Uplift rates of marine terraces as a constraint on fault-propagation fold kinematics: Examples from the Hawkswood and Kate anticlines, North Canterbury, New Zealand

Marine terraces on growing fault-propagation folds provide valuable insight into the relationship between fold kinematics and uplift rates, providing a means to distinguish among otherwise non-unique kinematic model solutions. Here, we investigate this relationship at two locations in North Canterbu...

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Bibliographic Details
Published in:Tectonophysics 2018-01, Vol.724-725, p.195-219
Main Authors: Oakley, David O.S., Fisher, Donald M., Gardner, Thomas W., Stewart, Mary Kate
Format: Article
Language:English
Subjects:
Anticlines
Computer simulation
Constraint modelling
Estimates
Fault-propagation folds
Folding
Folds
Geological data
Geological faults
Geological hazards
Geology
Kinematics
Marine terraces
Markov analysis
Markov chains
Monte Carlo simulation
New Zealand
Propagation
Seismic hazard
Slip
Solutions
Statistical methods
Surveys
Terraces
Trishear
Uniqueness
Uplift
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Summary:Marine terraces on growing fault-propagation folds provide valuable insight into the relationship between fold kinematics and uplift rates, providing a means to distinguish among otherwise non-unique kinematic model solutions. Here, we investigate this relationship at two locations in North Canterbury, New Zealand: the Kate anticline and Haumuri Bluff, at the northern end of the Hawkswood anticline. At both locations, we calculate uplift rates of previously dated marine terraces, using DGPS surveys to estimate terrace inner edge elevations. We then use Markov chain Monte Carlo methods to fit fault-propagation fold kinematic models to structural geologic data, and we incorporate marine terrace uplift into the models as an additional constraint. At Haumuri Bluff, we find that marine terraces, when restored to originally horizontal surfaces, can help to eliminate certain trishear models that would fit the geologic data alone. At Kate anticline, we compare uplift rates at different structural positions and find that the spatial pattern of uplift rates is more consistent with trishear than with a parallel-fault propagation fold kink-band model. Finally, we use our model results to compute new estimates for fault slip rates (~1–2m/ka at Kate anticline and 1–4m/ka at Haumuri Bluff) and ages of the folds (~1Ma), which are consistent with previous estimates for the onset of folding in this region. These results are consistent with previous work on the age of onset of folding in this region, provide revised estimates of fault slip rates necessary to understand the seismic hazard posed by these faults, and demonstrate the value of incorporating marine terraces in inverse fold kinematic models as a means to distinguish among non-unique solutions. •Marine terrace uplift rates and fold kinematic models are presented for two sites.•Uplift rates vary both spatially and temporally.•Marine terraces, as originally flat surfaces, constrain trishear kinematic models.•Uplift rates at different structural positions distinguish among kinematic models.•Model results predict fault slip rates of 1–4mm/yr and 1–2mm/yr at the two sites.
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2017.12.021