Proceedings of the
International Ocean Discovery Program
Volume 372B/375
Hikurangi Subduction Margin Coring, Logging, and Observatories
Expedition 372B/375 of the R/V JOIDES Resolution
Timaru, New Zealand, to Auckland, New Zealand
Sites U1518–U1520 and U1526
8 March–5 May 2018
Volume authorship
Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists
Published by
International Ocean Discovery Program
Publisher’s notes
This publication was prepared by the JOIDES Resolution Science Operator (JRSO) at Texas A&M University (TAMU) as an account of work performed under the International Ocean Discovery Program (IODP). Funding for IODP is provided by the following international partners:
- National Science Foundation (NSF), United States
- Ministry of Education, Culture, Sports, Science and Technology (MEXT), Japan
- European Consortium for Ocean Research Drilling (ECORD)
- Ministry of Science and Technology (MOST), People’s Republic of China
- Korea Institute of Geoscience and Mineral Resources (KIGAM)
- Australia-New Zealand IODP Consortium (ANZIC)
- Ministry of Earth Sciences (MoES), India
- Coordination for Improvement of Higher Education Personnel (CAPES), Brazil
Any opinions, findings, and conclusions or recommendations expressed in this publication are those of the author(s) and do not necessarily reflect the views of the participating agencies, TAMU, or Texas A&M Research Foundation.
The bulk of the shipboard-collected core data from this expedition is accessible at http://iodp.tamu.edu/database/index.html. If you cannot access this site or need additional data, please contact Data Librarian, International Ocean Discovery Program JOIDES Resolution Science Operator, Texas A&M University, 1000 Discovery Drive, College Station TX 77845-9547, USA. Tel: (979) 845-8495; Fax: (979) 458-1617; Email: database@iodp.tamu.edu.
A complete set of the logging data collected during the expedition is available at http://mlp.ldeo.columbia.edu/logdb/scientific_ocean_drilling. If you have problems downloading the data, wish to receive additional logging data, or have questions regarding the data, please contact Database Administrator, Borehole Research Group, Lamont-Doherty Earth Observatory of Columbia University, PO Box 1000, 61 Route 9W, Palisades NY 10964, USA. Tel: (845) 365-8343; Fax: (845) 365-3182; Email: logdb@ldeo.columbia.edu.
Supplemental data were provided by the authors and may not conform to IODP publication formats.
JRSO expedition photos are the property of IODP and are public access.
Some core photographs have been tonally enhanced to better illustrate particular features of interest. High-resolution images are available upon request.
Cover photograph shows wellhead of ACORK/CORK-II nested observatory deployed at Site U1518. The CORK was named “Te Matakite,” which means “to see into the future” in Māori. Photo credit: Demian Saffer and IODP JRSO.
Copyright
Except where otherwise noted, this work is licensed under the Creative Commons Attribution 4.0 International (CC BY 4.0) license (https://creativecommons.org/licenses/by/4.0/). Unrestricted use, distribution, and reproduction are permitted, provided the original author and source are credited.
Examples of how to cite this volume or part of this volume are available at http://publications.iodp.org/proceedings/372B_375/372B375title.html#bib.
ISSN
World Wide Web: 2377-3189
Volume DOI
https://doi.org/10.14379/iodp.proc.372B375.2019
Publication date
5 May 2019
Contents
Expedition reports
Chapters
Expedition 372B/375 summary
D.M. Saffer et al.
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Expedition 372B/375 methods
L.M. Wallace et al.
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Site U1518
D.M. Saffer et al.
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Site U1519
P.M. Barnes et al.
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Site U1520
P.M. Barnes et al.
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Site U1526
L.M. Wallace et al.
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Core descriptions
Visual core descriptions (VCDs) are presented in PDF files for each site. Smear slides and/or thin sections are presented in PDF and/or CSV files for each site and/or hole (CSV files are available in the CORES directory). The entire set of core images in PDF is available in the IMAGES directory.
Site U1518
Visual core descriptions · Smear slides · Thin sections
Site U1519
Visual core descriptions · Smear slides
Site U1520
Visual core descriptions · Smear slides · Thin sections
Site U1526
Visual core descriptions · Smear slides · Thin sections
Supplementary material
Supplementary material for the Volume 372B/375 expedition reports includes DESClogik workbooks, layer thickness data, and structure calculations in Microsoft Excel format, structure spreadsheet notes in Microsoft Word format, and smear slide log sheets and handwritten VCDs in PDF. A full list of directories can be found in SUPP_MAT in the volume zip folder or on the Supplementary material for Volume 372B/375 expedition reports web page.
Expedition research results
Data reports
Data report: reconnaissance of bulk sediment composition and clay mineral assemblages: inputs to the Hikurangi subduction system
Michael B. Underwood
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Updates
Data report: 87Sr/86Sr in pore fluids from IODP Expeditions 372 and 375, Hikurangi margin
Coby Ayres, Marta E. Torres, Brian Haley, and Min Luo
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Data report: standard mineral mixtures, normalization factors, and determination of error for quantitative X-ray diffraction analyses of bulk powders and clay-sized mineral assemblages
Michael B. Underwood, Nicolette Lawler, and Kelsey McNamara
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Data report: permeability and grain size of sediments, IODP Expeditions 372 and 375
Elizabeth J. Screaton, Cora Summerfield, John M. Jaeger, and Jonathan Whipple
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Data report: clay mineral assemblages within trench-floor and accreted trench-floor deposits, IODP Expedition 372B/375 Sites U1518 and U1520, offshore New Zealand
Michael B. Underwood
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Data report: clay mineral assemblages within biocalcareous and volcaniclastic inputs to the Hikurangi subduction zone, IODP Expedition 372B/375 Sites U1520 and U1526, offshore New Zealand
Michael B. Underwood
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Data report: early Late Cretaceous radiolarians from IODP Site U1520 (Expedition 375, Hikurangi subduction margin)
Christopher J. Hollis
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Data report: clay mineral assemblages within Hikurangi trench-slope deposits, IODP Expedition 375 Site U1519, offshore New Zealand
Michael B. Underwood
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Data report: marine tephra compositions in proximal and distal drill cores, IODP Expeditions 375, 372, and 329, ODP Leg 181, and DSDP Leg 90, offshore New Zealand, Southwest Pacific
Katharina Pank, Steffen Kutterolf, Jenni L. Hopkins, Kuo-Lung Wang, and Hao-Yang Lee
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Drilling location maps
A site map showing the drilling locations for this expedition and maps showing the drilling locations of all International Ocean Discovery Program (IODP) expeditions, produced using QGIS (http://www.qgis.org), and all Integrated Ocean Drilling Program, Ocean Drilling Program (ODP), and Deep Sea Drilling Project (DSDP) expeditions, produced using Generic Mapping Tools (GMT) of Paul Wessel and Walter H.F. Smith (http://gmt.soest.hawaii.edu), are available in PDF.
IODP Expedition 372B/375 site map
IODP map (Expeditions 349–357, 359–372, 374–375, and 380–381)
Integrated Ocean Drilling Program map (Expeditions 301–348)
ODP map (Legs 100–210)
DSDP map (Legs 1–96)
Acknowledgments
The success of International Ocean Discover Program (IODP) Expeditions 372 and 375 hinged on the dedication, support, and professionalism of the staff and crew aboard the R/V JOIDES Resolution and the JOIDES Resolution Science Operator (JRSO) technical staff. We acknowledge their pivotal contributions in accomplishing the objectives of the Hikurangi margin drilling program. They ensured that operations went smoothly with very few major issues, and when issues did arise, they addressed them quickly. This was key to achieving nearly 100% of our operational targets. We also acknowledge support from many other IODP staff before, during, and after the expedition, particularly in planning operations and observatory installations.
