排序方式: 共有13条查询结果,搜索用时 16 毫秒
1.
蒸散发是地表陆气水分交换的纽带,准确量化蒸散发的时空演变格局对于水资源规划与管理至关重要。本文基于GLEAM模型的蒸散发及其组分数据集,借助7个通量观测站数据、120个流域的流域水量平衡及PML_V2蒸散发产品,在中国九大流域系统评估了GLEAM-ET产品,分析了植被恢复背景下,蒸散发(ET)及其组分(植被蒸腾Ec,截留蒸发Ei,土壤蒸发Es)在1980—2020年的时空演变格局。本文主要得到以下结论:① GLEAM-ET产品在中国九大流域具有较好的适用性,其性能与气候类型有关,干旱区效果优于湿润区。此外,GLEAM与PML_V2模型在九大流域相关性较好(R>0.7),分布格局与变化趋势整体保持一致。② 全国尺度上,ET均值为416.88 mm,增长速率为1.21 mm/a。Ec与ET均呈自东南向西北递减的分布格局,而Es与其相反。Ec、ET在九大流域均呈显著增加趋势(p<0.001)。Ei、Es在季风区流域分别呈显著增加和显著减小趋势;在内陆区流域呈不显著减小(p>0.05)和显著增加趋势。③在植被恢复背景下,ET组分比例发生了变化。Ec占比变化存在南北差异,南方流域Ec占比均减小,北方流域均增加。Ei占比在各流域均增加,Es占比均减小。黄河流域ET组分对植被恢复的响应最为明显,Ec占比增加了5.21%,Es占比减小了5.56%。 相似文献
2.
蒸散发(ET)是水循环的关键变量之一,其长期变化直接影响区域水资源的时空分布格局。近几十年来,中国气候和下垫面特征发生了显著变化,但这些变化如何影响ET的时空分布仍缺乏清晰的认识。本文基于Penman-Monteith-Leuning模型和驱动要素去趋势实验定量揭示了降水、净辐射、水汽压差、风速和叶面积指数对中国陆地ET变化的贡献。研究结果表明,1982—2019年中国陆地ET呈显著增加(p <0.05)趋势,趋势值为1.25 mm a-1。水汽压差、降水和叶面积指数主导了中国陆地ET变化,三者对ET趋势的贡献度分别为44%(0.54 mm a-1)、29%(0.36 mm a-1)和25%(0.31 mm a-1)。ET变化的主导因素具有明显的区域分异规律,西北地区(干旱和半干旱区)ET变化受降水主导,长江大部以及东北北部(湿润区)受水汽压差主导,而黄土高原、华北平原和东北部分地区受叶面积指数主导。本文研究结果可为气候变化背景下中国水资源的差异化管理和规划提供参考。 相似文献
3.
4.
The coupled ocean–atmosphere–wave–sediment transport(COAWST) modeling system is employed to investigate the role of wave-mixing playing in the upwelling off the west coast of Hainan Island(WHU). Waves,tides and sea surface temperature(SST) are reproduced reasonably well by the model when validated by observations. Model results suggest the WHU is tidally driven. Further investigations indicate that inclusion of wave-mixing promotes the intensity of the WHU, making the simulated SST become more consistent with remote-sensed ones. Dynamically, wave-mixing facilitates the "outcrop" of more upwelled cold water, triggering stronger WHU and leading to a three-dimensional dynamical adjustment. From the perspective of time, wavemixing contributes to establishing an earlier tidal mixing front strong enough to generate WHU and that is, WHU may occur earlier when taking wave-mixing into consideration. 相似文献
5.
A synoptic-scale upwelling event that developed off the east coast of the Hainan Island(EHIU) in the summer of 2010 is defi ned well via processing the Moderate Resolution Imaging Spectroradiometer(MODIS) sea surface temperature(SST) data. The Regional Ocean Modeling System(ROMS) with high spatial resolution has been used to investigate this upwelling event. By comparing the ROMS results against tide station data, Argo fl oat profi les and MODIS SST, it is confi rmed that the ROMS reproduces the EHIU well. The cooler-water core(CWC) distinguished by waters(27) 27.5°C in the EHIU, which occurred in the east Qiongzhou Strait mouth area and was bounded by a high temperature gradient, was the focus of this paper. Vertical structure of the CWC suggests that interaction between the westward fl ow and the bathymetry slope played a signifi cant role in the formation of CWC. Numerical experiments indicated that the westward fl ow in the Qiongzhou Strait was the result of tidal rectifi cation over variable topography(Shi et al., 2002), thus tides played a critical role on the development of the CWC. The negative wind stress curl that dominated the east Qiongzhou Strait mouth area suppressed the intensity of the CWC by 0.2–0.4°C. Further, nonlinear interaction between tidal currents and wind stress enhanced vertical mixing greatly, which would benefi t the development of the CWC. 相似文献
6.
