of Foraminifera to Decipher the Stratigraphic Architecture of the Mount Messenger Depositional System, Taranaki Basin, New Zealand*

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PS Sub-Millennial Anatomy of Late Miocene Deep-Water Mass-Transport Deposits: Case Studies of the Use of Foraminifera to Decipher the Stratigraphic Architecture of the Mount Messenger Depositional System, Taranaki Basin, New Zealand* Martin P. Crundwell 1 and Malcolm J. Arnot 1 Search and Discovery Article #5119 (29) Posted February 4, 29 *Adapted from poster presentation at AAPG Annual Convention, San Antonio, TX, April 2-23, 28 1 GNS Science, Lower Hutt, New Zealand. (m.crundwell@gns.cri.nz) Abstract The Mount Messenger represents a highly dynamic deep-water system comprising slope to basin floor fan deposits that form stacked 4th to 5th order cycles deposited over timescales of 2-1 kyr. The late Miocene sedimentary patterns reflect a complex history of shelf progradation, tempered by sediment supply and accommodation, and tectonic controls within and adjacent to the basin. The variable stratigraphic and sedimentological character of the system poses problems for petroleum exploration because rapid lateral and vertical variation in facies make it difficult to correlate, date and predict the spatial distribution of intervals containing potential reservoir facies. In this presentation, we outline the application of new high-resolution biostratigraphic data and tools that have been developed by GNS Science to address correlation problems associated with this interval. Extremely high estimated rates of sedimentation are recognised at times within the Mount Messenger succession, based on sub-millennial-scale dating derived from weight-standardised counts of planktic and benthic forams and a non-linear age interpolation method. Intervals of downslope reworking are also recognised using dynamic facies analysis based on minimum paleo data. When applied in combination, the new biostratigraphic tools provide a robust temporal and paleoenvironmental framework that enables the stratigraphic architecture of late Miocene depositional systems to be correlated between wells at a greater level of precision than before. This has shown that reservoir-quality base of slope sands, the primary Mount Messenger exploration play, are confined to overlapping fan-lobes. Copyright AAPG. Serial rights given by author. For all other rights contact author directly.

Sub-millenial anatomy of Late Miocene deep-water mass-transport deposits Case studies of the use of foraminifera to decipher the stratigraphic architecture of the Mount Messenger depositional system, Taranaki Basin, New Zealand Abstract Martin Crundwell and Malcolm Arnot GNS Science, PO Box 3368, Lower Hutt New Zealand m.crundwell@gns.cri.nz The Mount Messenger represents a highly dynamic deep-water system comprising slope to basin floor fan deposits that form stacked 4th to 5th order cycles deposited over time scales of 2-1 kyr. The Late Miocene sedimentary patterns reflect a complex history of shelf progradation, tempered by sediment supply and accommodation, and tectonic controls within and adjacent to the basin. The variable stratigraphic and sedimentological character of the system poses problems for petroleum exploration, because rapid lateral and vertical variation in facies makes it difficult to correlate, date and predict the spatial distribution of intervals containing potential reservoir facies. In this presentation, we outline the application of new high-resolution biostratigraphic data and tools that have been developed by GNS Science to address correlation problems associated with this interval. Extremely high estimated rates of sedimentation are recognised at times within the Mount Messenger succession, based on sub-millennial-scale dating derived from weight-standardised counts of planktic and benthic forams and a non-linear age interpolation method. Intervals of downslope reworking are also recognised using dynamic facies analysis based on minimum paleo data. When applied in combination, the new biostratigraphic tools provide a robust temporal and paleoenvironmental framework that enables the stratigraphic architecture of Late Miocene depositional systems to be correlated between wells at a greater level of precision than previously. This has shown that reservoir-quality basal slope sands, the primary Mount Messenger exploration play, are confined to overlapping fan-lobes.

Introduction Taranaki Basin Taranaki Basin, New Zealand Located along west coast of New Zealand's North Island. 2 About 1, km, principally subsurface and mostly offshore. New Zealand's only economic petroleum producing basin. Discovered reserves 465 mmbbls oil/condensate 647 BCF gas 38MTLPG from total of 2 pools, including 14 producing or producible fields. Sedimentary basin fill Transgressive Late Cretaceous to Early Miocene succession, followed by a regressive succession. Primary source rocks Hydrogen-rich coals and terrestrial carbonaceous mudstones of Late Cretaceous to Eocene age. Primary oil and gas plays Mount Messenger sands: Late Miocene Moki sands: Middle Miocene Tikorangi Limestone: Oligocene Mangahewa and Farewell sands: Late Cretaceous to Eocene Urenui Fm ( Ur) Late Miocene (6.5-8.88 Ma) >5 m thick progradational shelf and upper slope system Mount Messenger Fm ( Mm) Late Miocene (8.88-1.92 Ma) 15 m thick progradational deep-water slope and aggradational basin floor fan system rapid vertical and lateral facies variation oil and gas play Age (Ma) Late Cenozoic chronostratigraphy of Taranaki Basin 1 2 3 Plio- Pleist. Oligocene Miocene South (proximal) Shelf Ur Mm Central North (distal) Slope Slope and basin floor fan Mount Messenger production Kaimiro Field estimated oil reserves 4.5 mmbbls produced 3.2 mmbbls since 1985 gas reserves 29.6 Bcf Ngatoro Field estimated oil reserves 9.4 mmbbls produced 4.7 mmbbls since 1992 gas reserves 23. Bcf Cheal Field no reliable production figures Mount Messenger reservoirs Upside shallow targets: 1-25 m cheap to drill existing infrastructure outcrop analogue Downside small reservoirs poor lateral continuity structural complexity difficult to correlate regionally and locally