Because of the complex and varied objectives of this drilling program, both expeditions involved multiple years of planning with heavy involvement from many IODP staff, most notably Katerina Petronotis, Kevin Grigar, Bill Rhinehart, John van Hyfte, Mike Storms, and Steve Midgely. We also gratefully acknowledge Hans Jannasch, Earl Davis, Tom Pettigrew, and Keir Becker for sharing their extensive knowledge during the design and planning phases of the observatories and Earl and Hans for constructing, designing, and testing some of the components.
We are also grateful to the United States National Science Foundation (NSF) for funding support of the CORK observatories and for supporting the planning, design, and fabrication efforts well in advance of drilling. This lead time was critical to the success of the expeditions.
We thank Dan Bassett, Greg Foothead, and the captain and crew of the R/V Tangaroa for facilitating delivery of some observatory components to JOIDES Resolution at sea during Expedition 375.
The IODP expeditions at the Hikurangi margin were the culmination of decades of a diverse array of surveys and research on the offshore Hikurangi margin and the slip behavior that occurs there. In particular, we thank the GeoNet project (https://www.geonet.org.nz; funded by the New Zealand Earthquake Commission and Land Information New Zealand), which operates the continuous GPS and seismic monitoring network that enabled the discovery of shallow slow slip events at the northern Hikurangi margin, thus motivating these expeditions. The tectonic and geological framework of the drilling transect for Expeditions 372 and 375 was underpinned by numerous seismic imaging and multibeam bathymetric expeditions led by scientists from New Zealand, the United States, and Europe. In particular, we gratefully acknowledge Phil Barnes, Rupert Sutherland, Stuart Henrys, Dan Barker, Joshu Mountjoy, Sebastian Krastel, Rob Harris, Anne Trehu, Rebecca Bell, Melissa Gray, Joanna Morgan, Andrea Plaza-Faverola, Dan Bassett, Steve Wilcox, John Mitchell, and Susi Woelz for their various contributions to seismic and bathymetric acquisition, processing, and/or interpretations of these data sets that provided a framework for the drilling transect and were critical for drill site characterization and safety evaluation. We are grateful to the funding agencies that supported the acquisition of site survey and regional geophysical and bathymetric data, including the New Zealand Ministry of Business, Innovation, and Employment (MBIE), New Zealand Ocean Survey 20/20 program, National Institute of Water & Atmospheric Research (NIWA), GNS Science, German Science Foundation, and NSF.
The IODP proposals that formed the basis for Expeditions 372 and 375 emerged from a series of workshops and meetings that involved a dedicated proponent group who were key contributors to the proposals, and members of the drilling proponent team provided continued input and guidance throughout the planning and implementation of the expeditions. We acknowledge the New Zealand MBIE, U.S. Science Support Program, New Zealand Earthquake Commission, and NSF for support of these workshops.
We also thank Stuart Henrys for his help in assembling materials for the IODP Environmental Protection and Safety Panel (EPSP) and for providing advice to Mitch Malone, who successfully dealt with the New Zealand environmental protection regulations and clearance requirements that were needed to undertake the drilling expedition.
Finally, we are grateful to IODP and the JOIDES Resolution Facility Board for supporting this complex project. We hope that it will help further build on the extensive legacy of IODP in illuminating fundamental and societally relevant processes that shape our planet.
Foreword
The International Ocean Discovery Program (IODP) represents the latest incarnation of almost five decades of scientific ocean drilling excellence and is generally accepted as the most successful international collaboration in the history of the Earth sciences. IODP builds seamlessly on the accomplishments of previous phases: the Deep Sea Drilling Project, Ocean Drilling Program, and Integrated Ocean Drilling Program. The 2013–2023 IODP Science Plan (Illuminating Earth’s Past, Present, and Future) defines four themes and thirteen challenges for this decade of scientific ocean drilling that are both of fundamental importance in understanding how the Earth works and of significant relevance to society as the Earth changes, at least in part in response to anthropogenic forcing. This phase of IODP represents a renewed level of international collaboration in bringing diverse drilling platforms and strategies to increasing our understanding of climate and ocean change, the deep biosphere and evolution of ecosystems, connections between Earth’s deep processes and surface manifestations, and geologically induced hazards on human timeframes.
The Proceedings of the International Ocean Discovery Program presents the scientific and engineering results of IODP drilling projects, expedition by expedition. As in the preceding Integrated Ocean Drilling Program, expeditions in the new IODP are conducted by three implementing organizations, each providing a different drilling capability. These are the US Implementing Organization (USIO; through September 2014) and the JOIDES Resolution Science Operator (JRSO; as of October 2014), providing the leased commercial vessel JOIDES Resolution for riserless drilling operations; JAMSTEC’s Center for Deep Earth Exploration (CDEX), providing the drillship Chikyu for riser and occasional riserless operations; and the European Consortium for Ocean Research Drilling (ECORD) Science Operator (ESO), providing “mission-specific” platforms (MSPs) for expeditions that extend the IODP operational range where neither drillship is suitable, for example, in polar environments and in shallow waters. Scheduling decisions for each capability are made by three independent Facility Boards, each of which includes scientists, operators, and platform funding partners: the JOIDES Resolution Facility Board (JRFB), Chikyu IODP Board (CIB), and ECORD Facility Board (EFB). At the beginning of the new IODP, the three Facility Boards agreed to utilize Publication Services at the USIO and now the JRSO for production of all expedition Proceedings volumes and reports.
The new IODP differs from prior scientific ocean drilling programs in that it has neither a central management organization nor commingled funding for program-wide activities. Yet this phase of IODP retains a fundamental integrative structural element: a “bottom-up” evaluation of all proposals for drilling expeditions by a single advisory structure composed of scientists representing all international program partners. International scientists may submit drilling proposals to the Science Support Office; all submitted proposals are then evaluated by a Science Evaluation Panel in the context of the Science Plan.
The new IODP also has a second internationally integrative level for high-level discussion and consensus-building: the IODP Forum. The Forum is charged with assessing program-wide progress toward achieving the Science Plan. At present, IODP involves 26 international financial partners, including the United States, Japan, an Australia/New Zealand consortium (ANZIC), Brazil, China, India, South Korea, and the eighteen members of ECORD (Austria, Belgium, Canada, Denmark, Finland, France, Germany, Ireland, Israel, Italy, the Netherlands, Norway, Poland, Portugal, Spain, Sweden, Switzerland, and the United Kingdom). This enhanced membership in the new IODP represents a remarkable level of international collaboration that remains one of the greatest ongoing strengths of scientific ocean drilling.
James A. Austin Jr.
