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Abstract
Steep slopes along narrow-high coastlines are highly susceptible to slope hazards due to road construction and quarrying activities. On December 8, 2024, a landslide occurred on the southern slope of the Black Sea Coastal Highway near the Kıyıcık locality in the Arhavi district (Artvin, Türkiye). This landslide resulted in the loss of four lives and led to the temporary closure of the Black Sea Coastal Highway, which is of both national and international importance. This study aims to investigate the role of the Black Sea Coastal Road construction in triggering the Kıyıcık landslide. The research utilizes historical aerial photographs, high-resolution drone imagery obtained after the landslide, a 1:25,000 scale topographic map, and climate records from 1962 to 2022. X-ray diffraction (XRD) analysis was conducted to determine the mineral composition of the landslide mass, and spatial analyses were performed using Remote Sensing and Geographic Information System (GIS) technologies. The weathering effect of marine moisture and wind on the narrow-high coastal slope, and the erosion effect of heavy waves in stormy weather overtopping the road platform and reaching the slope are natural processes. The landslide mass comprises saprolite and lateritic regolith—products of the chemical weathering of mafic volcanic rocks. Road construction and quarrying operations have increased slope steepness, fracture density in the mafic volcanic rocks, and the intensity of chemical weathering processes. A total of 244.4 kg/m2 of rainfall and infiltration between November 16 and 29, 2024, caused water accumulation in the loose regolith, increasing the static load and triggering a translational earth landslide. Tension cracks and fissures observed in the area indicate that the landslide remains active, highlighting the need for further risk mitigation measures.
Keywords
Narrow-high coast
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Coastal Road
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Landslide
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Artvin (Türkiye)
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Hüseyin Turoğlu, Abdulkadir Duran.
The Impact of Coastal Road Construction on Kıyıcık Landslide (Artvin, Türkiye) in December 2024.
Anthropocene Coasts, 2025, 8(1): 35 DOI:10.1007/s44218-025-00104-x
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