在数据稀少的情况下,沿海土地沉降对海平面上升的潜在影响:加纳沃尔特三角洲案例

IF 2.9 Q2 GEOGRAPHY, PHYSICAL Quaternary Science Advances Pub Date : 2024-02-29 DOI:10.1016/j.qsa.2024.100175
Selasi Yao Avornyo , Philip S.J. Minderhoud , Pietro Teatini , Katharina Seeger , Leon T. Hauser , Marie-Noëlle Woillez , Philip-Neri Jayson-Quashigah , Edem Mahu , Michael Kwame-Biney , Kwasi Appeaning Addo
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引用次数: 0

摘要

三角洲是非常宝贵的环境系统,通过其生态系统服务确保各种生计。然而,人类影响和气候变化压力因素正在对三角洲造成巨大影响。因此,包括加纳的沃尔特三角洲在内的许多三角洲正面临着越来越大的风险,尤其是灾害的严重程度在不断增加,对沿海地区的生计造成了影响。为了更好地了解沃尔特三角洲的沿海灾害,本研究评估了三角洲的沉降机制及其对海平面上升(SLR)潜在影响的后果。利用干涉合成孔径雷达 (InSAR) 技术和全球导航卫星系统 (GNSS) 勘测,记录了陆地垂直运动 (VLM)。从 2016 年到 2020 年的哨兵 1 号数据干涉图显示,下沉速度高达-9.2 毫米/年。通过将当地的 VLM 信息与最近的 SLR 预测和海拔数据相结合,本研究更新了这些预测,并对潜在的相对 SLR(rSLR)影响进行了当地评估。根据这些经过本地改进的情景,到 2100 年,三角洲多达 45% 的地区将低于当地海平面,其中近 10% 的地区仅通过整合本地 VLM 数据来解释。根据所使用的气候变化情景,陆地沉降将使三角洲的危险面积增加 4.31%(96.27 平方公里)到 10.18%(227.64 平方公里),从而加剧其遭受沿海淹没的风险。为避免出现上述预测,该研究建议建立健全的监测制度;采用其他淡水来源替代地下水;减少沉积物滞留和河流阻塞;以及必须停止目前正在伏尔泰盆地进行的石油和天然气勘探及随后的开采活动。
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The contribution of coastal land subsidence to potential sea-level rise impact in data-sparse settings: The case of Ghana’s Volta delta

Deltas are highly valuable environmental systems, ensuring various livelihoods through their ecosystem services. However, human impact and climate change stressors are impacting deltas immensely. Consequently, many deltas, including Ghana's Volta Delta, are facing increasing risks, especially as hazards are increasing in magnitude and impacting coastal livelihoods. To provide a better understanding of coastal hazards in the Volta Delta, this study assessed the Delta's subsidence regime and its consequences for the potential impact of sea-level rise (SLR). Using the Interferometric Synthetic Aperture Radar (InSAR) technique and Global Navigation Satellite System (GNSS) surveys, vertical land motion (VLM) was documented. Interferograms of Sentinel-1 data from 2016 to 2020 indicated subsiding rates of up to −9.2 mm/yr. By combining local VLM information with recent SLR projections and elevation data, this study updates those projections and provides local assessments of potential Relative SLR (rSLR) impact. According to these locally improved scenarios, up to ∼45 % of the Delta will fall below local sea level by 2100, of which close to 10 % is explained by the integration of local VLM data alone. Depending on the climate change scenarios used, land subsidence will increase the deltaic area at risk by 4.31 % (96.27 km2) to 10.18 % (227.64 km2) and consequently exacerbate its exposure to coastal inundation. To avert the projections, the study recommends robust monitoring regimes; alternative freshwater sources to groundwater; reduced sediment trapping and river obstruction; and the need to stall ongoing oil and gas prospecting and subsequent extraction in the Voltain Basin.

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来源期刊
Quaternary Science Advances
Quaternary Science Advances Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
4.00
自引率
13.30%
发文量
16
审稿时长
61 days
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