Chair, IODP Forum
Reviewers for this volume
Julie Christin Belo
Stephen Hillier
Christopher J. Hollis
Katherine L. Maier
Alan Orpin
Barbara Teichert
International Ocean Discovery Program
JOIDES Resolution Science Operator
Website: http://iodp.tamu.edu
IODP JRSO
International Ocean Discovery Program
Texas A&M University
1000 Discovery Drive
College Station TX 77845-9547
USA
Tel: (979) 845-2673; Fax: (979) 845-4857
Email: information@iodp.tamu.edu
IODP JRSO Curation and Laboratories
IODP Gulf Coast Repository (GCR)
Texas A&M University
1000 Discovery Drive
College Station TX 77845-9547
USA
Tel: (979) 845-8490; Fax: (979) 845-1303
Email: rumford@iodp.tamu.edu
European Consortium for Ocean Research Drilling, Science Operator (ESO)
Website: http://www.ecord.org
IODP ESO Coordinator: Science, Logistics, and Operations
British Geological Survey
The Lyell Centre
Research Avenue South
Edinburgh EH14 4AP
United Kingdom
Tel: (44) 131-667-1000; Fax: (44) 131-668-4140
Email: eso@bgs.ac.uk
IODP ESO Petrophysics
European Petrophysics Consortium
Department of Geology
University of Leicester
Leicester LE1 7RH
United Kingdom
Tel: (44) 116-252-3611; Fax: (44) 116-252-3918
Email: sjd27@leicester.ac.uk
IODP ESO Curation and Laboratories
IODP Bremen Core Repository (BCR)
Center for Marine Environmental Sciences (MARUM)
University of Bremen
Leobener Strasse
28359 Bremen
Germany
Tel: (49) 421-218-65560; Fax: (49) 421-218-98-65560
Email: bcr@marum.de
Japan Agency for Marine-Earth Science and Technology (JAMSTEC)
Website: http://www.jamstec.go.jp/chikyu/e
IODP Japan Science Operator
Center for Deep Earth Exploration (CDEX)
Japan Agency for Marine-Earth Science and Technology
Yokohama Institute for Earth Sciences
3175-25 Showa-machi
Kanazawa-ku, Yokohama
Kanagawa 236-0001
Japan
Tel: (81) 45-778-5643; Fax: (81) 45-778-5704
Email: cdex@jamstec.go.jp
IODP Japan Curation and Laboratories
IODP Kochi Institute for Core Sample Research (KCC)
Japan Agency for Marine-Earth Science and Technology
200 Monobe Otsu
3175-25 Showa-machi
Nankoku City, Kochi 783-8502
Japan
Tel: (81) 88-864-6705; Fax: (81) 88-878-2192
Email: kcc.contact@jamstec.go.jp
Expedition 372B/375 participants*
Expedition 372 scientists
Ingo A. Pecher
Co-Chief Scientist
School of Environmental and Marine Sciences
University of Auckland
New Zealand
Philip M. Barnes
Co-Chief Scientist
Ocean Geology
National Institute of Water and Atmospheric Research (NIWA)
New Zealand
Leah J. LeVay
Expedition Project Manager/Staff Scientist
International Ocean Discovery Program
Texas A&M University
USA
Sylvain M. Bourlange
Physical Properties Specialist
Ecole Nationale Supérieure de Géologie-Laboratoire geoRessources
Université de Lorraine
France
sylvain.bourlange@univ-lorraine.fr
Morgane M.Y. Brunet
Sedimentologist
MARUM-Center for Marine Environmental Sciences
University of Bremen
Germany
Present affiliation (1 January 2019):
University of Rennes 1
France
Sebastian Cardona
Sedimentologist
Department of Geology and Geological Engineering
Colorado School of Mines
USA
Michael B. Clennell
Physical Properties Specialist/Downhole Measurements
Energy
CSIRO
Australia
Ann E. Cook
Physical Properties Specialist/Downhole Measurements
School of Earth Sciences
Ohio State University
USA
Brandon Dugan
Physical Properties Specialist/Downhole Measurements
Department of Geophysics
Colorado School of Mines
USA
Judith Elger
Physical Properties Specialist/Downhole Measurements
Helmholtz Centre for Ocean Research Kiel
Christian-Albrechts-Universitat zu Kiel (IFM)
Germany
Davide Gamboa
Physical Properties Specialist/Downhole Measurements
British Geological Survey-Wales
United Kingdom
Aggeliki Georgiopoulou
Sedimentologist
UCD School of Earth Sciences
University College Dublin
Ireland
Present affiliation (1 February 2019):
School of Environment and Technology
University of Brighton
United Kingdom
A.Georgiopoulou@brighton.ac.uk
Shuoshuo Han
Physical Properties Specialist/Downhole Measurements
Institute for Geophysics
The University of Texas at Austin
USA
Katja U. Heeschen
Organic Geochemist/Pressure Coring Specialist
GFZ German Research Centre for Geosciences
Germany
Gaowei Hu
Physical Properties Specialist
Gas Hydrate Department
Qingdao Institute of Marine Geology
China
Gil Young Kim
Physical Properties Specialist/Downhole Measurements
Marine Geology and Exploration Center
Korea Institute of Geoscience & Mineral Resources (KIGAM)
Republic of Korea
Hiroaki Koge
Physical Properties Specialist/Downhole Measurements
Graduate School of Frontier Sciences/Atmosphere and Ocean Research Institute
University of Tokyo
Japan
Present affiliation (18 April 2019):
Marine Geology Research Group
Geological Survey of Japan
National Institute of Advanced Industrial Science and Technology (AIST)
Japan
Karina S. Machado
Organic Geochemist
Production Engineering Department
Federal University of Paraná
Brazil
David D. McNamara
Physical Properties Specialist/Downhole Measurements
Earth and Ocean Sciences
School of Natural Sciences
National University of Ireland, Galway
Ireland
Present affiliation (27 June 2019):
Department of Earth, Ocean, and Environmental Sciences
University of Liverpool
United Kingdom
Gregory F. Moore
Physical Properties Specialist/Downhole Measurements
Department of Geology and Geophysics/SOEST
University of Hawaii at Manoa
USA
Joshu J. Mountjoy
Sedimentologist/Structural Geologist/New Zealand Observer
National Institute of Water and Atmospheric Research (NIWA)
New Zealand
Michael A. Nole
Physical Properties Specialist
Hildebrand Department of Petroleum and Geosystems Engineering
University of Texas at Austin
USA
Present affiliation (1 July 2018):
Applied Systems Analysis and Research
Sandia National Laboratories
USA
Satoko Owari
Inorganic Geochemist
Department of Earth Sciences
Chiba University
Japan
Present affiliation (2 April 2019):
School of Marine Resources and Environment
Tokyo University of Marine Science and Technology
Japan
Matteo Paganoni
Physical Properties Specialist/Downhole Measurements
Department of Earth Sciences
University of Oxford
United Kingdom
Present affiliation (1 July 2018):
Shell Global Solutions International, B.V.
