Seismic Performance of Ancient Masonry Structures in Korea Rediscovered in 2016 M 5.8 Gyeongju Earthquake

The Gyeongju Historic Areas, which include the millennium-old capital of the Silla Kingdom, are located in the region most frequently affected by seismic events in the Korean peninsula. Despite the numerous earthquakes documented, most of the stone architectural heritage has retained their original...

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Bibliographic Details
Published inSustainability Vol. 11; no. 6; p. 1565
Main Authors Park, Heon-Joon, Ha, Jeong-Gon, Kim, Se-Hyun, Jo, Sang-Sun
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 2019
Subjects
Architectural engineering
Centrifuge model
Centrifuges
Cultural heritage
Earthquake damage
Earthquake resistance
Earthquakes
Engineering
Environmental risk
Geographic information systems
Geotechnical engineering
Ground motion
Historic buildings & sites
Historic sites
Historical structures
History of engineering
Masonry
Memorials & monuments
Model testing
Observatories
Reliability analysis
Reliability engineering
Risk assessment
Seismic activity
Seismic design
Seismic engineering
Seismic hazard
Seismic response
Stone
Structural engineering
Subsoils
Sustainability
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Summary:The Gyeongju Historic Areas, which include the millennium-old capital of the Silla Kingdom, are located in the region most frequently affected by seismic events in the Korean peninsula. Despite the numerous earthquakes documented, most of the stone architectural heritage has retained their original forms. This study systematically reviews and categorises studies dealing with the seismic risk assessment of the architectural heritage of the historic areas. It applies research methodologies, such as the evaluation of the engineering characteristics of subsoil in architectural heritage sites, site-specific analysis of the ground motions in response to earthquake scenarios, geographic information system (GIS)-based seismic microzonation according to the geotechnical engineering parameters, reliability assessment of dynamic centrifuge model testing for stone masonry structures and evaluation of seismic behaviour of architectural heritage. The M 5.8 earthquake that hit Gyeongju on September 12, 2016 is analysed from an engineering point of view and the resulting damage to the stone architectural heritage is reported. The study focuses on Cheomseongdae, an astronomical observatory in Gyeongju, whose structural engineering received considerable attention since its seismic resistance was reported after the last earthquake. Dynamic centrifuge model tests applying the Gyeongju Earthquake motions are performed to prove that it is not a coincidence that Cheomseongdae, a masonry structure composed of nearly 400 stone members, survived numerous seismic events for over 1300 years. The structural characteristics of Cheomseongdae, such as the well-compacted filler materials in its lower part, rough inside wall in contrast to the smooth exterior, intersecting stone beams and interlocking headstones are proven to contribute to its overall seismic performance, demonstrating outstanding seismic design technology.
ISSN:2071-1050
2071-1050
DOI:10.3390/su11061565