浪流相互作用对北部湾内波浪、冷水团及冲淡水的影响研究 总被引:1,自引:0,他引:1
Wave-current interaction and its effects on the hydrodynamic environment in the Beibu Gulf(BG) have been investigated via employing the Coupled Ocean–Atmosphere–Wave–Sediment Transport(COAWST) modeling system. The model could simulate reasonable hydrodynamics in the BG when validated by various observations.Vigorous tidal currents refract the waves efficiently and make the seas off the west coast of Hainan Island be the hot spot where currents modulate the significant wave height dramatically. During summer, wave-enhanced bottom stress could weaken the near-shore component of the gulf-scale cyclonic-circulation in the BG remarkably, inducing two major corresponding adjustments: Model results reveal that the deep-layer cold water from the southern BG makes critical contribution to maintaining the cold-water mass in the northern BG Basin.However, the weakened background circulation leads to less cold water transported from the southern gulf to the northern gulf, which finally triggers a 0.2°C warming in the cold-water mass area; In the top areas of the BG, the suppressed background circulation reduces the transport of the diluted water to the central gulf. Therefore, more freshwater could be trapped locally, which then triggers lower sea surface salinity(SSS) in the near-field and higher SSS in the far-field. 相似文献
7.
利用COAWST数值模式就琼州海峡内潮流场对冬季风浪场的影响进行了研究。经实测数据验证,模型可较好的刻画海峡内的强潮流场。选定东、西向最大潮流时刻为典型案例分别就水位场及潮流场对波浪场的作用展开探讨。在琼州海峡东口处,西向最大潮流时刻下的正水位场增加了承载波浪运动的有效水深,有利于波浪能量的西向传播,进而使得当地有效波高增加。东、西向最大潮流均有利于琼州海峡东口处有效波高的增大,但前者主要通过流致辐聚效应实现,而后者主要经由流致波数位移生效。通过流致折射作用,东向(西向)最大潮流可在海峡中轴线以北的海区引起谱峰波向的逆时针(顺时针)旋转,而在以南的海区触发顺时针(逆时针)旋转。 相似文献
8.
基于1993-2017年卫星高度计数据得到的中尺度涡追踪产品,分析了1000 m以深南海海盆中尺度涡移动速度C的时空分布特征。结果表明,南海海盆气候态平均的中尺度涡纬向移动速度cx均为西向,经向移动速度cy在海盆西北侧为南向,东南侧为北向。cy随经度的变化与背景经向流的变化一致,相关系数达0.96,而cx的变化与背景纬向流和β效应有关。cx和C存在明显季节变化,夏季最慢,冬季最快。年际变化上,cx和cy的大值多发生在太平洋年代际涛动(PDO)负位相期的La Nina年。中尺度涡在其生命周期的开始和结束阶段(即生成和耗散阶段)移速较快,而在稳定的“中期”阶段移动缓慢。该趋势与涡旋转速呈反相关,相关系数为-0.93。以移速小于1.5 cm/s和大于15.4 cm/s定义的极慢和极快涡旋,分别占总涡旋数量的1.5%和1.9%。移速极慢的涡多出现在海盆的中部,且主要发生在夏季;移速极快的涡多出现在海盆的边缘,且主要发生在冬季。机制分析显示,南海海盆中尺度涡移动速度的时空分布受到大尺度背景流场调制。 相似文献
9.
Tidal energy budget in the Zhujiang(Pearl River) Estuary(ZE) is evaluated by employing high-resolution baroclinic regional ocean modeling system(ROMS). The results obtained via applying the least square method on the model elevations are compared against the tidal harmonic constants at 18 tide stations along the ZE and its adjacent coast. The mean absolute errors between the simulation and the observation of M_2, S_2, K_1 and O_1 are 4.6, 2.8, 3.2 and 2.8 cm in amplitudes and 9.8°, 15.0°, 4.6° and 4.6° in phase-lags, respectively. The comparisons between the simulated and observed sea level heights at 11 tide gauge stations also suggest good model performance. The total tidal energy flux incoming the ZE is estimated to be 343.49 MW in the dry season and larger than 336.18 MW in the wet season, which should due to higher mean sea level height and heavier density in the dry season. M_2, K_1, S_2, O_1 and N_2, the top five barotropic tidal energy flux contributors for the ZE,import 242.23(236.79), 52.97(52.08), 24.49(23.96), 16.22(15.91) and 7.10(6.97) MW energy flux into the ZE in dry(wet) season, successively and respectively. The enhanced turbulent mixing induced by eddies around isolated islands and sharp headlands dominated by bottom friction, interaction between tidal currents and sill topography or constricted narrow waterways together account for the five energy dissipation hotspots, which add up to about 38% of the total energy dissipation inside the ZE. 相似文献
10.