共查询到18条相似文献,搜索用时 375 毫秒
1.
珠江口近15年海平面变化特点及其与强咸潮发生的关系 总被引:1,自引:1,他引:0
通过对珠江口30多年相对海平面和近15年绝对海平面变化的研究,比较1992年12月~2008年12月南海卫星观测和珠江口验潮站观测的海平面变化趋势,认为珠江口的相对海平面(RSL)上升最主要原因是全球气候变暖、海平面上升所致;通过研究29个冬季各月西、北江冬季径流量、海平面、表层盐度的变化趋势,以及强咸潮月份的径流、海平面、盐度的对应关系,得出海平面上升是加大咸潮影响的重要因素。 相似文献
2.
3.
长江口海平面上升预测及其对滨海湿地影响 总被引:1,自引:0,他引:1
选择吴淞站和吕四站2个验潮站数据,通过统计学方法进行长江口海平面上升预测,从而构建了一套长江口地区较完备的海平面上升情景库:以2013年为基准年份,其最佳预测值的范围在2030年、2050年、2100年分别为50~217 mm,118~430 mm,256~1215 mm。以此情景库为基础,探究海平面上升变化对长江口滨海湿地的影响,结果表明:随着海平面上升值的增加,长江口滨海湿地的面积不断减少;在基于验潮站数据作趋势外推得到的情景下,湿地面积减少较平缓,而在考虑全球变暖背景的情景下,湿地面积减少迅速;且不论在何种情景下,时间尺度越大,湿地减少的面积越大。 相似文献
4.
对长江口海平面上升动态及其对沿海潮汐特性的影响进行了简析。结合长江口崇明三岛地区除涝安全面临海平面上升的影响和威胁,分别建立了基于海平面上升的上海市崇明三岛水系一维平原感潮河网水动力模型,深入开展了海平面上升对三岛地区除涝安全影响的模拟研究。结果显示,至2030年,长江口海平面上升10~16 cm,崇明三岛片区的面平均除涝最高水位、局部除涝最高水位均呈上升趋势,其中,崇明岛片受影响最大,对应水位将分别上升3~5 cm、4~6 cm;长兴岛片受影响次之,对应水位将分别上升3~4 cm、3~5 cm;横沙岛片受影响相对最小,对应水位均将上升1~2 cm;长江口海平面上升对崇明三岛的除涝安全影响在可控范围内。 相似文献
5.
低径流量条件下海平面上升对长江口淡水资源的影响 总被引:3,自引:0,他引:3
基于长江口水动力及盐水入侵三维数值模式ECOM-si,统筹考虑气候变化导致流域极端低径流量的前提下,研究在未来(2030、2050和2100年)海平面上升过程中,长江口淡水资源分布及总量变化过程,探讨河口三大重要水库取水活动对海平面上升的响应,对防范未来可能出现的盐水入侵危害具有重要作用,也为长江口水源地建设与水库取水调度提供理论依据和技术支持。1999年冬季、2006年秋季和2011年春季期间长江径流量均为自1980年以来的同期最低,且长江口均发生了极为严重、影响巨大的盐水入侵,考虑到径流量的季节变化特点,选取上述3个时期的径流量作为上游边界条件。结果表明,长江口淡水资源在1999年冬季径流量条件下随海平面上升而减少,至2100年大、小潮期间淡水总量相比于2012年分别减少42%和41%,水库最长不宜取水天数增加70%以上;在2006年秋季径流量条件下,淡水资源随海平面上升而减少,但在海平面上升至2050年情况下,河道水位抬升使进入北支的径流量增加,削弱盐水倒灌,水库最长不宜取水天数减少40%~50%;在2011年春季径流量条件下,淡水资源在海平面上升至2100年后大、小潮期间分别减少43%和20%,水库最长不宜取水天数增加1~3 d。 相似文献
6.
7.
