Geotechnical and Structural Investigations in Malatya Province after Kahramanmaraş Earthquake on February 6, 2023

Özgür Yıldız; Ceren Kına

doi:10.17798/bitlisfen.1282555

Research Article

Geotechnical and Structural Investigations in Malatya Province after Kahramanmaraş Earthquake on February 6, 2023

Year 2023, Volume: 12 Issue: 3, 686 - 703, 28.09.2023

Özgür Yıldız , Ceren Kına

https://doi.org/10.17798/bitlisfen.1282555

Cited By: 3

Abstract

Two earthquakes with moment magnitudes of 7.7 and 7.6 occured on February 6, 2023, at 04:17 a.m. (with local time, GMT+3) in Kahramanmaraş-Ekinözü Pazarcık and at 13:24 p.m. (with local time, GMT+3) in Kahramanmaraş-Elbistan, respectively, in Turkey. The earthquake was felt in a wide area within Turkey and caused structural destructions and heavy damage of buildings, especially in eleven cities including Adana, Adıyaman, Diyarbakır, Gaziantep, Hatay, Kahramanmaraş, Kilis, Malatya, Osmaniye, Şanlıurfa and Elazığ. The aim of this study was to present the detailed field investigation in Malatya province which was one of the most affected city in the region. The strong ground motion records have been analyzed and PGA distribution maps were presented. Structural defects in damaged and collapsed buildings were examined, and design and manufacturing defects were examined. The performance of soil structures was examined, and the defects demonstrated were evaluated in the context of the geological environment. The study is essential in terms of evaluating the damage and possible causes of the building stock in Malatya city center and its districts after the earthquake. In this sense, a holistic evaluation has been carried out, which can be a useful resource for Anatolian cities with typical building characteristics.

Keywords

Kahramanmaraş earthquake, Reinforced concrete buildings, Collapse, Damage, Earth structures, Geotechnical investigation

Supporting Institution

TÜBİTAK

Project Number

TÜBİTAK 1002C

Thanks

The data and pictures used in the study were partially compiled from the project final report supported by the TUBITAK 1002C program.

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