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Post-disaster geotechnical response for hilly terrain: a case study from the Canterbury Earthquake Sequence.Yates, Katherine January 2014 (has links)
Case study analysis of the 2010-2011 Canterbury Earthquake Sequence (CES), which particularly impacted Christchurch City, New Zealand, has highlighted the value of practical, standardised and coordinated post-earthquake geotechnical response guidelines for earthquake-induced landslides in urban areas. The 22nd February 2011 earthquake, the second largest magnitude event in the CES, initiated a series of rockfall, cliff collapse and loess failures around the Port Hills which severely impacted the south-eastern part of Christchurch. The extensive slope failure induced by the 22nd February 200 earthquake was unprecedented; and ground motions experienced significantly exceeded the probabilistic seismic hazard model for Canterbury.
Earthquake-induced landslides initiated by the 22nd February 2011 earthquake posed risk to life safety, and caused widespread damage to dwellings and critical infrastructure. In the immediate aftermath of the 22nd February 2011 earthquake, the geotechnical community responded by deploying into the Port Hills to conduct assessment of slope failure hazards and life safety risk. Coordination within the voluntary geotechnical response group evolved rapidly within the first week post-earthquake. The lack of pre-event planning to guide coordinated geotechnical response hindered the execution of timely and transparent management of life safety risk from coseismic landslides in the initial week after the earthquake.
Semi-structured interviews were conducted with municipal, management and operational organisations involved in the geotechnical response during the CES. Analysis of interview dialogue highlighted the temporal evolution of priorities and tasks during emergency response to coseismic slope failure, which was further developed into a phased conceptual model to inform future geotechnical response. Review of geotechnical responses to selected historical earthquakes (Northridge, 1994; Chi-Chi, 1999; Wenchuan, 2008) has enabled comparison between international practice and local response strategies, and has emphasised the value of pre-earthquake preparation, indicating the importance of integration of geotechnical response within national emergency management plans. Furthermore, analysis of the CES and international earthquakes has informed pragmatic recommendations for future response to coseismic slope failure.
Recommendations for future response to earthquake-induced landslides presented in this thesis include: the integration of post-earthquake geotechnical response with national Civil Defence and Emergency Management; pre-earthquake development of an adaptive management structure and standard slope assessment format for geotechnical response; and emergency management training for geotechnical professionals. Post-earthquake response recommendations include the development of geographic sectors within the area impacted by coseismic slope failure, and the development of a GIS database for analysis and management of data collected during ground reconnaissance. Recommendations provided in this thesis aim to inform development of national guidelines for geotechnical response to earthquake-induced landslides in New Zealand, and prompt debate concerning international best practice.
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CPT Prediction of Soil Behaviour Type, Liquefaction Potential and Ground Settlement in North-West ChristchurchVan T Veen, Lauren Hannah January 2015 (has links)
As a consequence of the 2010 – 2011 Canterbury earthquake sequence, Christchurch experienced widespread
liquefaction, vertical settlement and lateral spreading. These geological processes caused extensive damage to
both housing and infrastructure, and increased the need for geotechnical investigation substantially. Cone
Penetration Testing (CPT) has become the most common method for liquefaction assessment in Christchurch,
and issues have been identified with the soil behaviour type, liquefaction potential and vertical settlement
estimates, particularly in the north-western suburbs of Christchurch where soils consist mostly of silts, clayey
silts and silty clays. The CPT soil behaviour type often appears to over-estimate the fines content within a soil,
while the liquefaction potential and vertical settlement are often calculated higher than those measured after
the Canterbury earthquake sequence.
To investigate these issues, laboratory work was carried out on three adjacent CPT/borehole pairs from the
Groynes Park subdivision in northern Christchurch. Boreholes were logged according to NZGS standards,
separated into stratigraphic layers, and laboratory tests were conducted on representative samples.
Comparison of these results with the CPT soil behaviour types provided valuable information, where 62% of
soils on average were specified by the CPT at the Groynes Park subdivision as finer than what was actually
present, 20% of soils on average were specified as coarser than what was actually present, and only 18% of
soils on average were correctly classified by the CPT. Hence the CPT soil behaviour type is not accurately
describing the stratigraphic profile at the Groynes Park subdivision, and it is understood that this is also the
case in much of northwest Christchurch where similar soils are found.
The computer software CLiq, by GeoLogismiki, uses assessment parameter constants which are able to be
adjusted with each CPT file, in an attempt to make each more accurate. These parameter changes can in some
cases substantially alter the results for liquefaction analysis. The sensitivity of the overall assessment method,
raising and lowering the water table, lowering the soil behaviour type index, Ic, liquefaction cutoff value, the
layer detection option, and the weighting factor option, were analysed by comparison with a set of ‘base
settings’. The investigation confirmed that liquefaction analysis results can be very sensitive to the parameters
selected, and demonstrated the dependency of the soil behaviour type on the soil behaviour type index, as the
tested assessment parameters made very little to no changes to the soil behaviour type plots.
The soil behaviour type index, Ic, developed by Robertson and Wride (1998) has been used to define a soil’s
behaviour type, which is defined according to a set of numerical boundaries. In addition to this, the
liquefaction cutoff point is defined as Ic > 2.6, whereby it is assumed that any soils with an Ic value above this
will not liquefy due to clay-like tendencies (Robertson and Wride, 1998). The method has been identified in
this thesis as being potentially unsuitable for some areas of Christchurch as it was developed for mostly sandy
soils. An alternative methodology involving adjustment of the Robertson and Wride (1998) soil behaviour type
boundaries is proposed as follows:
Ic < 1.31 – Gravelly sand to dense sand
1.31 < Ic < 1.90 – Sands: clean sand to silty sand
1.90 < Ic < 2.50 – Sand mixtures: silty sand to sandy silt
2.50 < Ic < 3.20 – Silt mixtures: clayey silt to silty clay
3.20 < Ic < 3.60 – Clays: silty clay to clay
Ic > 3.60 – Organics soils: peats.