Depositional setting Field Area Mount Messenger deep-water clastic system Late Miocene (Tortonian) 3rd-order progradational system (2-3 Ma) Superimposed with 4-5th order cycles (<1 k yr) Complex structural setting: part fold thrust belt, foreland basin and intra-arc basin Slope fan to basin floor fan deposits Relatively small-scale fans (<1 km) Overview In sequence stratigraphic terms, the Mount Messenger and Urenui succession represents a complete lowstand sytems tract, from basin-floor fan to prograding complex. This outwardly reflects rapid basin floor aggradation and slope outbuilding. A consequence of high volumes of sediment supply caused by plateconvergent-related uplift and erosion. Sediment supply Mount Messenger sediments are largely derived from uplift and erosion of Cenozoic rocks of the eastern hinterland and Mezozoic greywackes of the main South Island ranges. Submarine andesite stratovolcanoes in the NW also contributed volcanigenic sediments. NE-SW Coastal cliff transect Basin floor to slope profile Oblique orientation to depositional dip Lateral migration of fans is exaggerated Coastal cliff section Unique field laboratory for studying deep-water clastic sedimentation. Excellent exposure along 5 km of coastline. Oblique 2-D window through Urenui and Mount Messenger deep-water clastic system. Generic facies architecture Urenui sequence: progradational shelf and upper slope facies Mount Messenger sequence: progradational slope fan to aggradational basin-floor fan facies Rocks dip gently southwest at 2-3 and are buried beneath the Taranaki Peninsula at s of 1-25 m. Regional paleoslope and direction of progradation runs northwest.

Subsurface correlation Biostratigraphy Seismic correlation Pukearuhe-1 SW High-resolution biostratigraphy using robustly dated bioevents provides a fully independent and valid test of seismic and well-log correlations, but is often underutilised. NE. Urenui Fm.5 channel In addition to being a valuable correlation tool, high-resolution biostratigraphy provides reliable dating for determining rates of sedimentation and deformation, and other geological processes. Mount Messenger 1. Mohakatino Fm TWT (secs) Manganui 1.5 The acquisition of high-resolution biostratigraphic data is relatively cheap compared to geophysical data. Mesozoic basement 2. Tikorangi Fm 1 2 km Horizontal distance Globigerininta glutinata Well-log correlation Dating SW In the case of the Late Miocene Mount Messenger sequence, high-resolution biostratigraphy can resolve dating to less than 5-thousand years, which is on a scale comparable to seismic resolution. Such dating is important for elucidating Milankovich-scale sedimentary detail and identifying eustatically-forced shifts in facies that are often unresolved with geophysical data. Reliable dating is also important for geohistory analysis. Kaimiro-1 Mangahewa-1 Onaero-1 Urenui-1 Manganui-1 NE Pukearuhe-1 Coastal outcrop Mohakatino Fm Matemateaonga Mount Messenger Urenui? 5 Mount Messenger Subsea (m) Mesozoic Basement 4th-order cycles 1 Oil producing zone in nearby Kaimiro-2 3rd-Order Succession Manganui Mesozoic Basement Prograding slope Slope fan Basin floor fan Sequence boundary SP logs shown in all wells SP log deflection Sand Shale 15 Globigerina bulloides 1 km Horizontal distance