分析和甄别上海市需水系统和长江口水源地供水系统风险因子,建立基于水资源供需平衡的上海市水源地供水安全风险评估模型,并采用系统动力学预测模型和高分辨率非正交曲线网格移动潮滩边界的长江河口盐水入侵三维数值模型,分别计算分析2030年人口增长、径流减少和海平面上升等3种风险因子叠加作用下的上海市需水量与长江口陈行、东风西沙和青草沙3个水源地的可供原水量,并进行供需比较分析和供水安全风险评估。结果表明:在海平面分别上升10和25 cm、枯季平均径流和没有新增水源条件下,2020年的缺水量分别为39万和74万m3/d,特枯水文年供水能力降低19万m3/d;若新增没冒沙水源300万m3/d,可缓解上海市2020年的缺水状况。 相似文献
8.
9.
本文将海平面上升作为上海地面沉降防治策略研究的一个考虑因素,主要通过分析对比黄浦江外滩防汛墙沉降监测结果与工程沿线区域地面沉降监测结果,以及海平面上升对防汛墙防御能力的影响,得到区域地面沉降对防汛墙沉降作用明显、地面沉降叠加了海平面上升因素将进一步降低城市防洪(潮)排涝能力。在此基础上,提出了考虑海平面上升因素下的未来地面沉降防治策略,包括重大市政工程地面沉降监测预警机制建设、实施地面沉降分区管控、加强地下水资源开发利用管理、建立完善地面沉降监测网络等。 相似文献
10.
气候变暖背景下,海平面上升已经成为全球沿海国家普遍面临的重大环境问题之一 [1].全球海平面上升是由气候变暖导致的海水增温膨胀、陆源冰川和极地冰盖融化等因素造成的.1901—2018年,海洋增温膨胀对全球海平面上升的贡献为29%;冰川和冰盖质量损失对全球海平面上升的贡献分别为41%和29%,且近40年来已经增加 [2]... 相似文献
11.
Modelling the combined impacts of sea-level rise and land subsidence on storm tides induced flooding of the Huangpu River in Shanghai, China 总被引:3,自引:0,他引:3
This paper presents a scenario-based study that investigates the interaction between sea-level rise and land subsidence on the storm tides induced fluvial flooding in the Huangpu river floodplain. Two projections of relative sea level rise (RSLR) were presented (2030 and 2050). Water level projections at the gauging stations for different return periods were generated using a simplified algebraic summation of the eustatic sea-level rise, land subsidence and storm tide level. Frequency analysis with relative sea level rise taken into account shows that land subsidence contributes to the majority of the RSLR (between 60 % and 70 %). Furthermore, a 1D/2D coupled flood inundation model (FloodMap) was used to predict the river flow and flood inundation, after calibration using the August 1997 flood event. Numerical simulation with projected RSLR suggests that, the combined impact of eustatic sea-level rise and land subsidence would be a significantly reduced flood return period for a given water level, thus effective degradation of the current flood defences. In the absence of adaptation measures, storm flooding will cause up to 40 % more inundation, particularly in the upstream of the river. 相似文献
12.
Relative sea level rise (RSLR) due to climate change and geodynamics represents the main threat for the survival of Venice,
emerging today only 90 cm above the Northern Adriatic mean sea level (msl). The 25 cm RSLR occurred over the 20th century,
consisting of about 12 cm of land subsidence and 13 cm of sea level rise, has increased the flood frequency by more than seven
times with severe damages to the urban heritage. Reasonable forecasts of the RSLR expected to the century end must be investigated
to assess the suitability of the Mo.S.E. project planned for the city safeguarding, i.e., the closure of the lagoon inlets
by mobile barriers. Here we consider three RSLR scenarios as resulting from the past sea level rise recorded in the Northern
Adriatic Sea, the IPCC mid-range A1B scenario, and the expected land subsidence. Available sea level measurements show that
more than 5 decades are required to compute a meaningful eustatic trend, due to pseudo-cyclic 7–8 year long fluctuations.
