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  • 1
    Online-Ressource
    Online-Ressource
    Enhanced Surface Imaging of Crustal Deformation : Obtaining Tectonic Force Fields Using GPS Data. (2015)
    Cham :Springer International Publishing AG,
    Details
    Schlagwort(e): Geology. ; Electronic books.
    Materialart: Online-Ressource
    Seiten: 1 online resource (107 pages)
    Ausgabe: 1st ed.
    ISBN: 9783319215785
    Serie: SpringerBriefs in Earth Sciences Series
    URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=3568313
    DDC: 551.1360285
    Sprache: Englisch
    Anmerkung: Intro -- Preface -- Contents -- 1 Introduction -- Abstract -- References -- 2 Introduction to the Vertical Derivatives of Horizontal Stress (VDoHS) Rates -- Abstract -- 2.1 Flat Earth Form of the Force Balance Equations at the Earth's Surface -- 2.2 1-D Expressions -- 2.3 Structure of 2-D Expressions -- 2.4 Spherical Polar Coordinate Form of the Force Balance Equations at the Earth's Surface -- 2.5 Summary and Discussion -- References -- 3 Inversion Methodology -- Abstract -- 3.1 Summary of the Inversion Process -- 3.2 1-D Basis Functions -- 3.3 Interpolation Related Issues and 2-D Basis Functions -- 3.4 Boundary Conditions and Finite Element Solutions for 2-D Problems -- 3.5 Application of the Maximum Entropy Principle -- 3.6 Linking Maximum Entropy to Bayesian Inversion -- 3.7 Obtaining Expected Values for \left\| {{\bf m}} \right\|^{2} and \left\| {\nabla {{\bf m}}} \right\|^{2} -- 3.8 Appraisal of Inversion Solutions -- 3.9 Inclusion of Radial Velocity in the Spherical Case -- 3.10 Summary and Discussion -- References -- 4 1-Dimensional Synthetic Examples -- Abstract -- 4.1 Forward Examples for Strike-Slip and Dip-Slip Faults -- 4.2 Obtaining Fault Characteristics from Strain and VDoHS Rates -- 4.3 Effects of Discrete Sampling Illustrated for a Regular Sample Spacing -- 4.4 Inversions of Randomly Generated Datasets -- 4.5 Effects of Random Noise on Inversion Results -- 4.6 Effect of Near Surface Heterogeneity -- 4.7 Summary and Discussion -- References -- 5 Application to Central South Island, New Zealand -- Abstract -- 5.1 Tectonic Setting and 1-D Inversion Results -- 5.2 Estimation of Alpine Fault Properties -- 5.3 Other Sources of Deformation -- 5.4 Model Appraisal -- 5.5 Summary and Discussion -- References -- 6 2-Dimensional Examples -- Abstract -- 6.1 2-Dimensional Synthetic Examples of Strike-Slip and Dip-Slip Faults and a Mogi Source. , 6.2 2-Dimensional Inversions of Randomly Generated Datasets -- 6.3 2-D Inversion Results -- 6.4 Summary and Discussion -- References -- 7 Concluding Remarks -- Abstract -- References.
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  • 2
    Online-Ressource
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    Enhanced Surface Imaging of Crustal Deformation : Obtaining Tectonic Force Fields Using GPS Data (2015)
    Cham : Springer International Publishing
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    Schlagwort(e): Geography ; Physical geography ; Geology ; Earth Sciences ; Geophysics. ; Natural disasters. ; Mathematical physics. ; Geography ; Physical geography ; Geology ; Geology, Structural ; Imaging systems in geology ; Plate tectonics -- Research ; Faults (Geology) ; Global Positioning System ; Inversion (Geophysics) ; Rock deformation ; Earth (Planet) ; Südinsel ; Rezente Krustenbewegung ; GPS ; Messung ; Seismometrie ; Neuseeland ; Erdbeben ; Neotektonik ; Krustenbewegung ; Deformation ; Deformationsmessung ; Südinsel ; Rezente Krustenbewegung ; GPS ; Messung ; Seismometrie ; Neuseeland ; Erdbeben ; Neotektonik ; Krustenbewegung ; Deformation ; Deformationsmessung
    Beschreibung / Inhaltsverzeichnis: 1. Introduction.- 2. Introduction to the Vertical Derivatives of Horizontal Stress (VDoHS) Rates -- 3. Inversion Methodology -- 4. 1-Dimensional Synthetic Examples -- 5. Application to Central South Island, New Zealand -- 6. 2-Dimensional Examples -- 7. Concluding Remarks.
