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New Scaling Relationships of
Earthquake Source Parameters for
Stochastic Tsunami Simulations
Katsu Goda
Senior Lecturer in Civil Engineering
University of Bristol
United Kingdom
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Probabilistic Tsunami Risk Analysis
Scenarios &
source region
characteristics
Scenario
generation
Exposure
Scenarios may
be specified
based on
inversion
models
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Hazard
modelling
Vulnerability
Consequences
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Scaling Relationships for Source Parameters
• Earthquake source modelling aims at predicting key characteristics
of a fault rupture based on past major earthquakes.
• The results are typically summarised as empirical scaling
relationships (Wells and Coppersmith 1994; Murotani et al. 2013).
• The source parameters of interest include fault geometry, slip
statistics, and spatial slip distribution.
• Currently, there is a critical gap in stochastic earthquake source
modelling: lack of comprehensive evaluations of the spatial slip
distribution parameters (also applicable to geometry/slip statistics
parameters) for large mega-thrust subduction earthquakes.
• New scaling relationships are useful for characterising uncertainties
of earthquake source characteristics in strong motion and tsunami
simulations.
bristol.ac.uk/cabot Living with environmental uncertainty 5
SRCMOD Database
• SRCMOD
(http://equake-
rc.info/srcmod/) is a
comprehensive and
growing on-line
database of finite-
fault rupture models
• It includes 317
inversion-based
rupture models
from 155
earthquakes as of
December 2015.
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Analysis of Finite-fault Rupture Model
• Numerous
source models
are analysed
consistently and
uniformly.
• Effective
dimension
analysis -> Box-
Cox analysis ->
Spectral analysis
12 )1()(
H
zx
k
AAkP
von Karman model:
Estimated
parameters:
width, length, area,
mean slip, max slip,
Box-Cox power,
correlation lengths,
and Hurst number
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Fault Geometry Parameters
• The prediction model of the fault width for subduction events
differs from existing scaling relationships.
• The different behaviour is related to the dip angle of the fault plane
and lower limit of the seismogenic thickness.
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Slip Statistics Parameters
• Both mean and maximum slips for subduction models differ
significantly from those for non-subduction models.
• These two parameters are highly correlated.
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Spatial Slip Distribution Parameters
• The prediction model of the correlation length for subduction
events differs from an existing scaling relationship.
• This is similar to the fault width.
bristol.ac.uk/cabot Living with environmental uncertainty 10
Spectral Synthesis of Slip Distribution
(i) Define a scenario and fault model.
(ii) Generate source parameters from scaling
models.
(iii) Generate a slip distribution and determine
its position within the fault plane.
(iv) Perform tsunami simulation
(v) Repeat (i) to (iv) for probabilistic hazard
analysis.
bristol.ac.uk/cabot Living with environmental uncertainty
Synthesised Stochastic Source Models
• A Mw9.0 scenario is
considered in the
Tohoku region of
Japan.
• Two cases are set up
for the inclusion or
exclusion of prediction
errors of the scaling
models.
• Various source models
are generated for
probabilistic hazard
analysis.
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Tsunami Hazard Assessment
• Uncertainty associated with tsunami
hazard analysis can be quantified
and visualised through various
graphical plots.
• These are useful for making tsunami
risk management decisions.
Probability distribution of
inundation area above 3 m
depth for the two cases
Spatial variation of tsunami
height along the coast for
the two cases
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Tsunami Hazard Maps
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Summary
• New scaling relationships of the earthquake source parameters
enable probabilistic earthquake-tsunami hazard-risk assessments
by accounting for detailed spatial slip characteristics.
• The new models are particularly applicable to mega-thrust
subduction earthquakes.
• The new models are multivariate prediction models of the source
parameters (variability and dependency are modelled).
• The stochastic tsunami simulation can be carried out using the new
models.
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Future Research Topics
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Ongoing Research Development
• Applications of stochastic earthquake-tsunami hazard and risk
methods to different subduction regions: Nankai-Tonankai (Japan),
Sumatra (Indonesia), Guerrero (Mexico), Cascadia (Canada), etc.
• Multi-variate modelling of building vulnerability: peak ductility and
residual ductility for shaking vulnerability and inundation depth and
flow velocity for tsunami vulnerability.
• Analytical earthquake-tsunami fragility modelling of structures.
• Probabilistic coupled earthquake-tsunami hazard-risk analysis.
• Multi-hazard insurance and catastrophe bonds – what is the tipping
point of shaking related loss and tsunami related loss? This also
requires different modes of emergency responses.
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Nankai-Tonankai Earthquake
• The Nankai-Tonankai earthquake is anticipated to occur in the near
future.
• The new tsunami source models developed by the Cabinet Office do
not take full account of uncertainties associated with the rupture
scenarios.
• The stochastic source
models for the
Nankai-Tonankai
event are developed
for hazard and risk
prediction purposes.
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• Stochastic
source models
for the Nankai-
Tonankai
earthquake.
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• Stochastic
inundation
maps for
Hamamatsu
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Coupled Simulation: Strong Motion
• Comparison of
observed and simulated
ground motions at
MYGH08 (Iwanuma)
and MYGH12
(Shizugawa).
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Coupled Simulation: Tsunami
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Any Questions?
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