Biostratigraphic correlation Locally age-calibrated bioevents NZ Stage EARLY ZANCLEAN Opoitian Wo 5.28 6 Mount Messenger biostratigraphy Kapitean Tk The Late Miocene Mount Messeneger sequence is up to 15 m thick and is dated 8.88-1.92 Ma. 1st-order GPTS calibration (ODP Site 1123 ) 2nd-order age calibration (DSDP Site 593) High-resolution Matemateaonga n=16 upper lower 39 robustly dated planktonic bioevents have been identified in the Mount Messenger interval; this equates to an average biostratigraphic resolution of about 5 ka. 6.5 MESSINIAN 5 PLIOCENE (Ma) Epoch/Age 4 Ma Low-resolution Urenui n=8 upper 7 The bioevents include planktic foraminiferal and bolboformid appearances, disappearances, acme events, and coiling changes. 8.88 TORTONIAN 9 LATE 8 MIOCENE Tongaporutuan Tt lower 1 High-resolution Mt Messenger n=39 DSDP Site 593 1.92 Planktic foraminifer Dextral proportion Globoconella miotumida Waiauan Sw Abundance 24 SERRAVALLIAN MIDDLE 11 late 25 12 Tukemokihi Coiling Zone () The is robustly dated (9.27-9.31 Ma) and it spans 4, years. Globoconella miotumida The coiling zone has been identified in more than 2 wells in North Taranaki and it is regionally isochronous. interval 1 m isopach intervals 27 Depth (mbsf) LATE MIOCENE The is the youngest of three intervals of dextrally-coiled Globoconella miotumida within the Mount Messenger sequence. 26 28 Tt 29 early MCZ 3 KCZ 31 32 MIDDLE MIOCENE 33 NEW PLYMOUTH Location of new data acquisition 1 scale (km) well data Ea ste rn Tar ana k i B as in marg in 34 Sw.5 proportion.5 proportion 1 interval The interval is reliably identified in most marine environments, except inner neritic facies where there is a paucity of planktic foraminifera. Isopachs on the interval show two primary depocentres along the eastern Taranaki Basin margin. The is up to 63 m thick, which indicates a very high average sedimentation rate (15.8 m/ka). Globoquadrina dehiscens 1

Non-linear age interpolation Foram counts: Pukearuhe-1 Theory 2 Weight standardised counts of foraminifera provide useful information about changes in sedimentation. 4 Where productivity is constant, high foram numbers (i.e. weight standardised counts) indicate low rates of sedimentation, and low foram numbers indicate high rates of sedimentation. Verification When the signatures of planktic and benthic foram numbers are in phase, productivity can be assumed to be constant, and when they are out of phase, productivity must be taken into consideration. 6 Neogloboquadrina mayeri Age models: Pukearuhe-1 Expanded Mount Messenger sequence Expanded 8 Condensing upwards 1 Expanding upwards 12 Condensed ( 53 m thick) 2 14 Top (9.27 Ma) 3 3 m/ka 16 6 9 18 Weight standardised foram counts 4 Foram counts 34 m/ka 5 3 m/ka 6 8.5 m/ka Cycle-1 7 93 m/ka In the lower part of the drilled section where foram numbers are high, decreasing foram numbers suggest the section becomes slightly less condensed uphole. Immediately below the this trend is reversed and the section becomes more condensed. It then becomes highly expanded, especially in the middle and upper parts of the. Sedimentation rate: Pukearuhe-1 8 2 Base (9.31 Ma) 9 9.27 9.28 9.29 9.3 3 9.31 Condensed Age (Ma) Sand-H Sand-G 343 m/ka 4 Sand-F Sand-E Non-linear age model The non-linear age model shows two sedimentary cycles within the, and a very high rate of sedimentation through the lower part of the (93 m/ka), maximum rate 358 m/ka. Cycle-1 Includes four sands: sands A, B, and C within the lower rapidly deposited part of the cycle, and sand D within the upper slightly more condensed part of the cycle. Includes four sands: sands E and F within the lower rapidly deposited part of the cycle, and sands G and H within the slightly more condensed part of the cycle. Zeaglobigerina nepenthes 5 Expanding upwards 6 Condensed Sand-D 358 m/ka Sand-C 7 Expanded 8 Sand-B Sand-A 9 1 2 3 Sedimentation rate (m/ka) 4 Cycle-1

Non-linear age interpolation Onaero-1 Onaero-1 linear and non-linear age models (441 m thick) sedimentation rate 5 5 Top (9.27 Ma) 6 6 6.2 m/ka 9.2 m/ka 8 7.4 m/ka 14 m/ka 9 Cycle-1 1 The 9.31 Ma age of cycle-1 and the very high sedimentation rate, suggest it is a potential correlative of the Tongaporutu Sandstone in the coastal cliff section, 3 km NE of Onaero-1. 887 m/ka 1 Base Base (9.31 Ma) 11 The highest sed rate (887 m/ka) occurs in the lower part of cycle-1 within the lowermost part of the. 8 9 3.6 m/ka The non-linear age model shows three sedimentary cycles within the. 133 m/ka 7 Onaero-1 Cycle-3 7 Turborotalita quinqueloba Top 11 12 12 9.27 9.28 9.29 9.3 9.31 Outcrop photo shown bottom right introduction panel. Age (Ma) Ngatoro-3 Ngatoro-3 sedimentation rate linear and non-linear age models (5 m thick) 11 11 Top (9.27 Ma) Zeaglobigerina woodi Cycle-4 The non-linear age model shows five sedimentary cycles within the. The 9.29 Ma age of cycle-3 and the very high sedimentation rate, suggest it is a potential correlative of the Waikiekie Sandstone in the coastal cliff section, 53 km NE of Ngatoro-3. The 5-cycles are inferred to represent a succession of overlapping slope fan lobes. Top 12 12 Ngatoro-3 The highest sed rate (817 m/ka) occurs in cycle-3 near the middle of the. Cycle-5 13 13 Cycle-3 14 15 8.3 m/ka 15 16 Cycle-1 16 17 17 Base (9.31 Ma) 817 m/ka 14 232 m/ka Base 18 18 9.27 9.28 9.29 Age (Ma) 9.3 9.31 3 6 Sed rate (m/ka) 9