    Materialart: Online-Ressource
    Seiten: Online-Ressource (X, 99 p. 50 illus., 37 illus. in color, online resource)
    Ausgabe: 1st ed. 2015
    ISBN: 9783319215785
    Serie: SpringerBriefs in Earth Sciences
    URL: https://doi.org/10.1007/978-3-319-21578-5
    URL: http://dx.doi.org/10.1007/978-3-319-21578-5
    URL: https://zbmath.org/?q=an:1327.86002
    DOI: 10.1007/978-3-319-21578-5
    Sprache: Englisch
    Anmerkung: Description based upon print version of record , 1. Introduction.- 2. Introduction to the Vertical Derivatives of Horizontal Stress (VDoHS) Rates3. Inversion Methodology -- 4. 1-Dimensional Synthetic Examples -- 5. Application to Central South Island, New Zealand -- 6. 2-Dimensional Examples -- 7. Concluding Remarks.
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  • 3
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    Observations of Laboratory and Natural Slow Slip Events: Hikurangi Subduction Zone, New Zealand (2021)
    Details
    Publikationsdatum: 2021-07-21
    Beschreibung: Slow slip events (SSEs) are recognized as an important component of plate boundary fault slip, and there is a need for laboratory friction data on natural samples to guide comparisons with natural SSEs. Here, we compile a comprehensive catalog of SSEs observed geodetically at the Hikurangi subduction zone offshore northern New Zealand, and compare it with results of laboratory friction experiments that produce laboratory SSEs under plate tectonic driving rates (5 cm/yr). We use samples from Ocean Drilling Program Site 1124 seaward of the Hikurangi subduction zone to represent the plate boundary that hosts shallow SSEs at Hikurangi. We find that laboratory SSEs exhibit a similar displacement record and range of stress drops as the natural SSEs. Results of velocity step tests, which can be used to evaluate frictional instability based on the critical stiffness criterion, indicate that the slow slip activity at Hikurangi is a form of stably-accelerating slip. Our laboratory SSEs provide an alternative method of quantifying (in)stability by direct measurement of the unloading stiffness during the stress drop. The observed dependence of laboratory SSE parameters on effective normal stress is consistent with critical stiffness theory; however, depth-increasing projections based on laboratory data do not match observations from natural SSEs. These differences are likely related to changing temperature and fault rock composition downdip but also complications related to scaling and/or limited sampling. Scientific drilling recently undertaken at the Hikurangi subduction zone should serve to improve and guide future studies of the role of frictional properties for the occurrence of SSEs.
    Schlagwort(e): 551.8 ; Hikurangi ; slow slip ; subduction zone ; friction ; GPS ; fault
    Sprache: Englisch
    Materialart: article
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  • 4
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    International ocean discovery program expedition 375 preliminary report: Hikurangi subduction margin coring and observatories unlocking the secrets of slow slip through drilling to sample and monitor the forearc and subducting plate, 8 March - 5 May 2018 (2018)
    In:  Integrated Ocean Drilling Program: Preliminary Reports, 375 . UNSPECIFIED, 38 pp.
