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The Marmara, Turkey Earthquake of August  17, 1999: Reconnaissance Report

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Foreword

by George C. Lee
Director, Multidisciplinary Center for Earthquake Engineering Research

Over the years, MCEER has supported many rapid surveys and reconnaissance visits to areas hit by severe earthquakes. Observations in the field as soon as possible following a major earthquake are one of the important ways in which vital data can be gathered and important lessons learned. In order to realize our vision of "earthquake resilient communities," these often tragic events must be investigated to validate our collective knowledge and to discover new insight into success stories and failures.

Our multidisciplinary team members conduct their reconnaissance visits primarily to support and foster knowledge development within MCEER’s research program. The mission of the research program is to investigate how advanced and emerging technologies can be adapted and implemented to reduce earthquake hazards. Research efforts focus on development and calibration of loss estimation methodologies, damage evaluation, detection and response technologies, and development of retrofit strategies for critical facilities (such as lifelines, buildings and their contents, and bridges). The time period immediately following a destructive earthquake offers a critical window of opportunity to determine more closely the "weak links," reasons for failure or unacceptable performance, and to observe the success stories.

The observations and recommendations made by our team members are presented in this report, for the benefit of people in seismic regions throughout the world. Only by absorbing the technical and institutional lessons from these events, and then further developing our understanding and potential solutions in the laboratory and in our communities, can the potential for future tragedies be reduced.

 

Preface

Early in the morning of Tuesday, August 17, 1999, a magnitude 7.4 earthquake struck along the Anatolian fault in the northwestern region of Turkey. Epicentered approximately 11 km southeast of the industrial city of Izmit, the earthquake lasted 45 seconds and was felt over thousands of square miles in Turkey’s most densely populated region. Commercial and residential buildings from Adapazari to Istanbul collapsed, resulting in large-scale loss of life. According to official government estimates (as of October 19, 1999), the earthquake killed over 17,000, and injured almost 44,000 people. Estimates of property losses (as of September 14, 1999) according to the World Bank range from $3 to $6.5 billion, which is equivalent to 1.5 to 3.3 percent of the Gross National Product of Turkey. It was the most devastating earthquake to strike Turkey since the 1939 Erzincan earthquake, which killed 30,000 people. According to official Turkish government estimates, the earthquake displaced more than 250,000 people. Approximately 120 tent cities were required for emergency housing. About 214,000 residential units and 30,500 business units were lightly to heavily damaged.

Within days, MCEER dispatched several researchers to the region - three of them simultaneously serving as part of the Earthquake Engineering Research Center (EERI) reconnaissance team - to examine the earthquake’s impact. Their initial observations and impressions are reported in two publications, MCEER Response by M. Bruneau, J. Mander, W. Mitchell, A. Papageorgiou, C. Scawthorn and N. Sigaher, and in a Preliminary Report by C. Scawthorn. Both reports can be accessed from our web site at http://mceer.buffalo.edu/research/turkeyeq/default.asp.

MCEER sponsored a second reconnaissance trip to Turkey together with the Earthquake Disaster Mitigation (EDM) Research Center in Miki, Japan. Team members visited Turkey from September 28 to October 4 to conduct high level reconnaissance using satellite imagery, differential global positioning systems and in-field GPS-GIS interfaces. In addition, restoration activities already underway were observed and documented.

This report includes observations from both these reconnaissance trips. It is the product of many authors representing several disciplines and, while not a final assessment of the topics addressed, represents an interim earthquake engineering evaluation of the natural, built and social environments. As noted by several of the authors, the analogies between the North Anatolian Fault Zone in Turkey and the San Andreas Fault in the United States are strikingly similar. The observations and conclusions herein form a springboard for future collaborative research efforts, which will advance society’s ability to better withstand the destruction caused by earthquakes throughout the world.

 

Introduction

Contents


Section 1 Introduction
Charles Scawthorn, EQE International, Inc.
   