Netherlands
Paula S. Rose
Inorganic Geochemist
Physical and Environmental Sciences
Texas A&M University-Corpus Christi
USA
Elizabeth J. Screaton
Physical Properties Specialist/Downhole Measurements
Department of Geological Sciences
University of Florida
USA
Uma Shankar
Physical Properties Specialist/Downhole Measurements
Department of Geophysics
Institute of Science
Banaras Hindu University
India
Marta E. Torres
Inorganic Geochemist
College of Earth, Ocean and Atmospheric Sciences
Oregon State University
USA
Xiujuan Wang
Physical Properties Specialist/Downhole Measurements
Key Laboratory of Marine Geology and Environment
Institute of Oceanology, Chinese Academy of Sciences
China
Hung-Yu Wu
Physical Properties Specialist/Downhole Measurements
Japan Agency for Marine-Earth Science and Technology
Japan
Expedition 372 education and outreach
Stephanie M. Sharuga
Education Officer
National Oceanic and Atmospheric Administration (NOAA)
USA
Erin K. Todd
Education Officer
Department of Geology
University of Otago
New Zealand
Expedition 375 scientists
Demian M. Saffer
Co-Chief Scientist
Department of Geosciences
The Pennsylvania State University
USA
Present affiliation (1 January 2020):
University of Texas Institute for Geophysics (UTIG) and Department of Geological Sciences
University of Texas
USA
Laura M. Wallace
Co-Chief Scientist
Tectonophysics Department
GNS Science
New Zealand
Katerina E. Petronotis
Expedition Project Manager/Staff Scientist
International Ocean Discovery Program
Texas A&M University
USA
Philip M. Barnes
Core-Log-Seismic Integration Specialist
Ocean Geology
National Institute of Water and Atmospheric Research (NIWA)
New Zealand
Rebecca E. Bell
Core-Log-Seismic Integration Specialist
Geology and Geophysics
Imperial College London
United Kingdom
Martin P. Crundwell
Micropaleontologist (foraminifers)/Observer
Paleontology and Environmental Change Section
GNS Science
New Zealand
Christie H. Engelmann de Oliveira
Sedimentologist
Programa de Pós-Graduação em Geologia
Universidade do Vale do Rio dos Sinos
Brazil
Ake Fagereng
Structural Geologist
School of Earth and Ocean Sciences
Cardiff University
United Kingdom
Patrick M. Fulton
Petrophysics (downhole measurements)/Observatory Specialist
Department of Geology and Geophysics
Texas A&M University
USA
Present affiliation (1 January 2019):
Department of Earth and Atmospheric Sciences
Cornell University
USA
Annika Greve
Paleomagnetist
R&D Center for Ocean Drilling Science (ODS)
Japan Agency for Marine-Earth Science and Technology (JAMSTEC)
Japan
Present affiliation (11 October 2019):
Paleomagnetic Laboratory, Fort Hoofddijik
Department of Earth Sciences
Utrecht University
The Netherlands
Petrophysics (physical properties/downhole measurements) Specialist
College of Earth, Ocean and Atmospheric Sciences
Oregon State University
USA
Yoshitaka Hashimoto
Sedimentologist
Department of Natural Environmental Science
Kochi University
Japan
Andre Hüpers
Inorganic Geochemist
MARUM
University of Bremen
Germany
Matt J. Ikari
Petrophysics (physical properties) Specialist
MARUM
University of Bremen
Germany
Yoshihiro Ito
Petrophysics (physical properties) Specialist
Disaster Prevention Research Institute
Kyoto University
Japan
ito.yoshihiro.4w@kyoto-u.ac.jp
Hiroko Kitajima
Petrophysics (physical properties) Specialist
Department of Geology and Geophysics
Texas A&M University
USA
Steffen Kutterolf
Sedimentologist
Helmholtz Centre for Ocean Research Kiel
Germany
Hikweon Lee
Petrophysics (physical properties) Specialist
Climate Change Mitigation and Sustainability
Korea Institute of Geoscience and Mineral Resources (KIGAM)
Republic of Korea
Xuesen Li
Paleomagnetist
College of Earth Science
Guilin University of Technology
China
Min Luo
Inorganic Geochemist
Hadal Science and Technology Research Center
College of Marine Sciences
Shanghai Ocean University
China
Pierre R. Malie
Organic Geochemist
Geosciences Montpellier Laboratory
Université Montpellier
France
Francesca Meneghini
Sedimentologist
Dipartimento di Scienze della Terra
Università degli Studi di Pisa
Italy
Julia K. Morgan
Structural Geologist
Department of Earth Science
Rice University
USA
Atsushi Noda
Sedimentologist
Research Institute of Geology and Geoinformation
National Institute of Advanced Industrial Science and Technology (AIST)
Geological Survey of Japan
Japan
Hannah S. Rabinowitz
Sedimentologist
Lamont-Doherty Earth Observatory
Columbia University
USA
Present affiliation (1 June 2018):
Department of Earth, Environmental, and Planetary Sciences
Brown University
USA
Heather M. Savage
Structural Geologist
Lamont-Doherty Earth Observatory
Columbia University
USA
Present affiliation (1 July 2019):
Earth and Marine Sciences Building
University of California
USA
Claire L. Shepherd
Micropaleontologist (nannofossils)
Paleontology and Environmental Change Section
GNS Science
New Zealand
Srisharan Shreedharan
Petrophysics (downhole measurements) Specialist
Department of Geosciences
The Pennsylvania State University
USA
Evan A. Solomon
Inorganic Geochemist/Observatory Specialist
School of Oceanography
University of Washington
USA
Michael B. Underwood
Sedimentologist
Department of Earth and Environmental Science
New Mexico Institute of Mining and Technology
USA
Maomao Wang
Structural Geologist
College of Oceanography
Hohai University
China
Adam D. Woodhouse
Micropaleontologist (foraminifers)
School of Earth and Environment
University of Leeds
United Kingdom
Present affiliation (1 September 2023):
School of Earth Sciences
University of Bristol
United Kingdom
Expedition 375 education and outreach
Thanos A. Fatouros
Outreach Officer
USA
Aliki Weststrate
Outreach Officer
New Zealand
*Affiliations at time of expedition, except where updated by participants.Operational and technical staff
Siem Offshore AS officials
Jacob C. Robinson
Master of the Drilling Vessel
Mark Robinson
Drilling Supervisor
JRSO shipboard personnel and technical representatives
Expedition 372
Robert Aduddell
Engineer
Susan Boehm
Thin Section Laboratory
Inva Braha
Curatorial Specialist
Ty Cobb
Physical Properties Laboratory
Lisa Crowder
Assistant Laboratory Officer
Aaron de Loach
Core Laboratory
Lachlan Douglass
LWD Engineer
Keith Dupuis
Underway Geophysics Laboratory/Downhole Tools Laboratory
David Fackler
Applications Developer
Timothy Fulton
Senior Imaging Specialist
Clayton Furman
Logging Engineer
Randy Gjesvold
Marine Instrumentation Specialist
Kevin Grigar
Operations Superintendent
Sandra Herrmann
Assistant Laboratory Officer
Michael Hodge
Marine Computer Specialist
Jon Howell
Applications Developer
Minh Huynh
Marine Computer Specialist
Rhonda Kappler
Publications Specialist
Nicolette Lawler
X-Ray Laboratory
Aaron Mechler
Chemistry Laboratory
Mike Meiring
Engineer
William Mills
Laboratory Officer
Beth Novak
Paleomagnetism Laboratory
David Pedulla
LWD Engineer
Garrick Van Rensburg
Marine Instrumentation Specialist
Liam Warda
Expedition 375
X-Ray Laboratory
Lisa Brandt
Chemistry Laboratory
Ty Cobb
Physical Properties Laboratory
Lisa Crowder
Laboratory Officer
Aaron de Loach
Assistant Laboratory Officer
Ekanta Desai
Publications Specialist
Keith Dupuis
Underway Geophysics Laboratory
Timothy Fulton
Senior Imaging Specialist
Clayton Furman
Logging Engineer
Randy Gjesvold
Marine Instrumentation Specialist
Kevin Grigar
Operations Superintendent
Sandra Herrmann
Assistant Laboratory Officer
Michael Hodge
Marine Computer Specialist
Minh Huynh
Marine Computer Specialist
Nicolette Lawler
X-Ray Laboratory
Aaron Mechler
Chemistry Laboratory
Mike Meiring
Engineer
Algie Morgan
Application Developer
Beth Novak
Paleomagnetism Laboratory
William Rhinehart
Engineer
Catherine Smith
Curatorial Specialist
Larry Tuttle
Core Laboratory (temporary)
John Van Hyfte
Engineer
Garrick Van Rensburg
Marine Instrumentation Specialist
Hai (James) Zhao
Application Developer
IODP Publication Services staff*
Douglas Cummings
Graphics Specialist II
Gudelia (“Gigi”) Delgado
Publications Coordinator
Ekanta Desai
Graphics Specialist II
Patrick H. Edwards
Production Editor IV
Jaime A. Gracia
Supervisor of Production and Graphics
Jenni Hesse
Editor IV
Rhonda Kappler
Graphics Specialist IV
Shana C. Lewis
Editor III
Ginny Lowe
Reports Coordinator
Amy McWilliams
Supervisor of Editing
Julie Myers
Production Editor II
Lorri Peters
Manager of Publication Services
Sandi Sherar Ruddick
Editor II
Kenneth Sherar
Production Editor III
Alyssa Stephens
Graphics Specialist III
Crystal Wolfe
Production Editor III
Jean Wulfson
Graphics Specialist III
Ann Yeager
Distribution Specialist
*At time of publication.Expedition-related bibliography*
Citation data for IODP publications and journal articles in RIS format
This list includes entries for Volume 372A and Volume 372B/375.
