Lake Maggiore: geomorphological genesis, lake-level evolution, and present and future ecosystems importance

Pub Date : 2023-09-18 DOI:10.4081/jlimnol.2022.2146
Cristian Scapozza, Nicola Patocchi
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引用次数: 1

Abstract

Lake Maggiore, the second deeper and larger south alpine lake, was selected as a model system to detect the potential damages on water resources, biodiversity and ecosystem health caused by different water levels during the lake-level regulation period (March to November). With a drainage basin exceeding an altitude difference of 4400 m, Lake Maggiore fills a deep valley floor whose bedrock reaches up to 700 m below the present sea level. The cryptodepression occupied by the lake was probably formed during the end of the Miocene and the Pliocene and was shaped successively during the Pleistocene glaciations. Lake Maggiore originated following the Last Glaciation, when it reached its maximum lake-level and extension just after its deglaciation. The mean secular lake-level progressively decreased throughout the Holocene, causing a gradual shrinkage of the lake because of the constant depositional input that created the fluvio-deltaic plains at the mouth of the main tributaries of the lake. The regime of the tributaries is of mixed type, with a spring maximum mainly due to snowmelt and an autumn maximum exclusively of pluvial origin. Water levels naturally tend to reflect the amount of rain or snow precipitation and are expressed through a double cycle: winter and summer characterised by low waters, and spring and autumn by high waters. In 1943, the need to use the waters of the great lakes to have water available in the less favourable periods, led to the construction of a dam at the Lake Maggiore outlet. This structure allows to store water during heavy rainfall or snowmelt periods. The accumulated water is then supplied during the irrigation periods to agriculture (spring and summer) and to industrial users (mainly in autumn and winter). The geomorphological genesis and the ecosystems description was focused on riparian, fluvio-deltaic, and ephemeral systems. For these ecosystems, their evolution considering the hydrological regime of the tributaries, the anthropogenic activities in the watershed and the effects of lake-level management since 1943, was also described. Considering the summer increase, between April and July, to +1.25 m (with possible peaks to +1.50 m) experimentally tested between 2015 and 2020, and the approval of the proposal to continue the test for the next five-year period (2022-2026), we finally emphasise the potential further reduction of reeds and natural habitats and the subsequent loss of biodiversity related to the plan of raise the lake-level to +1.50 m all year round.
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马焦雷湖:地貌成因,湖位演化,现在和未来生态系统的重要性
选取南高寒第二大湖泊马焦雷湖(Lake Maggiore)作为模型系统,检测水位调节期(3 - 11月)不同水位对水资源、生物多样性和生态系统健康的潜在损害。马焦雷湖(Lake Maggiore)的流域高度差超过4400米,它填满了一个深谷底,其基岩深度可达目前海平面以下700米。湖泊所占据的隐坳陷可能形成于中新世至上新世末期,并在更新世冰期期间先后形成。马焦雷湖形成于末次冰期之后,在冰期消退之后,它达到了最大的湖面和延伸。在整个全新世期间,平均长期湖泊水位逐渐下降,由于不断的沉积输入在湖泊主要支流的河口形成了河流三角洲平原,导致湖泊逐渐缩小。支流的状态是混合型的,春季的最大值主要是由于融雪造成的,秋季的最大值完全是由雨源造成的。水位自然地倾向于反映降雨或降雪的数量,并通过双重循环来表示:冬季和夏季以低水位为特征,春季和秋季以高水位为特征。1943年,由于需要利用五大湖的水,以便在不太有利的时期有水可用,因此在马焦雷湖出水口修建了一座大坝。这种结构可以在暴雨或融雪期间储存水。然后在灌溉期间将积累的水供应给农业(春季和夏季)和工业用户(主要在秋季和冬季)。地貌成因和生态系统的描述主要集中在河岸系统、河流三角洲系统和短暂系统。对于这些生态系统,还描述了自1943年以来考虑到支流水文状况、流域人为活动和湖泊水位管理影响的演变。考虑到2015年至2020年期间实验测试的夏季增加(4月至7月)至+1.25 m(可能达到+1.50 m),以及批准在下一个五年期间(2022-2026)继续测试的建议,我们最后强调了芦苇和自然栖息地的潜在进一步减少以及与全年将湖泊水位提高到+1.50 m相关的生物多样性的损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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