    Details
    Publikationsdatum: 2020-12-23
    Beschreibung: Slow slip events (SSEs) at the northern Hikurangi subduction margin, New Zealand, are among the best-documented shallow SSEs on Earth. International Ocean Discovery Program Expedition 375 was undertaken to investigate the processes and in situ conditions that underlie subduction zone SSEs at the northern Hikurangi Trough by (1) coring at four sites, including an active fault near the deformation front, the upper plate above the high-slip SSE sourc e region, and the incoming sedimentary succession in the Hikurangi Trough and atop the Tūranganui Knoll Seamount, and (2) installing borehole observatories in an active thrust near the deformation front and in the upper plate overlying the slow slip source region. Logging-while-drilling (LWD) data for this project were acquired as part of Expedition 372 (26 November 2017-4 January 2018; see th e Expedition 372 Preliminary Report for further details on the LWD acquisition program). Northern Hikurangi subduction margin SSEs recur every 1-2 years and thus provide an ideal opportunity to monitor deformation and associated changes in chemical and physical properties throughout the slow slip cycle. Sampling of material from the sedimentary section and oceanic basement of the subducting plate reveals the rock properties, composition, lithology, and structural character of material that is transported downdip into the SSE source region. A recent seafloor geodetic experiment raises the possibility that SSEs at northern Hikurangi may propagate all the way to the trench, indicating that the shallow thrust fault zone targeted during Expedition 375 may also lie in the SSE rupture area. Hence, sampling at this location provides insights into the composition, physical properties, and architecture of a shallow fault that may host slow slip. Expedition 375 (together with the Hikurangi subduction LWD component of Expedition 372) was designed to address three fundamental scientific objectives: (1) characterize the state and composition of the incoming plate and shallow plate boundary fault near the trench, which comprise the protolith and initial conditions for fault zone rock at greater depth and which may itself host shallow slow slip; (2) characterize material properties, thermal regime, and stress conditions in the upper plate above the core of the SSE source region; and (3) install observatories at an active thrust near the deformation front and in the upper plate above the SSE source to measure temporal variations in deformation, temperature, and fluid flow. The observatories will monitor volumetric strain (via pore pressure as a proxy) and the evolution of physical, hydrological, and chemical properties throughout the SSE cycle. Together, the coring, logging, and observatory data will test a suite of hypotheses about the fundamental mechanics and behavior of SSEs and their relationship to great earthquakes along the subduction interface.
    Materialart: Report , NonPeerReviewed
    Format: text
    DOI: 10.14379/iodp.pr.375.2018
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  • 5
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    Slow slip source characterized by lithological and geometric heterogeneity (2020)
    AAAS (American Association for the Advancement of Science)
    Details
    Publikationsdatum: 2023-02-08
    Beschreibung: Slow slip events (SSEs) accommodate a significant proportion of tectonic plate motion at subduction zones, yet little is known about the faults that actually host them. The shallow depth (〈2 km) of well-documented SSEs at the Hikurangi subduction zone offshore New Zealand offers a unique opportunity to link geophysical imaging of the subduction zone with direct access to incoming material that represents the megathrust fault rocks hosting slow slip. Two recent International Ocean Discovery Program Expeditions sampled this incoming material before it is entrained immediately down-dip along the shallow plate interface. Drilling results, tied to regional seismic reflection images, reveal heterogeneous lithologies with highly variable physical properties entering the SSE source region. These observations suggest that SSEs and associated slow earthquake phenomena are promoted by lithological, mechanical, and frictional heterogeneity within the fault zone, enhanced by geometric complexity associated with subduction of rough crust.
    Materialart: Article , PeerReviewed
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  • 6
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    Borehole stress indicators across the Hikurangi Subduction Margin: Preliminary insights from IODP Expedition 372 (2018)
    In:  [Talk] In: AGU Fall Meeting 2018, 10.-14.12.2018, Washington, D.C., USA .
    Details
    Publikationsdatum: 2019-02-15
    Beschreibung: The Hikurangi Subduction Margin was the recent focus of two IODP expeditions seeking to explore the cause and effect of slow slip earthquake generation at this plate boundary. Characterising the stress field across the Hikurangi Subduction Margin is a crucial element of to understanding the relationship between the contemporary in-situ stress state, active and inactive structures along the subduction front, and fluid pressures and the observed spatial variation in subduction behaviour. Existing stress observations rely on earthquake focal mechanisms and limited onshore borehole data from industry wells on the overriding plate. Reported pore pressures within the over-riding plate are often close to vertical stress magnitudes at shallow depths. Variability of in-situ stress orientations occur along strike of the subduction trench, with a subduction trench parallel SHmax in the south transitioning to a plate motion parallel, trench-oblique SHmax further north. This spatially correlates with observed changes in subduction interface coupling and earthquake behaviour. Here we present new stress field orientation data acquired from resistivity image logging carried out in IODP Expedition 372 using the logging while drilling GeoVision Resistivity tool. We report Shmin orientations from borehole breakout observations of N-S at Site U1518 near the deformation front, and NW-SE from Site U1519 within the upper plate. These data represent the first estimates of stress field orientation (from drilling data) in the outer forarc, near the deformation front of the Hikurangi Margin, an area characterised by shallow slow slip.
