而在40 cm深处土壤温度日变化很小. 相似文献
9.
10.
《岩土力学》2020,(5)
为明确气候湿化背景下多年冻土活动层对降雨的水热响应机制,探讨了考虑降雨作用的不同土质地表能水平衡差异和活动层水热过程。基于土壤–地表–大气能量平衡的冻土水–汽–热耦合模型,以青藏高原北麓河地区2013年实测气象资料为模型驱动数据,定量分析了高原真实野外降雨条件下3种典型地表土质(砂土、亚砂土、粉质黏土)地表水分和能量平衡差异、活动层内部水分与能量输运分量变化过程和耦合机制。结果表明:随着土壤粒径增大,地表净辐射增大、蒸发潜热增大、感热通量减少、土壤热通量减小,不同土质地表蒸发潜热和地表感热通量差异最为显著,地表能量平衡差异在暖季较大、冷季较小;土壤粒径越大,水势梯度液态水和温度梯度水汽迁移越显著,但温度梯度水汽通量减小、水势梯度液态水通量增大;随着土壤粒径增大,土壤浅表层水分减少,25~75 cm水分略有增加;随着土壤粒径增大,土壤导热系数、降雨入渗对流传热和地表蒸发量增大、热传导通量减小,土体温度梯度降低,相同深度处土壤温度更高,活动层厚度增大,不利于多年冻土稳定。研究成果可为湿化背景下多年冻土的稳定性预测和保护提供参考。 相似文献
11.
黑河中游间作灌溉农田的能量平衡 总被引:2,自引:0,他引:2
利用布设在黑河流域中游的张掖绿洲区的一套自动气象观测系统在2004年作物生长期内的完整资料,分析了黑河中游春小麦和玉米间作农田生态系统的辐射收支,在此基础上选用波文比能量平衡法(BREB)进行了能量平衡计算.结果表明:间作作物-土壤系统截获的太阳短波辐射占太阳总辐射的比例从生长初期的0.81持续增加到生长末期的0.86;净辐射在生长初期较小,生长中期第一阶段增幅大,至第二阶段达到最大,生长末期降低;净辐射占太阳总辐射的比例与净辐射的变化相似.能量平衡中,净辐射的消耗以潜热为主,占70%左右,感热能量占20%,土壤热通量占净辐射总值的10%.不同生长阶段的能量平衡差异较大,能量平衡在不同生长阶段呈现出不同的日变化特征. 相似文献
12.
青藏高原林芝与四川盆地温江地区晴天辐射和能量平衡特征 总被引:2,自引:0,他引:2
分析了2008年青藏高原林芝地区与四川盆地温江地区无降水条件下地表辐射、 湍流通量和地表反照率的日变化及月际变化特征, 并探讨了季风过程对其产生的影响.结果表明: 林芝与温江地区地表辐射和湍流通量都具有明显的日变化和月际变化周期, 季风期受云的影响, 日循环规律变得不是非常规则.季风对林芝地区地表能量分配影响极大, 季风前感热通量占主导地位, 季风期和季风后(夏、 秋节)潜热通量是净辐射的主要消耗项; 温江地区全年潜热在净辐射的分布中占主导地位, 感热通量的作用和土壤热通量相当. 林芝地区年平均地表反照率为0.21, 温江地区年平均仅为0.14; 季风前(3-5月)、 季风中(6-7月)和季风后(8-9月), 林芝地区的地表反照率分别为0.20、 0.19和0.20, 温江地区的地表反照率分别为0.13、 0.11和0.14. 相似文献
13.
Zhen-chao Li Zhi-gang Wei Shi-hua Lv Wen-jie Dong Yan-hong Gao Hong Wei Zhi-yuan Zheng 《Environmental Earth Sciences》2014,72(4):1155-1166
Complex interactions between the land surface and atmosphere and the exchange of water and energy have a significant impact on climate. The Tibetan Plateau is the highest plateau in the world and is known as “Earth’s third pole”. Because of its unique natural geographical and climatic characteristics, it directly affects China’s climate, as well as the world’s climate, through its thermal and dynamic roles. In this study, the BCCCSM1.1 model for the simulation results of CMIP5 is used to analyze the variation of the land surface processes of the Tibetan Plateau and the possible linkages with temperature change. The analysis showed that, from 1850 to 2005, as temperature increases, the model shows surface downward short-wave radiation, upward short-wave radiation, and net radiation to decrease, and long-wave radiation to increase. Meanwhile, latent heat flux increases, whereas sensible heat flux decreases. Except for sensible heat flux, the correlation coefficients of land surface fluxes with surface air temperature are all significant at the 99 % significance level. The model results indicate rising temperature to cause the ablation of ice (or snow) cover and increasing leaf area index, with reduced snowfall, together with a series of other changes, resulting in increasing upward and downward long-wave radiation and changes in soil moisture, evaporation, latent heat flux, and water vapor in the air. However, rising temperature also reduces the difference between the surface and air temperature and the surface albedo, which lead to further reductions of downward and upward short-wave radiation. The surface air temperature in winter increases by 0.93 °C/100 years, whereas the change is at a minimum (0.66 °C/100 years) during the summer. Downward short-wave and net radiation demonstrate the largest decline in the summer, whereas upward short-wave radiation demonstrates its largest decline during the spring. Downward short-wave radiation is predominantly affected by air humidity, followed by the impact of total cloud fraction. The average downward short-wave and net radiation attain their maxima in May, whereas for upward short-wave radiation the maximum is in March. The model predicts surface temperature to increase under all the different representative concentration pathway (RCP) scenarios, with the rise under RCP8.5 reaching 5.1 °C/100 years. Long-wave radiation increases under the different emission scenarios, while downward short-wave radiation increases under the low- and medium-emission concentration pathways, but decreases under RCP8.5. Upward short-wave radiation reduces under the various emission scenarios, and the marginal growth decreases as the emission concentration increases. 相似文献
14.
