Nearshore ice complex breakup is controlled by a balance between thermal and mechanical processes

IF 2.8 3区 地球科学 Q2 GEOGRAPHY, PHYSICAL Earth Surface Processes and Landforms Pub Date : 2023-09-07 DOI:10.1002/esp.5698
Ethan J. Theuerkauf, Lucas K. Zoet, Stefanie E. Dodge, William Tuttle, J. Elmo Rawling III
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Abstract

Shore ice is an important facet of cold-climate coastal geomorphology yet is generally understudied in comparison to other aspects such as nearshore hydrodynamics. Climate change is resulting in more dynamic shore ice regimes (i.e., shortened ice season and multiple freeze–thaw cycles); thus, a clear understanding of the role of shore ice in coastal geomorphic evolution is needed. The presence of shore ice is generally thought to provide the coast a protective buffer from storm waves though some studies have indicated enhanced nearshore erosion and sediment transport associated with ice development. This is particularly apparent during the breakup phase of shore ice as sediment can be scoured from the bed, deposited in place, or transported offshore. Given this, understanding the mechanics of shore ice breakup is critical. This study documents the first combined field and laboratory evaluation of the physical conditions leading to shore ice breakup, detailing the complex interplay between thermal and mechanical processes in ice deterioration. Through a wave tank experiment as well as field observations, wave impacts alone are shown to be unlikely to cause breakup of shore ice and thermal weakening is required. This has important implications both for predicting when ice will break up as well as for identifying potential nearshore sediment transport pathways. If ice breaks up entirely from thermal degradation, then sediment is likely to be deposited in place, whereas if ice breaks up from a combination of thermal degradation and wave impact, then sediment can be redistributed across the shoreface. Monitoring of meteorological conditions during ice breakup can likely be used as a first-order predictor of geomorphic changes resulting from shore ice deterioration.

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近岸冰群的破碎是由热和机械过程之间的平衡控制的
海岸冰是寒冷气候海岸地貌的一个重要方面,但与近岸水动力学等其他方面相比,通常研究不足。气候变化正在导致更动态的海岸冰状态(即冰季缩短和多次冻融循环);因此,有必要清楚地认识岸冰在海岸地貌演变中的作用。海岸冰的存在通常被认为为海岸提供了一个免受风暴波浪的保护缓冲,尽管一些研究表明,与冰的发展有关的近岸侵蚀和沉积物运输加剧。这在岸冰破裂阶段尤其明显,因为沉积物可能从床上冲刷出来,沉积在原地,或被运往近海。考虑到这一点,了解海岸冰破裂的机制至关重要。这项研究首次记录了现场和实验室对导致海岸冰破裂的物理条件的综合评估,详细说明了冰退化过程中热和机械过程之间复杂的相互作用。通过波浪槽试验和实地观测,表明波浪的单独影响不太可能造成岸冰的破裂,需要进行热削弱。这对于预测冰何时破裂以及确定潜在的近岸沉积物运输途径都具有重要意义。如果冰完全因热降解而破裂,那么沉积物很可能会沉积在原地,而如果冰因热降解和波浪冲击而破裂,那么沉积物可能会在海岸表面重新分布。监测冰崩解期间的气象条件可能被用作海岸冰退化导致的地貌变化的一级预测因子。
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来源期刊
Earth Surface Processes and Landforms
Earth Surface Processes and Landforms 地学-地球科学综合
CiteScore
6.40
自引率
12.10%
发文量
215
审稿时长
4 months
期刊介绍: Earth Surface Processes and Landforms is an interdisciplinary international journal concerned with: the interactions between surface processes and landforms and landscapes; that lead to physical, chemical and biological changes; and which in turn create; current landscapes and the geological record of past landscapes. Its focus is core to both physical geographical and geological communities, and also the wider geosciences
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