IODP publications
Scientific Prospectus
Barnes, P.M., Pecher, I., and LeVay, L., 2017. Expedition 372 Scientific Prospectus: Creeping Gas Hydrate Slides and LWD for Hikurangi Subduction Margin. International Ocean Discovery Program. https://doi.org/
Saffer, D.M., Wallace, L.M., and Petronotis, K., 2017. Expedition 375 Scientific Prospectus: Hikurangi Subduction Margin Coring and Observatories. International Ocean Discovery Program. http://dx.doi.org/
Preliminary Report
Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372 Scientists, 2018. Expedition 372 Preliminary Report: Creeping Gas Hydrate Slides and Hikurangi LWD. International Ocean Discovery Program. https://doi.org/
Saffer, D.M., Wallace, L.M., Petronotis, K., and the Expedition 375 Scientists, 2018. Expedition 375 Preliminary Report: Hikurangi Subduction Margin Coring and Observatories. International Ocean Discovery Program. https://doi.org/
Proceedings volume
Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, 2019. Creeping Gas Hydrate Slides. Proceedings of the International Ocean Discovery Program, 372A: College Station, TX (International Ocean Discovery Program). https://doi.org/
Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, 2019. Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Expedition reports
Expedition 372A section
Barnes, P.M., Pecher, I.A., LeVay, L.J., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Crundwell, M.P., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Greve, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Kitajima, H., Koge, H., Li, X., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Petronotis, K.E., Rose, P.S., Screaton, E.J., Shankar, U., Shepherd, C.L., Torres, M.E., Underwood, M.B., Wang, X., Woodhouse, A.D., and Wu, H.-Y., 2019. Expedition 372A summary. In Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, Creeping Gas Hydrate Slides. Proceedings of the International Ocean Discovery Program, 372A: College Station, TX (International Ocean Discovery Program). https://doi.org/
Pecher, I.A., Barnes, P.M., LeVay, L.J., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Crundwell, M.P., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Greve, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Kitajima, H., Koge, H., Li, X., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Petronotis, K.E., Rose, P.S., Screaton, E.J., Shankar, U., Shepherd, C.L., Torres, M.E., Underwood, M.B., Wang, X., Woodhouse, A.D., and Wu, H.-Y., 2019. Expedition 372A methods. In Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, Creeping Gas Hydrate Slides. Proceedings of the International Ocean Discovery Program, 372A: College Station, TX (International Ocean Discovery Program). https://doi.org/
Barnes, P.M., Pecher, I.A., LeVay, L.J., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Crundwell, M.P., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Greve, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Kitajima, H., Koge, H., Li, X., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Petronotis, K.E., Rose, P.S., Screaton, E.J., Shankar, U., Shepherd, C.L., Torres, M.E., Underwood, M.B., Wang, X., Woodhouse, A.D., and Wu, H.-Y., 2019. Site U1517. In Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, Creeping Gas Hydrate Slides. Proceedings of the International Ocean Discovery Program, 372A: College Station, TX (International Ocean Discovery Program). https://doi.org/
Expedition 372B/375 section
Saffer, D.M., Wallace, L.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., Woodhouse, A.D., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Koge, H., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Rose, P.S., Screaton, E.J., Shankar, U., Torres, M.E., Wang, X., and Wu, H.-Y., 2019. Expedition 372B/375 summary. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., Woodhouse, A.D., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Koge, H., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Rose, P.S., Screaton, E.J., Shankar, U., Torres, M.E., Wang, X., and Wu, H.-Y., 2019. Expedition 372B/375 methods. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Saffer, D.M., Wallace, L.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., Woodhouse, A.D., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Koge, H., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Rose, P.S., Screaton, E.J., Shankar, U., Torres, M.E., Wang, X., and Wu, H.-Y., 2019. Site U1518. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Barnes, P.M., Wallace, L.M., Saffer, D.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., Woodhouse, A.D., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Koge, H., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Rose, P.S., Screaton, E.J., Shankar, U., Torres, M.E., Wang, X., and Wu, H.-Y., 2019. Site U1519. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Barnes, P.M., Wallace, L.M., Saffer, D.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., Woodhouse, A.D., Bourlange, S.M., Brunet, M.M.Y., Cardona, S., Clennell, M.B., Cook, A.E., Dugan, B., Elger, J., Gamboa, D., Georgiopoulou, A., Han, S., Heeschen, K.U., Hu, G., Kim, G.Y., Koge, H., Machado, K.S., McNamara, D.D., Moore, G.F., Mountjoy, J.J., Nole, M.A., Owari, S., Paganoni, M., Rose, P.S., Screaton, E.J., Shankar, U., Torres, M.E., Wang, X., and Wu, H.-Y., 2019. Site U1520. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Wallace, L.M., Saffer, D.M., Petronotis, K.E., Barnes, P.M., Bell, R.E., Crundwell, M.P., Engelmann de Oliveira, C.H., Fagereng, A., Fulton, P.M., Greve, A., Harris, R.N., Hashimoto, Y., Hüpers, A., Ikari, M.J., Ito, Y., Kitajima, H., Kutterolf, S., Lee, H., Li, X., Luo, M., Malie, P.R., Meneghini, F., Morgan, J.K., Noda, A., Rabinowitz, H.S., Savage, H.M., Shepherd, C.L., Shreedharan, S., Solomon, E.A., Underwood, M.B., Wang, M., and Woodhouse, A.D., 2019. Site U1526. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Supplementary material
Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, 2019. Supplementary material, https://doi.org/
Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, 2019. Supplementary material, https://doi.org/10.14379/iodp.proc.372B375supp.2019. Supplement to Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, 2019. Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/
Expedition research results
Ayres, C., Torres, M.E., Haley, B., and Luo, M., 2020. Data report: 87Sr/86Sr in pore fluids from IODP Expeditions 372 and 375, Hikurangi margin. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375. https://doi.org/10.14379/iodp.proc.372B375.202.2020
