work programme topics addressed:
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New Directions in Seismic Hazard Assessment through Focused Earth Observation in the M AR mara Super SITE. Work programme topics addressed: - PowerPoint PPT PresentationTRANSCRIPT
New Directions in Seismic Hazard Assessment through Focused Earth Observation in the MARmara
SuperSITE
Work programme topics addressed: ENV.2012.6.4-2 Long-term monitoring experiment in geologically active regions of Europe prone to natural
hazards: the Supersite concept16 - FP7-ENV-2012-two-stage.
Project Coordinator: Prof. Dr. Nurcan Meral Özel
Project acronym: MarSite
B) The seismicity of the Marmara Region from combined catalogues of KOERI and TUBITAK (1964-2011, M≥2.5).
A) The occurrence years and possible locations of historical earthquakes .
Instrumental observation infrastructure of Marmara
The MARsite project proposes to identify the Marmara region as a ‘Supersite’ within European initiatives to aggregate on-shore, off-shore and space-based
observations, comprehensive geophysical monitoring, improved hazard and risk assessments encompassed in an integrated set of activities to respond to all
priorities identified in the ENV.2012.6.4-2 call.
OBJECTİVES
MARsite aims to: 1) harmonize geological, geophysical, geodetic and geochemical observations to
provide a better view of the post-seismic deformation of the 1999 Izmit earthquake (in addition to the post-seismic signature of previous earthquakes),
2) investigate loading of submarine and inland active fault segments and transient pre-earthquake signals, related to stress loading with different tectonic properties in and around Marmara Sea.
3) explore earthquake/landslide triggering mechanisms and tsunami hazard modelling.
4) obtain rapid source-mechanism solutions and slip models, 5) develop new algorithms for early warning and rapid-response studies, 6) establish a risk management cycle with the creation of a link between the scientific
community and end users. 7) to develop novel geo-hazard monitoring instruments including high-resolution
displacement meters, novel borehole instrumentation and sea-bottom gas emission and heat-flow measurement systems, in association with the relevant industrial sectors and SMEs.
Participant no. *
Participant organisation name Country
1
(Coordinator)KOERI
(Bogazici University, Kandilli Observatory and Earthquake Research Institute) Turkey
2GFZ
(Helmholtz-Zentrum Potsdam Deutsches GeoForschungsZentrum)
Germany
3 TUBITAK(The Scientific & Technological Research Council of Turkey) Turkey
4 IFREMER(Research Institute for Exploration of the Sea ) France
5 INGV(Istituto Nazionale di Geofisica e Vulcanologia) Italy
6 IU(Istanbul University) Turkey
7 KOU(Kocaeli University) Turkey
8 ITU(Istanbul Technical University) Turkey
9 CNR(The National Research Council) Italy
10 BRGM(Bureau de Recherches Géologiques et Minières) France
11 Eucentre(European Centre for Training and Research in Earthquake Engineering) Italy
12 CNRS(Centre National de la Recherche Scientifique) France
13 INERIS(French National Institute for Industrial Environment and Risks) France
14 AMRA(Analysis and Monitoring of Environmental Risk) Italy
15 EMSC(European-Mediterranean Seismological Centre) France
16 ESA(European Space Agency) Netherland
17 Univ. of Pavia Italy
18 IFSTTAR(French Institute of Science and Technology devoted to Transport, Planning and Networks) France
19 GURALP Systems Ltd UK
20 DAIMAR s.r.l. Italy
21 SARMAP s.a. Switzerland
MARsite WPs
7JICA-JST Meeting, 26 June 2012
MARsite will use the power of -dense seismological, geochemical and GPS networks-experts on PSInSAR and SBAS analysis-combination of the remote-sensing and ground-based data-developing and demonstration of new systems-Integration of different data sources, uses of data etc.-early warning and rapid response system for Istanbul-Real-time data provision during crisis period (e.g. aftershocks)
MARSiteThe monitoring of the 'Supersites' should be conducted through a fully integrated conceptual approach based on collaboration with existing monitoring networks and international initiatives, developing new instrumentation such as in-situ sensors, and aggregating space and ground-based observations (including from subsurface), and geophysical monitoring.