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  • 7
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    Imaging the Spatiotemporal Evolution of Plate Coupling With Interferometric Radar (InSAR) in the Hikurangi Subduction Zone (2023)
    AGU (American Geophysical Union) | Wiley
    Details
    Publikationsdatum: 2024-02-07
    Beschreibung: The coupling at the interface between tectonic plates is a key geophysical parameter to capture the frictional locking across plate boundaries and provides a means to estimate where tectonic strain is accumulating through time. Here, we use both interferometric radar (InSAR) and Global Navigation Satellite System (GNSS) data to investigate the plate coupling of the Hikurangi subduction zone beneath the North Island of New Zealand, where multiple slow slip cycles are superimposed on the long‐term loading. We estimate the plate coupling across the subduction zone over three multi‐year observational periods targeting different stages of the slow slip cycle. Our results highlight the importance of the observational time period when interpreting coupling maps, emphasizing the temporal variability of plate coupling. Leveraging multiple geodetic data sets, we demonstrate how InSAR provides powerful constraints on the spatial resolution of both plate coupling and slow fault slip, even in a region where a dense GNSS network exists. Plain Language Summary Plate coupling as a concept describes to what degree the boundaries between tectonic plates are locked and building up stress. Such accumulated stress (over hundreds to thousands of years) will eventually be released in earthquakes, and therefore provides important information about the potential for future earthquakes. Our study uses satellite data to investigate how coupling between tectonic plates along the Hikurangi subduction zone (New Zealand's largest and most dangerous plate boundary fault) changes with time. We analyzed Interferometric Synthetic Aperture Radar and Global Navigation Satellite System data to map the areas where the plates are stuck together (coupled) and where they move past each other (uncoupled). We show that plate coupling varies significantly in space over 2, 4, and 10‐year time scales, highlighting the importance of carefully considering the observational time period when interpreting coupling maps. Key Points Integration of high‐resolution displacement maps from radar imagery captures plate coupling at fine scales Estimates of plate coupling depend strongly on the time period over which surface velocities are measured Temporal variations in plate coupling highlight when and where slow slip dominates the slip budget
    Materialart: Article , PeerReviewed
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  • 8
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    Physical conditions and frictional properties in the source region of a slow-slip event (2021)
    Nature Research
    Details
    Publikationsdatum: 2024-02-07
    Beschreibung: Recent geodetic studies have shown that slow-slip events can occur on subduction faults, including their shallow (〈15 km depth) parts where tsunamis are also generated. Although observations of such events are now widespread, the physical conditions promoting shallow slow-slip events remain poorly understood. Here we use full waveform inversion of controlled-source seismic data from the central Hikurangi (New Zealand) subduction margin to constrain the physical conditions in a region hosting slow slip. We find that the subduction fault is characterized by compliant, overpressured and mechanically weak material. We identify sharp lateral variations in pore pressure, which reflect focused fluid flow along thrust faults and have a fundamental influence on the distribution of mechanical properties and frictional stability along the subduction fault. We then use high-resolution data-derived mechanical properties to underpin rate–state friction models of slow slip. These models show that shallow subduction fault rocks must be nearly velocity neutral to generate shallow frictional slow slip. Our results have implications for understanding fault-loading processes and slow transient fault slip along megathrust faults.