Hollis, C.J., 2021. Data report: early Late Cretaceous radiolarians from IODP Site U1520 (Expedition 375, Hikurangi subduction margin). In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.208.2021
Pank, K., Kutterolf, S., Hopkins, J.L., Wang, K.-L., and Lee, H.-Y., 2023. Data report: marine tephra compositions in proximal and distal drill cores, IODP Expeditions 375, 372, and 329, ODP Leg 181, and DSDP Leg 90, offshore New Zealand, Southwest Pacific. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.210.2023
Screaton, E.J., Summerfield, C., Jaeger, J.M., and Whipple, J., 2021. Data report: permeability and grain size of sediments, IODP Expeditions 372 and 375. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.205.2021
Underwood, M.B., 2020. Data report: reconnaissance of bulk sediment composition and clay mineral assemblages: inputs to the Hikurangi subduction system. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.203.2020
Underwood, M.B., 2021. Data report: clay mineral assemblages within trench-floor and accreted trench-floor deposits, IODP Expedition 372B/375 Sites U1518 and U1520, offshore New Zealand. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.206.2021
Underwood, M.B., 2021. Data report: clay mineral assemblages within biocalcareous and volcaniclastic inputs to the Hikurangi subduction zone, IODP Expedition 372B/375 Sites U1520 and U1526, offshore New Zealand. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Proceedings of the International Ocean Discovery Program. 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.207.2021
Underwood, M.B., 2022. Data report: clay mineral assemblages within Hikurangi trench-slope deposits, IODP Expedition 375 Site U1519, offshore New Zealand. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.209.2022
Underwood, M.B., and Dugan, B., 2021. Data report: clay mineral assemblages within and beneath the Tuaheni landslide complex, IODP Expedition 372A Site U1517, offshore New Zealand. In Pecher, I.A., Barnes, P.M., LeVay, L.J., and the Expedition 372A Scientists, Proceedings of the International Ocean Discovery Program. 372A: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372A.201.2021
Underwood, M.B., Lawler, N., and McNamara, K., 2020. Data report: standard mineral mixtures, normalization factors, and determination of error for quantitative X-ray diffraction analyses of bulk powders and clay-sized mineral assemblages. In Wallace, L.M., Saffer, D.M., Barnes, P.M., Pecher, I.A., Petronotis, K.E., LeVay, L.J., and the Expedition 372/375 Scientists, Hikurangi Subduction Margin Coring, Logging, and Observatories. Proceedings of the International Ocean Discovery Program, 372B/375: College Station, TX (International Ocean Discovery Program). https://doi.org/10.14379/iodp.proc.372B375.201.2020
Journals/Books
Akhmetova, G., 2022. Hydraulic and thermal modelling in faulted geological systems, application for the Site U1517 of Hikurangi Margin, New Zealand, and Enhanced Geothermal System of Soultz-sous-Forêts [PhD dissertation]. University of Lorraine, France. https://www.theses.fr/2022LORR0307
Allen, S.M., Marsaglia, K.M., Morgan, J., and Franco, A., 2022. Origin and diagenetic priming of a potential slow-slip trigger zone in volcaniclastic deposits flanking a seamount on the subducting plate, Hikurangi margin, New Zealand. New Zealand Journal of Geology and Geophysics. https://doi.org/10.1080/00288306.2021.1975776
Arai, R., Kodaira, S., Henrys, S., Bangs, N., Obana, K., Fujie, G., Miura, S., Barker, D., Bassett, D., Bell, R., Mochizuki, K., Kellett, R., Stucker, V., Fry, B., and the NZ3D Team, 2020. Three-dimensional P-wave velocity structure of the northern Hikurangi margin from the NZ3D experiment: evidence for fault-bound anisotropy. Journal of Geophysical Research: Solid Earth, 125(12):e2020JB020433. https://doi.org/10.1029/2020JB020433
Aretusini, S., Meneghini, F., Spagnuolo, E., Harbord, C.W., and Di Toro, G., 2021. Fluid pressurisation and earthquake propagation in the Hikurangi subduction zone. Nature Communications, 12(1):2481. https://doi.org/10.1038/s41467-021-22805-w
Bailey, W., McArthur, A., and McCaffrey, W., 2021. Sealing potential of contourite drifts in deep-water fold and thrust belts: examples from the Hikurangi Margin, New Zealand. Marine and Petroleum Geology, 123:104776. https://doi.org/10.1016/j.marpetgeo.2020.104776
Bailey, W.S., McArthur, A.D., and McCaffrey, W.D., 2021. Distribution of contourite drifts on convergent margins: examples from the Hikurangi subduction margin of New Zealand. Sedimentology, 68(1):294–323. https://doi.org/10.1111/sed.12779
Bangs, N.L., Morgan, J.K., Bell, R.E., Han, S., Arai, R., Kodaira, S., Gase, A.C., Wu, X., Davy, R., Frahm, L., Tilley, H.L., Barker, D.H.N., Edwards, J.H., Tobin, H.J., Reston, T.J., Henrys, S.A., Moore, G.F., Bassett, D., Kellett, R., Stucker, V., and Fry, B., 2023. Slow slip along the Hikurangi margin linked to fluid-rich sediments trailing subducting seamounts. Nature Geoscience, 16(6):505–512. https://doi.org/10.1038/s41561-023-01186-3
Barker, D.H.N., Henrys, S., Caratori Tontini, F., Barnes, P.M., Bassett, D., Todd, E., and Wallace, L., 2018. Geophysical constraints on the relationship between seamount subduction, slow slip, and tremor at the north Hikurangi subduction zone, New Zealand. Geophysical Research Letters, 45(23):12804–12813. https://doi.org/10.1029/2018GL080259
Barnes, P.M., Wallace, L.M., Saffer, D.M., Bell, R.E., Underwood, M.B., Fagereng, A., Meneghini, F., Savage, H.M., Rabinowitz, H.S., Morgan, J.K., Kitajima, H., Kutterolf, S., Hashimoto, Y., Engelmann de Oliveira, C.H., Noda, A., Crundwell, M.P., Shepherd, C.L., Woodhouse, A.D., Harris, R.N., Wang, M., Henrys, S., Barker, D.H.N., Petronotis, K.E., Bourlange, S.M., Clennell, M.B., Cook, A.E., Dugan, B.E., Elger, J., Fulton, P.M., Gamboa, D., Greve, A., Han, S., Hüpers, A., Ikari, M.J., Ito, Y., Kim, G.Y., Koge, H., Lee, H., Li, X., Luo, M., Malie, P.R., Moore, G.F., Mountjoy, J.J., McNamara, D.D., Paganoni, M., Screaton, E.J., Shankar, U., Shreedharan, S., Solomon, E.A., Wang, X., Wu, H.-Y., Pecher, I.A., and LeVay, L.J., 2020. Slow slip source characterized by lithological and geometric heterogeneity. Science Advances, 6(13):eaay3314. https://doi.org/10.1126/sciadv.aay3314
Cardona, S., 2020. Finding order in chaos—a multi scale study of mass-transport deposits [PhD dissertation]. Colorado School of Mines, Golden, CO. https://www.proquest.com/docview/2414454372/E6F9E73636C144E1PQ/1?accountid=7082
Carey, J.M., Mountjoy, J.J., Crutchley, G.J., Petley, D.N., Holden, C.F., Kaneko, Y., and Huhn, K., 2022. Episodic movement of a submarine landslide complex driven by dynamic loading during earthquakes. Geomorphology, 408:108247. https://doi.org/10.1016/j.geomorph.2022.108247