Section 2 Seismology
Apostolos Papageorgiou, Department of Civil, Structural and Environmental Engineering, University at Buffalo, State University of New York
2.1 Seismological Parameters
2.2 North Anatolian Fault Zone (NAFZ)
2.3 Fault Slip of the 1999 Marmara Earthquake
2.4 Similarities and Differences Between the North Anatolian Fault and the San Andreas Fault
2.5 Strong Motion Recordings
2.6 Conclusion
2.7 References
   
Section 3 Geotechnical Effects
James Mitchell, Department of Civil and Environmental Engineering, Virginia Polytechnic Institute and Thomas Holzer, U.S. Geological Survey
3.1 Geological Setting
3.2 Ground Motions and Site Response
3.3 Soil Liquefaction
3.4 Landslides and Subsidence
3.5 Behavior of Building Foundations
3.6 Performance of Improved Ground and Earth Structures
3.7 Waterfront Structures
3.8 Geotechnical Effects on Transportation Systems
3.9 Conclusion
3.10 References
   
Section 4 Structural Damage
Michel Bruneau, Department of Civil, Structural and Environmental Engineering, University at Buffalo, State University of New York
4.1 Past Earthquake History and Damage
4.2 Building Characteristics and Building Codes
4.3 Structural Damage
4.3.1 Foundation Failures
4.3.2 Soft Stories
4.3.3 Strong Beams and Weak Columns
4.3.4 Lack of Column Confinement and Poor Detailing Practice
4.3.5 Miscellaneous
4.4 Damage to Steel Structures
4.5 Other Construction Types, Nonstructural Damage and Seismic Retrofit
4.6 Damage from Aftershocks
4.7 Lessons Learned and Conclusions
4.8 References
   
Section 5 Damage to the Transportation Infrastructure
John Mander, Department of Civil, Structural and Environmental Engineering, University at Buffalo, State University of New York
5.1 Damage to Highway Bridges
5.1.1 Collapse of the D650 E-80 Motorway Overpass
5.1.2 Collapsed Local River Bridge Near Akyazi
5.1.3 Damage to the E-80 Motorway Bridges over the Sakarya River
5.1.4 Damage to the D310 Overpass that Crosses the E-80 Motorway
5.1.5 Damage to Bridges on the D100 Highway
5.2 Damage to Roads
5.3 Damage to Railways
5.4 Damage to Port Facilities
5.5 Conclusion
   
Section 6 Performance of Industrial Facilities
Gayle S. Johnson, EQE International, Inc., Mark Aschheim, Department of Civil Engineering, University of Illinois at Urbana-Champaign and Halil Sezen, Pacific Earthquake Engineering Research Center, University of California, Berkeley
6.1 Types of Industry
6.1.1 Petrochemical Industry
6.1.2 Automobile Industry
6.2 Summary of Damage and Business Interruption
6.3 Tüpras Refinery Damage
6.3.1 Crude Unit and Stack Collapse
6.3.2 Port Damage and Oil Spill
6.4 Building Performance at Industrial Facilities
6.5 Performance of Non-Building Structures
6.6 Tank Damage
6.7 Equipment Damage
6.8 Other Fires
6.9 Summary
   
Section 7 Lifeline Performance
Charles Scawthorn, EQE International, Inc.
7.1 Water Systems
7.2 Wastewater
7.3 Electric System
7.4 Gas System
7.5 Summary and Lessons Learned
   
Section 8 Social, Political and Emergency Response
William Mitchell, Department of Political Science, Baylor University
8.1 Search and Rescue (Initial Response)
8.2 Brief Overview of Emergency Response
8.3 Casualties and Injuries
8.4 Medical Facilities
8.5 Mental Health Services
8.6 Displaced Persons
8.7 Turkish Red Crescent and Other Organizational Response
8.8 Media Response
8.9 Human Impact of the Destruction and Damage
8.10 Recommendations for Further Study
8.11 Conclusions
8.12 References
   
Section 9 Restoration Activities
Gary Webb, Disaster Research Center, University of Delaware
9.1 Housing and the Earthquake
9.1.1 Estimating the Number of Homeless
9.1.2 Three Types of Tent Cities
9.1.3 Adjusting to Daily Living in the Tent Cities
9.2 Restoration of Education After the Earthquake
9.3 Health Care Facilities and the Earthquake
9.4 Concluding Remarks and Future Research Needs
9.5 References
Section 10 The Marmara Earthquake: A View from Space
Ronald Eguchi, ImageCat, Inc., Charles Huyck, EQE International, Inc., Bijan Houshmand, Department of Electrical Engineering, University of California at Los Angeles, Babak Mansouri and Masanobu Shinozuka, Department of Civil Engineering, University of Southern California, Fumio Yamazaki and Masashi Matsuoka, Earthquake Disaster Mitigation Research Center, and Suha Ülgen, IMAGINS - TED
10.1 Purpose of the Trip
10.2 Itinerary
10.3 Field Investigations
10.3.1 New Technologies
10.3.2 Avcilar
10.3.3 Seymen
10.3.4 Adapazari
10.4 Summary

 

Acknowledgments

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