The period from 1890 to 2007 is characterized by an average rate of 0.12 ± 0.01 cm/year. We demonstrate that linear regression
is the most suitable model to represent the eustatic process over these 117 year. Concerning subsidence, at present Venice
is sinking due to natural causes at 0.05 cm/year. The RSLR is expected to range between 17 and 53 cm by 2100, and its repercussions
in terms of flooding frequency are associated here to each scenario. In particular, the frequency of tides higher than 110 cm,
i.e., the value above which the gates would close the lagoon to the sea, will increase from the nowadays 4 times per year
to a range between 20 and 250. These projections provide a large spread of possible conditions concerning the survival of
Venice, from a moderate nuisance to an intolerable aggression. Hence, complementary solutions to Mo.S.E. may well be investigated. 相似文献
13.
Robert W. Stewart 《大气与海洋》2013,51(3):461-477
Abstract Relative sea‐level rise along the Atlantic coast of North America is observed to be about 30 cm/century. No more than half of this rise can be explained by eustatic changes. It is improbable that the remainder is explicable by steric changes. It is therefore almost certainly produced by a systematic subsidence of that coast. The required rate of at least 15 cm/ century is very large by long‐term geologic standards. However, it is comparable with rates measured in relevelling programs, and we must recognize that we live in extraordinary times geologically in that ice‐ages are unusual, and we are in a very warm portion of the present ice‐age. If at least half of the observed relative sea‐level rise is caused by subsidence, it seems reasonable to suppose that nearly all, except for the effects of the observed melting of small glaciers, is so caused. Sea‐level rise is so variable in other parts of the world that there also it is better explained by crustal movements than by eustatic sea‐level rise. The doubt that these considerations place on the usual interpretation of past sea‐level rise extends to consideration of a possible future rise brought ori by climate change. It is uncertainty that has clearly increased, not eustatic sea‐level. 相似文献
14.
Evaluation of the combined risk of sea level rise, land subsidence, and storm surges on the coastal areas of Shanghai, China 总被引:10,自引:0,他引:10
Shanghai is a low-lying city (3–4?m elevation) surrounded on three sides by the East China Sea, the Yangtze River Estuary, and Hangzhou Bay. With a history of rapid changes in sea level and land subsidence, Shanghai is often plagued by extreme typhoon storm surges. The interaction of sea level rise, land subsidence, and storm surges may lead to more complex, variable, and abrupt disasters. In this paper, we used MIKE 21 models to simulate the combined effect of this disaster chain in Shanghai. Projections indicate that the sea level will rise 86.6?mm, 185.6?mm, and 433.1?mm by 2030, 2050, and 2100, respectively. Anthropogenic subsidence is a serious problem. The maximum annual subsidence rate is 24.12?mm/year. By 2100, half of Shanghai is projected to be flooded, and 46?% of the seawalls and levees are projected to be overtopped. The risk of flooding is closely related to the impact of land subsidence on the height of existing seawalls and levees. Land subsidence increases the need for flood control measures in Shanghai. 相似文献
15.
Against a background of climate change, Macau is very exposed to sea level rise(SLR) because of its low elevation,small size, and ongoing land reclamation. Therefore, we evaluate sea level changes in Macau, both historical and, especially,possible future scenarios, aiming to provide knowledge and a framework to help accommodate and protect against future SLR. Sea level in Macau is now rising at an accelerated rate: 1.35 mm yr-1over 1925–2010 and jumping to 4.2 mm yr-1over 1970–2010, which outpaces the rise in global mean sea level. In addition, vertical land movement in Macau contributes little to local sea level change. In the future, the rate of SLR in Macau will be about 20% higher than the global average, as a consequence of a greater local warming tendency and strengthened northward winds. Specifically, the sea level is projected to rise 8–12, 22–51 and 35–118 cm by 2020, 2060 and 2100, respectively, depending on the emissions scenario and climate sensitivity. Under the +8.5 W m-2Representative Concentration Pathway(RCP8.5) scenario the increase in sea level by2100 will reach 65–118 cm—double that under RCP2.6. Moreover, the SLR will accelerate under RCP6.0 and RCP8.5, while remaining at a moderate and steady rate under RCP4.5 and RCP2.6. The key source of uncertainty stems from the emissions scenario and climate sensitivity, among which the discrepancies in SLR are small during the first half of the 21 st century but begin to diverge thereafter. 相似文献
16.