Chesley, C., Naif, S., Key, K., and Bassett, D., 2021. Fluid-rich subducting topography generates anomalous forearc porosity. Nature, 595(7866):255–260. https://doi.org/10.1038/s41586-021-03619-8
Chiele, M.B., Engelmann de Oliveira, C.H., and Sobel, E.R., 2022. New Zealand thermo-tectonic evolution: evidence from apatite fission-track and U-Th/He thermochronology. Social Science Research Network. https://doi.org/10.2139/ssrn.4060061
Clarke, M.A.M., 2023. Cryptotephra studies applied to a deep marine sedimentary record in the northern Hikurangi Trough, Aotearoa New Zealand [MS thesis]. Victoria University of Wellington, New Zealand. https://openaccess.wgtn.ac.nz/articles/thesis/Cryptotephra_studies_applied_to_a_deep_marine_sedimentary_record_in_the_northern_Hikurangi_Trough_Aotearoa_New_Zealand/24098442?file=42282180
Coffey, G.L., Savage, H.M., Polissar, P.J., Meneghini, F., Ikari, M.J., Fagereng, Å., Morgan, J.K., and Wang, M., 2021. Evidence of seismic slip on a large splay fault in the Hikurangi subduction zone. Geochemistry, Geophysics, Geosystems, 22(8):e2021GC009638. https://doi.org/10.1029/2021GC009638
Coffey, G.L.L., 2021. Mapping earthquake temperature rise along faults to understand fault structure and mechanics [PhD dissertation]. Columbia University, New York. https://www.proquest.com/docview/2457947939
Cook, A.E., Paganoni, M., Clennell, M.B., McNamara, D.D., Nole, M., Wang, X., Han, S., Bell, R.E., Solomon, E.A., Saffer, D.M., Barnes, P.M., Pecher, I.A., Wallace, L.M., LeVay, L.J., and Petronotis, K.E., 2020. Physical properties and gas hydrate at a near-seafloor thrust fault, Hikurangi Margin, New Zealand. Geophysical Research Letters, 47(16):e2020GL088474. https://doi.org/10.1029/2020GL088474
Corella Santa Cruz, C.R., Straub, S.M., Zellmer, G.F., Stirling, C.H., Reid, M.R., Barr, D., Martin, C.E., Brenna, M., and Nemeth, K., 2023. Geochemical and isotopic characterisation of trench sediment at the Hikurangi Margin from IODP Sites U1518 and U1520. New Zealand Journal of Geology and Geophysics:1–15. https://doi.org/10.1080/00288306.2023.2280031
Couvin, B., Georgiopoulou, A., Mountjoy, J.J., Amy, L., Crutchley, G.J., Brunet, M., Cardona, S., Gross, F., Böttner, C., Krastel, S., and Pecher, I., 2020. A new depositional model for the Tuaheni landslide complex, Hikurangi margin, New Zealand. Geological Society Special Publication, 500:551–566. https://doi.org/10.1144/SP500-2019-180
Crundwell, M.P., and Woodhouse, A., 2022. Biostratigraphically constrained chronologies for Quaternary sequences from the Hikurangi margin of north-eastern Zealandia. New Zealand Journal of Geology and Geophysics. https://doi.org/10.1080/00288306.2022.2101481
Crutchley, G.J., Elger, J., Kuhlmann, J., Mountjoy, J.J., Orpin, A., Georgiopoulou, A., Carey, J., Dugan, B., Cardona, S., Han, S., Cook, A., Screaton, E.J., Pecher, I.A., Barnes, P., and Huhn, K., 2022. Investigating the basal shear zone of the submarine Tuaheni Landslide Complex, New Zealand: a core-log-seismic integration study. Journal of Geophysical Research: Solid Earth, 127(1):e2021JB021997. https://doi.org/10.1029/2021JB021997
Crutchley, G.J., Klaeschen, D., Henrys, S.A., Pecher, I.A., Mountjoy, J.J., and Woelz, S., 2020. Subducted sediments, upper-plate deformation and dewatering at New Zealand's southern Hikurangi subduction margin. Earth and Planetary Science Letters, 530:115945. https://doi.org/10.1016/j.epsl.2019.115945
Das, G., and Maiti, S., 2023. A machine learning approach for the prediction of pore pressure using well log data of Hikurangi Tuaheni Zone of IODP Expedition 372, New Zealand. Energy Geoscience:100227. https://doi.org/10.1016/j.engeos.2023.100227
Davy, R.G., Frahm, L., Bell, R., Arai, R., Barker, D.H.N., Henrys, S., Bangs, N., Morgan, J., and Warner, M., 2021. Generating high-fidelity reflection images directly from full-waveform inversion: Hikurangi subduction zone case study. Geophysical Research Letters, 48(19):e2021GL094981. https://doi.org/10.1029/2021GL094981
Dutilleul, J., 2021. Petrophysical and hydrogeological study of sediment inputs to subduction zones [PhD dissertation]. Université de Lorraine, France. https://hal.univ-lorraine.fr/tel-03378509
Dutilleul, J., Bourlange, S., and Géraud, Y., 2021. Porosity and compaction state at the active Pāpaku thrust fault in the frontal accretionary wedge of the north Hikurangi margin. Geochemistry, Geophysics, Geosystems, 22(10):e2020GC009325. https://doi.org/10.1029/2020GC009325
Dutilleul, J., Bourlange, S., Géraud, Y., and Reuschlé, T., 2021. Porosity and permeability evolution in the Tuaheni landslide complex at Hikurangi margin from IODP Sites U1517 and U1519. New Zealand Journal of Geology and Geophysics. https://doi.org/10.1080/00288306.2021.1990088
Dutilleul, J., Bourlange, S., Géraud, Y., and Stemmelen, D., 2020. Porosity, pore structure, and fluid distribution in the sediments entering the northern Hikurangi margin, New Zealand. Journal of Geophysical Research: Solid Earth, 125(11):e2020JB020330. https://doi.org/10.1029/2020JB020330
Eijsink, A.M., and Ikari, M.J., 2022. Plate-rate frictional behavior of sediment inputs to the Hikurangi subduction margin: how does lithology control slow slip events? Geochemistry, Geophysics, Geosystems, 23(6):e2022GC010369. https://doi.org/10.1029/2022GC010369
Epstein, G.S., Bebout, G.E., Christenson, B.W., Sumino, H., Wada, I., Werner, C., and Hilton, D.R., 2021. Cycling of CO2 and N2 along the Hikurangi subduction margin, New Zealand: an integrated geological, theoretical, and isotopic approach. Geochemistry, Geophysics, Geosystems, 22(9):e2021GC009650. https://doi.org/10.1029/2021GC009650
Fagereng, A., Savage, H.M., Morgan, J.K., Wang, M., Meneghini, F., Barnes, P.M., Bell, R., Kitajima, H., McNamara, D.D., Saffer, D.M., Wallace, L.M., Petronotis, K., and LeVay, L., 2019. Mixed deformation styles observed on a shallow subduction thrust, Hikurangi margin, New Zealand. Geology, 47(9):872–876. https://doi.org/10.1130/G46367.1
French, M.E., and Morgan, J.K., 2020. Pore fluid pressures and strength contrasts maintain frontal fault activity, northern Hikurangi margin, New Zealand. Geophysical Research Letters, 47(21):e2020GL089209. https://doi.org/10.1029/2020GL089209
Gase, A.C., Bangs, N.L., Saffer, D.M., Han, S., Miller, P.K., Bell, R.E., Arai, R., Henrys, S.A., Kodaira, S., Davy, R., Frahm, L., and Barker, D.H.N., 2023. Subducting volcaniclastic-rich upper crust supplies fluids for shallow megathrust and slow slip. Science Advances, 9(33):eadh0150. https://doi.org/10.1126/sciadv.adh0150