The project(s) will develop and demonstrate the next generation of geo-hazards monitoring/observing systems, and contribute to establishing comprehensive natural hazards observatories through a cross-cutting approach.
MARSiteThe projects will establish a chain from observations to end users. The outcomes will be
applied to the phases of the risk management cycle relevant for this region.
GeologicalGeophysical Models
Hazard estimation
.Collection of Multidisiplinary Data from avaliable networks.Developing of newsystems.Contribution of SMEs
Collobrative efforts in the frame of the Marsite
EVENT
Optimization of Risk
Cycle under this project
Risk Studies&Vulnerability Estimation
Links to end users &Risk Mitigation
Harmonzation&Re-evaluation
of the avaliable data
Work Packages Coordinaton and link to other projects
Data from available networks, Satellite data/Harmonization and modeling for hazard studies
To develop new technologies and methodologies
To study the triggering between natural hazards, experiences from 1999 eq. (Avcilar)
To create a link to end-users
To understand the Marmara tectonics and upgrade the avaliable models
Work Packages To estimate real time hazard
Work Packages
the locations of borehole (red star) earthquake recording stations (triangles are permanent KOERI stations; rectangles are TUBITAK temporary
stations and red circles are the surface array stations, which will be installed in the frame of this project)
Establishment of Borehole Observation System and High Resolution Seismic Studies in the Western part of the main Marmara Fault in the frame of a EU-FP7 project titled as MARSITE
MARsite will adopt Advancing GEOSS Data Sharing Principles
• MARsite will adopt Advancing GEOSS Data Sharing Principles and will incorporate related GEOSS strategic targets defined as “Provide a shared, easily accessible, timely, sustained stream of comprehensive data of documented quality, as well as metadata and information products, for informed decision making….” in GEOSS Strategic Targets - Document 12 (Rev,1), page 8.
• • The high level Data Sharing Principles represents on of the foundations for GEOSS, and
their effective yet flexible implementation remains a major challenge. MARSite will be a good chance to experiment their application. The 10-year implementation plan sets out the GEOSS Data Sharing Principles:
• • There will be full and open exchange of data, metadata and products shared within
GEOSS, recognizing relevant international instruments and national policies and legislation
– MARSite partners will actively share their data among themselves, through suitable tools such as the shared repository on the project web site, and will experiment and tune the data sharing models and interfaces that will potentially be used for data sharing at large within the GEO Supersite iniziative
Outcomes of the MARsite project:
. Geodetic monitoring of 4D deformations in order to understand earthquake cycle processes, to develop probabilistic earthquake forecasting models and to constrain the seismic hazard models in the Marmara region;•High resolution data acquired by a new generation deep multidisciplinary complete digital borehole seismic station;•Rapid and quantitative ShakeMap scheme by implementing finite-source descriptions and calibrating with multiple geodetic/seismic data;•Characterization of activated and reactivated Deep-seated Gravitational Slope Deformations (DGSD) determined through the integration of geological and geomorphological analyses with high-resolution DInSAR;•Knowledge on the distribution of active structures in the Marmara Region and the amount of motion they localize;•Geophysical, seismological, physical and geochemical data from automatic sea-floor devices (e.g. OBS, Piezometers, acoustic station and multidisciplinary SN4-type observatory) including data from periodical cruises for water column sampling and laboratory analyses, for seafloor degassing measurements; and •Results on earthquake early-warning (EW) and rapid-response systems in the Marmara Region (Istanbul) with the addition of a pilot landslide monitoring and EW system and introduction of new space technologies for monitoring and assessment of vulnerabilities. •Therefore, MARsite will surely have an important impact on the regional response for seismic risk prevention, but also plays a scientific/technical significant role as a European supersite.