IPCC第六次评估报告第一工作组报告第九章综合评估了与海平面相关的最新监测和数值模拟结果,指出目前(2006—2018年)的海平面上升速率处于加速状态(3.7 mm/a),并会在未来持续上升,且呈现不可逆的趋势。其中低排放情景(SSP1-1.9)和高排放情景(SSP5-8.5)下,到2050年,预估全球平均海平面(GMSL)分别上升0.15~0.23 m和0.20~0.30 m;到2100年,预估GMSL分别上升0.28~0.55 m和0.63~1.02 m。南极冰盖不稳定性是影响未来海平面上升预估的最大不确定性来源之一。区域海平面变化是影响沿海极端静水位的重要因素。 相似文献
17.
AbstractTrends in regional mean sea levels can be substantially different from the global mean trend. Here, we first use tide-gauge data and satellite altimetry measurements to examine trends in mean relative sea level (MRSL) for the coasts of Canada over approximately the past 50–100 years. We then combine model output and satellite observations to provide sea level projections for the twenty-first century. The MRSL trend based on historical tide-gauge data shows large regional variations, from 3?mm?y?1 (higher than the global mean MRSL rise rate of 1.7?mm?y?1 for 1900–2009) along the southeast Atlantic coast, close to or below the global mean along the Pacific and Arctic coasts, to –9?mm?y?1 in Hudson Bay, as indicated by the vertical land motion. The combination of altimeter-measured sea level change with Global Positioning System (GPS) data approximately accounts for tide-gauge measurements at most stations for the 1993–2011 period. The projected MRSL change between 1980 and 1999 and between 2090 and 2099 under a medium-high climate change emission scenario (A2) ranges from ?50?cm in northeastern Canada to 75?cm in southeastern Canada. Along the coast of the Beaufort Sea, the MRSL rise is as high as 70?cm. The MRSL change along the Pacific coast varies from ?15 to 50?cm. The ocean steric and dynamical effects contribute to the rise in MRSL along Canadian coasts and are dominant on the southeast coast. Land-ice (glaciers and ice sheets) melt contributes 10–20?cm to the rise in MRSL, except in northeastern Canada. The effect of the vertical land uplift is large and centred near Hudson Bay, significantly reducing the rise in MRSL. The land-ice melt also causes a decrease in MRSL in northeastern Canada. The projected MRSL change under a high emission scenario (Representative Concentration Pathway 8.5) has a spatial pattern similar to that under A2, with a slightly greater rise in MRSL of 7?cm, on average, and some notable differences at specific sites. 相似文献
18.
In the northern Bay of Bengal, mechanisms of seasonal sea-level variation have not previously been examined, and the understanding of longer-term inter-annual sea-level variation is also not concrete. These parameters are addressed in this study utilizing available tide gauge and satellite altimetry data. The contribution of steric sea level to seasonal and longer-term inter-annual sea-level variations is quantified, and statistical analysis is performed to determine the correlations of various atmospheric and oceanic factors with sea level. This study suggests that the trend of sea-level rise in this bay (4 ± 1.33 mm/year) is higher than the global average (3.32 ± 0.46 mm/year) for the studied period 1993 to 2018. The rate of sea-level rise is higher along the coast than in the offshore area and the highest in the central part of the coast. Sea level shows a strong seasonal variation: sea level is the lowest in the winter but the highest in autumn. The contribution from the thermosteric sea level is higher to the observed sea level from winter to early summer, whereas contributions from the halosteric sea level and wind stress curl are higher during autumn. Long-term variations in sea level show strong positive correlations with thermosteric sea level, indicating that temperature is a major local controlling factor for sea-level change. In addition to local factors, long-term sea level also varies by remote forcing (equatorial zonal wind stress), which explains approximately 36 % of the sea-level variation in this bay. Sea level is low during the combined events of positive Indian Ocean dipole (IOD) and El Niño, whereas the sea level is high during the combined events of negative IOD and La Niña. This study provides an improved understanding of seasonal and longer-term inter-annual variations of sea level and the necessary groundworks for a dedicated model study to further quantify all the components of the sea-level budget in the study areas. 相似文献