    Materialart: Article , PeerReviewed
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  • 9
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    Geodetic Strain Rates for the 2022 Update of the New Zealand National Seismic Hazard Model (2024)
    Seismological Society of America
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    Publikationsdatum: 2024-04-22
    Beschreibung: Geodetic data in plate boundary zones reflect the accrual of tectonic strain and stress, which will ultimately be released in earthquakes, and so they can provide valuable insights into future seismic hazards. To incorporate geodetic measurements of contemporary deformation into the 2022 revision of the New Zealand National Seismic Hazard Model 2022 (NZ NSHM 2022), we derive a range of strain-rate models from published interseismic Global Navigation Satellite Systems velocities for New Zealand. We calculate the uncertainty in strain rate excluding strain from the Taupō rift–Havre trough and Hikurangi subduction zone, which are handled separately, and the corresponding moment rates. A high shear strain rate occurs along the Alpine fault and the North Island dextral fault belt, as well as the eastern coast of the North Island. Dilatation rates are primarily contractional in the South Island and less well constrained in the North Island. Total moment accumulation derived using Kostrov-type summation varies from 0.64 to 2.93×1019 N·m/yr depending on method and parameter choices. To account for both aleatory and epistemic uncertainty in the strain-rate results, we use four different methods for estimating strain rate and calculate various average models and uncertainty metrics. The maximum shear strain rate is similar across all methods, whereas the dilatation rate and overall strain rate style differ more significantly. Each method provides an estimate of its own uncertainty propagated from the data uncertainties, and variability between methods provides an additional estimate of epistemic uncertainty. Epistemic uncertainty in New Zealand tends to be higher than the aleatory uncertainty estimates provided by any single method, and epistemic uncertainty on dilatation rate exceeds the aleatory uncertainty nearly everywhere. These strain-rate models were provided to the NZ NSHM 2022 team and used to develop fault-slip deficit rate models and scaled seismicity rate models.
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  • 10
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    Inverting Geodetic Strain Rates for Slip Deficit Rate in Complex Deforming Zones: An Application to the New Zealand Plate Boundary (2024)
    AGU (American Geophysical Union) | Wiley
    Details
    Publikationsdatum: 2024-05-17
    Beschreibung: The potential for future earthquakes on faults is often inferred from inversions of geodetically derived surface velocities for locking on faults using kinematic models such as block models. This can be challenging in complex deforming zones with many closely spaced faults or where deformation is not readily described with block motions. Furthermore, surface strain rates are more directly related to coupling on faults than surface velocities. We present a methodology for estimating slip deficit rate directly from strain rate and apply it to New Zealand for the purpose of incorporating geodetic data in the 2022 revision of the New Zealand National Seismic Hazard Model. The strain rate inversions imply slightly higher slip deficit rates than the preferred geologic slip rates on sections of the major strike‐slip systems including the Alpine Fault, the Marlborough Fault System and the northern part of the North Island Fault System. Slip deficit rates are significantly lower than even the lowest geologic estimates on some strike‐slip faults in the southern North Island Fault System near Wellington. Over the entire plate boundary, geodetic slip deficit rates are systematically higher than geologic slip rates for faults slipping less than one mm/yr but lower on average for faults with slip rates between about 5 and 25 mm/yr. We show that 70%–80% of the total strain rate field can be attributed to elastic strain due to fault coupling. The remaining 20%–30% shows systematic spatial patterns of strain rate style that is often consistent with local geologic style of faulting. Plain Language Summary The potential for future earthquakes on faults is often inferred from velocities of the ground surface derived from satellite geodesy, but this approach can be challenging in complex deforming zones with many closely spaced faults. We present a new methodology for estimating the rate at which energy is accumulating on faults using measurements of surface strain rates. The method is applied to New Zealand for the purpose of incorporating geodetic data in the 2022 revision of the New Zealand National Seismic Hazard Model. We show that 70%–80% of the total deformation field can be attributed to energy accumulation on known active faults while the source of the remaining 20%–30% remains unknown. Along some of the major faults in New Zealand we find some important differences in rates of energy accumulation from what is expected from geologic data. Estimated rates are significantly lower than even the lowest geologic estimates on some faults in the fault system near highly‐populated Wellington. Key Points We develop a method to invert geodetically derived strain rates for slip deficit rates on faults We find small but systematic differences between slip deficit rates and geologic slip rates About 70%–80% of the surface strain can be attributed to elastic strain due to coupling on faults
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