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Mapping the subsurface Mark Rattenbury Programme Leader, Geological Map of New Zealand GNS Science, Lower Hutt Why do we need to know about the subsurface? We build on it and into it. We grow food and timber in it. We extract resources from it Dangers lurk within it and are recorded by it Photos by D.B. Townsend (Townsend & others 2008) GNS Science Surface outcrop Extrapolation of trends Application of geological rules Surface landform GNS Science GNS Science QMAP: Geological Map of New Zealand • Designed and built around GIS software (ESRI ArcGIS) since 1994 • Pragmatic design based around map production • High-quality printed maps using ArcGIS • National consistency at 1:250,000 • Rich data attributes • 21 separate GIS datasets • Building towards seamless GIS coverage GNS Science The traditional geological map informs about the near-surface Edbrooke 2001 GNS Science Edbrooke 2001, 2006 GNS Science Edbrooke 2006 GNS Science Geological maps re-evaluated and reclassified (a knowledge-based approach using GIS) = Alluvial fan hazard analysis Grindley et al. 2009, Barrell et al. 2009 GNS Science Geological maps reclassified using material property estimates (a knowledge-based approach using GIS) = Regional Earthquake Susceptibility Begg & Mazengarb 1996 @ 1:50k Earthquake shaking potential GNS Science Geological maps for gauging liquefaction susceptibility Liquefaction potential 87% of September 2010 earthquake liquefaction occurrences were in modelled VERY HIGH to HIGH susceptibility zones Low Medium High Very high Pre Canterbury earthquake liquefaction susceptibility modelling based on interpretation of geological map unit description GNS Science But geology is 3D and paper maps don’t do 3D well Kermode 1992 Auckland 1:50k GNS Science Cox & Barrell (2007) Rattenbury & others (1998) Swapping 2D axes 2½D drapes on DTMs GNS Science 3D volumes in GIS 0 conventional map view -5 -10 multiple Z values for single X,Y -15 -20 -25 -30 -35 consider a buried sphere (with its top eroded away) -40 Contoured depth to lower surface -20 -25 -15 -15 Contoured depth to upper surface Contoured thickness (isopach) -10 5 -5 0 10 15 20 25 30 -30 GNS Science A new era for geological maps Blend conventional lithostratigraphic mapping philosophy and geological principles with new datasets and tools: • 3D geological modelling software visualisation • Drill hole data mining • LiDAR surface analysis • Ambient noise and passive seismic analysis • Cone penetrometer test analysis Modelled greywacke basement underlying the Taupo Volcanic Zone (Alvarez & others) Modelled geological units in Wellington CBD using GSI3D software • Ground-penetrating radar imaging • Aeromagnetic data GNS Science 3D geological modelling software Hutt Valley “It’s our Fault” project using GSI3D modelling software, Boon et al. 2010 GNS Science Drill hole data (we need them!) Leapfrog 3D modelling software GSI3D modelling software GNS Science Lidar topography for geomorphological mapping Relict geomorphology visible through human modification What does it tell us about Christchurch geology? Surface extent of the Springston Formation Surface extent of the Christchurch Formation After Begg & Jones in prep. GNS Science Cone Penetration Testing (CPT) data Measuring geotechnical property proxies Photo: http://www.rdcl.co.nz “Ic” – the soil behavior type index N60 – relative density with water = liquefaction susceptibility Christchurch urban geological mapping after Begg & Jones in prep. using Leapfrog 3D modelling software GNS Science Sinosteel Australia Pty Ltd aeromagnetic data (courtesy of Dr J. Meyers) and QMAP Waikato geology after Edbrooke (2005) lava flows are well delineated on the flanks of Pirongia volcano outcropping Murihiku Supergroup strata have well defined magnetic character… …that is still visible under Oligocene Te Kuiti Group sedimentary rock cover up to 300 m thick The Junction Magnetic Anomaly is the magnetic expression of the buried Dun Mountain Ultramafic Group peridotite rocks GNS Science Extract from Forsyth, Barrell & Jongens 2008 New geological maps of Christchurch GNS Science Geology after Forsyth, Barrell & Jongens 2008 ECAN Drillhole Database GNS Science Christchurch urban geological mapping after Begg & Jones in prep. using Leapfrog 3D modelling software GNS Science Christchurch urban geological mapping after Begg & Jones in prep. using Leapfrog 3D modelling software GNS Science 3D geological modelling While 3D geological modelling software is improving rapidly, there are serious technical challenges around: Hardware demands Software complexity Lack of standards and interoperability Handling of geological faults (discontinuities) Quantifying uncertainty of the interpretation Excellent for conveying a geologist’s understanding of 3D subsurface geometries New era in mapping out geotechnical ground classification GNS Science 3D, GIS and local government GIS data can be imported and input into models Drillhole and other geotechnical data (commonly held by councils) provide vital constraints on subsurface interpretation 3D models can be imported via into GIS component surfaces or 2D derivatives e.g. depth slices, depth to surface top/base and isopachs 2D-based GIS will continue to be a vital tool at GNS Science for managing, analysing and presenting geological data www.gns.cri.nz GNS Science