JICA-JST Project (Japan-Turkey) Theme 1: Seafloor Observations for Earthquake Source Models in the Marmara Sea
Region Subgroup 1.1: Long-term sea-bottom seismic observation 1.1.a Micro-Earthquake activity 1.1.b Stress field evaluation 1.1.c Seismic tomography Subgroup 1.2: Electromagnetic observation Subgroup 1.3: GPS-acoustic observation Subgroup 1.4: Geo chemical studies (water chemistry, radon, temperature, gas
exhalations, current etc. Theme 2: Estimation of Strong Ground Motion for Earthquake Source Models Subgroup 2.1: Micro-tremor observation and subsoil structure Subgroup 2.2: Observation of strong ground motion Subgroup 2.3: Theoretical estimation of ground motion Theme 3: Experimental Study of Building Response to Strong Ground Motion Theme 4: Forecasts of Earthquake and Tsunami Occurrences in the Marmara Sea
Region Subgroup 4.1: Incorporation of seafloor seismic data into Earthquake Early Warning
(EEW) Subgroup 4.2: Simulation of large earthquake occurrence along the North Anatolian Fault
beneath the Marmara Sea and estimation of possible rupture parameters Subgroup 4.3: Tsunami simulations and hazard assessment. Subgroup 4.4: Tsunami monitoring Theme 5: Understanding of historical large earthquakes at on-land branches of the
western part of the North Anatolian Fault Subgroup 5.1: Trenching studies Subgroup 5.2: InSAR studies
Theme 6: Effective Dissemination of Earthquake Hazard Information Subgroup 6.1: Earthquake monitoring in the Yalova-Izmit-Bursa-Sakarya area
Subgroup 6.2: Rapid information with collaboration of mass-media Subgroup 6.3: Hazard and risk assessment with collaboration of administration
Subgroup 6.4: Disaster Education Program
1. Earthquake Source Model2. Tsunami prediction based
on earthquake scenarios4. Disaster education using
research result visuals
Istanbul & Local regions around Marmara Sea ⇒ Nationwide in Turkey
Objective of JST Project
JST superiority object
Estimation of the source region
Proposing a Disaster Prevention Plan against Marmara Earthquakeon the basis of scientific research analyses
3. Seismic characterization and damage prediction
Evaluation of linkage of the anticipated Marmara earthquake
based on the estimated source region
Disaster education program and organizing the Content
Implementing the proposed disaster prevention plan by Turkish Government
Development and enlargement of the numerical simulation
Analysis of the anticipated Marmara earthquake and tsunami
generation process
Improvement of hazard maps and visualizations
Seismic assessment:Seismic evaluation considering retrofitting and seismic isolation
Creating reference materials for disaster education and for disaster prevention countermeasures
Visualization
Japan-Turkey Joint seafloor observatory
Numerical modeling of the active Faults beneath the Sea of Marmara
based on the existing observational data
・ Prediction of building Vibration ・ Evaluation of existing structures
Integration of land and sea data:・ Shape of fault and bathymetry・ Friction characteristics
・ Plate motion velocity・ Historical seismic activity
Theoretical prediction of strong ground motion of the
anticipated Marmara earthquakeEstimation of fault shapes and fault
brunches beneath the Sea of Marmara based on integrated data
20%
0%
40%
60%
80%
100%
Integration of the data observed in (sea bottom) and around (land) the Sea of Marmara
Identification of the vibration characteristics of buildings
based on design documents and experimental study
On the ground surface (around the building)
Microtremor and earthquake observation in and around the existing
buildings (schools, hospitals, etc.)
Estimation of subsurface
structure
In the building1st Floor and Top Floor
source region of the anticipated Marmara earthquake
Numerical modellingVisualization
Preliminary numerical simulation Of tsunami and earthquake cycle
extraction of lack of data⇒
Determine each regions needs and problems
Sharing experiences of earthquake – tsunami victims from Japan and Turkey
Extraction of necessary information from rapid analysis
Development of rapid analysis process
Regional disaster prevention community
Disaster management symposium
Information disseminationStudy Committee
Broadcasting the preliminary information through mass-media, telecommunication and internet
⇒ Rapid response in the case of a disaster
Disaster experience.Reflect the regional issues
Awareness training and disaster prevention plan against Marmara Earthquake
Thank you yThank you...
21
Boğaziçi UniversityKandilli Observatory and Earthquake Research Institute