The relationship between sensible and latent heat flux and diurnal variation in soil surface temperature and moisture under
four freeze/thaw soil conditions was investigated using observed soil temperature and moisture and simulated sensible and
latent heat flux. The diurnal range of latent heat flux had a similar temporal change pattern as that of unfrozen soil water
at depths of 0–3 cm during the freezing stage. Also, there was a better relationship with the diurnal range of unfrozen soil
water at depths of 3–6 cm during the thawing stage. Diurnal variation in latent heat flux was significant and depended mostly
on solar radiation during the completely thawed stage. However, while diurnal variation in solar radiation during the completely
frozen stage was significant, for latent heat flux it was quite weak due to low unfrozen soil water content. Thus, diurnal
variation in latent heat flux depended mostly on unfrozen soil water content during this stage. During the freezing and thawing
stages, diurnal variation in latent heat flux was also significant and depended mostly on diurnal variation in unfrozen soil
water content. However, the impacts of air temperature change from solar radiation on latent heat flux could not be ignored. 相似文献
15.
科奇喀尔冰川夏季表碛区热量平衡参数的估算分析 总被引:8,自引:8,他引:0
利用能量平衡原理、热传导理论和通量传输理论建立了一个热量平衡参数的估算模型,对西天山的科奇喀尔冰川夏季消融区中部表碛区的热量平衡参数进行估算与分析.结果表明:净辐射是表碛面热量收支的主要热源,吸收的热量主要以潜热和感热的形式向大气输送水汽和热量,剩余部分用于表碛增温耗热.与消融区上部的冰面和表碛面相比,在消融区中部表碛面热量收入中感热输送减小,同时向上的地热输送增加.热平衡支出项中,感热交换、蒸发耗热和地热通量的比例分别为39.1%、39.9%和21%,其中感热通量与蒸发耗热的比例比消融区上部有所提高,蒸发耗热的增加比较显著.在总的热量支出中,平均只有7.8%的热量可以用于表碛下部的增温和向深层传导. 相似文献
16.
ZHANG Ming-li WEN Zhi DONG Jian-hua WANG De-kai YUE Guo-dong WANG Bin GAO Qiang 《岩土力学》2020,41(5):1549-1559
In order to understand the hydrothermal activity mechanism of active layers to rainfall in permafrost regions caused by humidification of climate, the differences of ground surface energy balance and hydrothermal activity in different types of shallow soil with the consideration of rainfall were discussed. Based on the meteorological data in 2013 observed at Beiluhe observation station of Tibet Plateau, three types of shallow ground soil (i.e., sandy soil, sandy loam and silty clay) were selected to compare the differences in the water content and energy balance at the ground surface, dynamic processes of water and energy transport in active layers and coupling mechanism under rainfall condition in the plateau using a coupled water-vapor-heat transport model. The results show that the increase of soil particle size leads to the increase of surface net radiation and latent heat of evaporation, but the decrease of soil heat flux. The difference of surface energy balance, especially the sensible heat flux and latent heat of evaporation, are larger in the warm season but smaller in the cold season. The liquid water transport under hydraulic gradient and the water-vapor transport under thermal gradient are obvious as the particle size in soil increases. However, the water-vapor flux under thermal gradient increases but the liquid water flux under hydraulic potential gradient decreases. As a result, the water content in shallow soil decreases accordingly but it increases slightly at the depth of 25 ~75 cm. Moreover, with the increase of soil particle size, the thermal conductivity of soil, convective heat transfer under rainfall and surface evaporation increase, but the soil heat conduction flux and soil temperature gradient decrease. Thus, soil temperature in sandy soil is much higher than that of sandy loam and silty clay at the same depth. The permafrost table declines with the increase of the thickness of active layer, which is unfavourable to permafrost stability. The results can provide theoretical reference for stability prediction and protection of permafrost caused by humidification of climate. 相似文献