2 4 Paleobathymetry Pukearuhe-1 Lower bathyal >1 m Facies analysis Outlier Sedimentation rate Low High Cycle-1 Paleobathymetry Estimates of paleobathymetry are an essential input in geohistory analysis and modelling of depositional systems. Methodologies 6 8 1 12 Upper bathyal 2-6 m Mid bathyal 6-1 m Common downslope reworking Downslope reworking Low to very low sedimentation rates Depth paleoecology in New Zealand has been based on two different methodologies: 1) The biofacies approach to recognising constrained faunal associations 2) The key taxa approach of determining the upper paleobathymetric limits of selected isobathyal taxa. In the key taxa approach, shown here, the upper paleobathymetric limits of calibrated taxa constrain the minimum of deposition. Marked excursions in the paleobathymetry signature that are shallower than background s identify intervals of downslope reworking. 14 Shelf -2 m 4 8 12 16 Water (m) 2-point moving average: minimum paleobathymetric data Estimated paleobathymetry 2 Oceanicity Pukearuhe-1 Sedimentation rate Low High 4 Paleobathymetry of Pukearuhe-1 water s increase downhole common downslope reworking occurs through the interval where sedimentation rates are very high minor downslope reworking in the lowermost part of the drilled section no shelfal reworking, mostly upper and mid bathyal estimated water at base of drilled Miocene section 174 m Oceanicity 6 8 1 Unfavourable planktonic conditions Sub-oceanic 6-9% Oceanic 9-1% Slope fan deposition Low planktic foraminiferal abundances through the indicate unfavourable turbid conditions and support high rates of sedimentation and slope fan deposition. Very high planktic foraminiferal abundances through the lower part of the drilled section are consistent with very low rates of sedimentation and basin floor fan deposition. 12 14 Neritic -3% Extra-neritic 3-6% Basin floor deposition 2 4 6 8 1 Neogloboquadrina pachyderma Planktonic foraminiferal abundance (%)

Replace image, better tonal balance Tukemokihi Coiling Zone () Summary 1) The is a robustly dated interval of dextrally-coiled Globoconella miotumida, within the Mount Messenger sequence. 2) The spans 4, years, and a sedimentary sequence up to 63 m thick accumulated in that time, along the eastern margin of the Taranaki Basin. Non-linear age models 1) Very high rates of sedimentation within the (3-1 m/ka, reaching 87m/ka) point to high local volumes of sediment supply. 2) Millennial-scale sedimentary cycles with sub-millennial-scale heterogeneity have been identified within the interval of the Late Miocene Mount Messenger sequence. 3) Highly refined dating within the interval enables lateral continuity of sands to be tested independently of seismic and well-log data. 4) Reservoir quality sands within the interval do not always coincide with the most rapid rates of deposition; some occur within the slightly more condensed intervals. 5) Variations in the number of sedimentary cycles between different localities; suggest deposition was associated with small-scale (<1 km) overlapping fan-lobes. 6) The provisional correlation between cycle-1 in the Onaero-1 well and the Tongaporutu Sandstone, 3 km NE of Onaero-1, and the correlation between cycle-3 in Ngatoro-3 and the Waikiekie Sandstone, 53 km NE of Ngatoro-3, suggest some sedimentary cycles may be correlated over ten s of kilometers, especially those that are associated with major glacio-eustatic cycles. Downslope reworking 1) The upper paleobathymetric limits of calibrated isobathyal taxa constrain the minimum of deposition and help identify intervals of downslope reworking, and also the source of reworked sediments. 2) There is a strong correlation between low planktic foraminiferal abundances, high rates of sedimentation, and downslope reworking. Acknowledgements We would like to thank colleagues at GNS Science, especially Peter King and Greg Browne, whose work we called upon in the compilation of this poster. We would also like to thank Austral Pacific and Greymouth Petroleum for their collaboration on the Mount Messenger project.