When the soil behaviour type boundary changes were applied to 15 test sites throughout Christchurch, 67%
showed an improved change of soil behaviour type, while the remaining 33% remained unchanged, because
they consisted almost entirely of sand. Within these boundary changes, the liquefaction cutoff point was
moved from Ic > 2.6 to Ic > 2.5 and altered the liquefaction potential and vertical settlement to more realistic
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values. This confirmed that the overall soil behaviour type boundary changes appear to solve both the soil behaviour type issues and reduce the overestimation of liquefaction potential and vertical settlement.
This thesis acts as a starting point towards researching the issues discussed. In particular, future work which would be useful includes investigation of the CLiq assessment parameter adjustments, and those which would be most suitable for use in clay-rich soils such as those in Christchurch. In particular consideration of how the water table can be better assessed when perched layers of water exist, with the limitation that only one elevation can be entered into CLiq. Additionally, a useful investigation would be a comparison of the known liquefaction and settlements from the Canterbury earthquake sequence with the liquefaction and settlement potentials calculated in CLiq for equivalent shaking conditions. This would enable the difference between the two to be accurately defined, and a suitable adjustment applied. Finally, inconsistencies between the Laser-Sizer and Hydrometer should be investigated, as the Laser-Sizer under-estimated the fines content by up to one third of the Hydrometer values.
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Fine grained sediment clean-up in a modern urban environmentVillemure, Marlene January 2013 (has links)
Fine grained sediment deposition in urban environments during natural hazard events can impact critical infrastructure and properties (urban terrain) leading to reduced social and economic function and potentially adverse public health effects. Therefore, clean-up of the sediments is required to minimise impacts and restore social and economic functionality as soon as possible. The strategies employed to manage and coordinate the clean-up significantly influence the speed, cost and quality of the clean-up operation. Additionally, the physical properties of the fine grained sediment affects the clean-up, transport, storage and future usage of the sediment. The goals of the research are to assess the resources, time and cost required for fine grained sediment clean-up in an urban environment following a disaster and to determine how the geotechnical properties of sediment will affect urban clean-up strategies. The thesis focuses on the impact of fine grained sediment (<1 mm) deposition from three liquefaction events during the Canterbury earthquake sequence (2010-2011) on residential suburbs and transport networks in Christchurch. It also presents how geotechnical properties of the material may affect clean-up strategies and methods by presenting geotechnical analysis of tephra material from the North Island of New Zealand. Finally, lessons for disaster response planning and decision making for clean-up of sediment in urban environments are presented.
A series of semi-structured interviews of key stakeholders supported by relevant academic literature and media reports were used to record the clean-up operation coordination and management and to make a preliminary qualification of the Christchurch liquefaction ejecta clean-up (costs breakdown, time, volume, resources, coordination, planning and priorities). Further analysis of the costs and resources involved for better accuracy was required and so the analysis of Christchurch City Council road management database (RAMM) was done. In order to make a transition from general fine sediment clean-up to specific types of fine disaster sediment clean-up, adequate information about the material properties is required as they will define how the material will be handled, transported and stored. Laboratory analysis of young volcanic tephra from the New Zealand’s North Island was performed to identify their geotechnical properties (density, granulometry, plasticity, composition and angle of repose).
The major findings of this research were that emergency planning and the use of the coordinated incident management system (CIMS) system during the emergency were important to facilitate rapid clean-up tasking, management of resources and ultimately recovery from widespread and voluminous liquefaction ejecta deposition in eastern Christchurch. A total estimated cost of approximately $NZ 40 million was calculated for the Christchurch City clean-up following the 2010-2011 Canterbury earthquake sequence with a partial cost of $NZ 12 million for the Southern part of the city, where up to 33% (418 km) of the road network was impacted by liquefaction ejecta and required clearing of the material following the 22 February 2011 earthquake. Over 500,000 tonnes of ejecta has been stockpiled at Burwood landfill for all three liquefaction inducing earthquake events. The average cost per kilometre for the event clean-up was $NZ 5,500/km (4 September 2010), $NZ 11,650/km (22 February 2011) and $NZ 11,185/km (13 June 2011). The duration of clean-up time of residential properties and the road network was approximately two to three months for each of the three liquefaction ejecta events; despite events volumes and spatial distribution of ejecta. Interviews and quantitative analysis of RAMM data revealed that the experience and knowledge gained from the Darfield earthquake (4 September 2010) clean-up increased the efficiency of the following Christchurch earthquake induced liquefaction ejecta clean-up events.
Density, particle size, particle shape, clay content and moisture content, are the important geotechnical properties that need to be considered when planning for a clean-up method that incorporates collection, transport and disposal or storage. The geotechnical properties for the tephra samples were analysed to increase preparedness and reaction response of potentially affected North Island cities from possible product from the active volcanoes in their region. The geotechnical results from this study show that volcanic tephra could be used in road or construction material but the properties would have to be further investigated for a New Zealand context. Using fresh volcanic material in road, building or flood control construction requires good understanding of the material properties and precaution during design and construction to extra care, but if well planned, it can be economically beneficial.
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