Gray, M., Bell, R.E, Morgan, J.V., Henrys, S., Barker, D.H.N., and the IODP Expedition 372 and 375 Science Parties, 2019. Imaging the shallow subsurface structure of the north Hikurangi subduction zone, New Zealand, using 2-D full-waveform inversion. Journal of Geophysical Research: Solid Earth, 124(8):9049–9074. https://doi.org/10.1029/2019JB017793
Greve, A., Kars, M., and Dekkers, M.J., 2021. Fluid accumulation, migration and anaerobic oxidation of methane along a major splay fault at the Hikurangi subduction margin (New Zealand): a magnetic approach. Journal of Geophysical Research: Solid Earth, 126(2):e2020JB020671. https://doi.org/10.1029/2020JB020671
Greve, A., Kars, M., Zerbst, L., Stipp, M., and Hashimoto, Y., 2020. Strain partitioning across a subduction thrust fault near the deformation front of the Hikurangi subduction margin, New Zealand: a magnetic fabric study on IODP Expedition 375 Site U1518. Earth and Planetary Science Letters, 542:116322. https://doi.org/10.1016/j.epsl.2020.116322
Han, S., Bangs, N.L., Hornbach, M.J., Pecher, I.A., Tobin, H.J., and Silver, E.A., 2021. The many double BSRs across the northern Hikurangi margin and their implications for subduction processes. Earth and Planetary Science Letters, 558:116743. https://doi.org/10.1016/j.epsl.2021.116743
Ikari, M.J., Wallace, L.M., Rabinowitz, H.S., Savage, H.M., Hamling, I.J., and Kopf, A.J., 2020. Observations of laboratory and natural slow slip events: Hikurangi subduction zone, New Zealand. Geochemistry, Geophysics, Geosystems, 21(2):e2019GC008717. https://doi.org/10.1029/2019GC008717
Kars, M., Greve, A., and Zerbst, L., 2021. Authigenic greigite as an indicator of methane diffusion in gas hydrate-bearing sediments of the Hikurangi margin, New Zealand. Frontiers in Earth Science, 9:603363. https://doi.org/10.3389/feart.2021.603363
Kong, L., Luo, M., and Chen, D., 2021. Tracing of sediment diagenesis in the Hikurangi subduction zone, New Zealand: evidence from pore fluid Sr isotopes. Marine Geology and Quaternary Geology, 41(06). https://doi.org/10.16562/j.cnki.0256-1492.2021071202
Kroeger, K.F., Crutchley, G.J., and Pecher, I.A., 2023. Slow response of the gas hydrate system to ridge erosion and sea-level rise: insights from double BSRs on the southern Hikurangi margin (New Zealand). Earth and Planetary Science Letters, 624:118433. https://doi.org/10.1016/j.epsl.2023.118433
Leah, H., Fagereng, Å., Meneghini, F., Morgan, J.K., Savage, H.M., Wang, M., Bell, R., and Ikari, M.J., 2020. Mixed brittle and viscous strain localization in pelagic sediments seaward of the Hikurangi margin, New Zealand. Tectonics, 39(8):e2019TC005965. https://doi.org/10.1029/2019TC005965
Luo, M., Hong, W.L., Torres, M.E., Kutterolf, S., Pank, K., Hopkins, J.L., Solomon, E.A., Wang, K.L., and Lee, H.Y., 2023. Volcanogenic aluminosilicate alteration drives formation of authigenic phases at the northern Hikurangi margin: Implications for subseafloor geochemical cycles. Chemical Geology, 619:121317. https://doi.org/10.1016/j.chemgeo.2023.121317
Luo, M., Torres, M.E., Kasten, S., and Mountjoy, J.J., 2020. Constraining the age and evolution of the Tuaheni Landslide complex, Hikurangi Margin, New Zealand, using pore-water geochemistry and numerical modeling. Geophysical Research Letters, 47(11):e2020GL087243. https://doi.org/10.1029/2020GL087243
McNamara, D.D., Behboudi, E., Wallace, L., Saffer, D., Cook, A.E., Fagereng, A., Paganoni, M., Wu, H.-Y., Kim, G., Lee, H., Savage, H.M., Barnes, P., Pecher, I., LeVay, L.J., and Petronotis, K.E., 2021. Variable in situ stress orientations across the northern Hikurangi subduction margin. Geophysical Research Letters, 48(5):e2020GL091707. https://doi.org/10.1029/2020GL091707
Morgan, J.K., Solomon, E.A., Fagereng, A., Savage, H.M., Wang, M., Meneghini, F., Barnes, P.M., Bell, R.E., French, M.E., Bangs, N.L., Kitajima, H., Saffer, D.M., and Wallace, L.M., 2022. Seafloor overthrusting causes ductile fault deformation and fault sealing along the northern Hikurangi margin. Earth and Planetary Science Letters, 593:117651. https://doi.org/10.1016/j.epsl.2022.117651
Noda, A., Greve, A., Woodhouse, A., and Crundwell, M., 2022. Depositional rate, grain size and magnetic mineral sulfidization in turbidite sequences, Hikurangi Margin, New Zealand. New Zealand Journal of Geology and Geophysics. https://doi.org/10.1080/00288306.2022.2099910
Ojha, M., Shankar, U., and Ghosh, R., 2023. Gas hydrates, subsurface structures and tectonic features of the Tuaheni Landslide Complex in the Northern Hikurangi Margin, New Zealand, revealed by seismic attribute analysis. Journal of Marine Science and Engineering, 11(7):1359. https://doi.org/10.3390/jmse11071359
Oluwunmi, P.A., Reagan, M.T., Pecher, I.A., Archer, R.A., Moridis, G.J., Rowden, A.A., and Bowden, D.A., 2023. Possible influx of seawater during gas production from unsealed gas hydrate reservoirs has economic and environmental implications. Energy Fuels. https://doi.org/10.1021/acs.energyfuels.3c02963
Pan, H., Li, H., Wang, X., Cai, J., Qian, J., Howard, J.J., and Gao, Q., 2022. A unified effective medium modeling framework for quantitative characterization of hydrate reservoirs. Geophysics, 87(5):219–234. https://doi.org/10.1190/geo2021-0349.1
Pank, K., Kutterolf, S., Hopkins, J.L., Wang, K.-L., Lee, H.-Y., and Schmitt, A.K., 2023. Advances in New Zealand's tephrochronostratigraphy using marine drill sites: the Neogene. Geochemistry, Geophysics, Geosystems, 24(8):e2023GC010866. https://doi.org/10.1029/2023GC010866
Pank, K.M., 2023. From marine sediments to explosive eruption record: a case study from New Zealand and a revised methodical approach [PhD dissertation]. Kiel University, Germany. https://macau.uni-kiel.de/servlets/MCRFileNodeServlet/macau_derivate_00005500/Kurzfassung%20Pank-KatharinaMargarete.pdf
Pecher, I., Crutchley, G., Kröger, K.F., Hillman, J., Mountjoy, J., Coffin, R., and Gorman, A., 2022. New Zealand’s gas hydrate systems. In Mienert, J., Berndt, C., Tréhu, A.M., Camerlenghi, A., and Liu, C.S. (Eds.), World Atlas of Submarine Gas Hydrates in Continental Margins. Cham, Switzerland (Springer International Publishing), 415–424. https://doi.org/10.1007/978-3-030-81186-0_35
Santa Cruz, C., and Rodolfo, C., 2023. Subduction cycling and its controls on hyperactive volcanism in the Taupo Volcanic Zone, New Zealand [PhD dissertation]. Massey University, Palmerston North, New Zealand. http://hdl.handle.net/10179/20052
Savage, H.M., Shreedharan, S., Fagereng, Å., Morgan, J.K., Meneghini, F., Wang, M., McNamara, D.D., Wallace, L.M., Saffer, D.M., Barnes, P.M., Petronotis, K.E., and LeVay, L.J., 2021. Asymmetric brittle deformation at the Pāpaku fault, Hikurangi Subduction Margin, NZ, IODP Expedition 375. Geochemistry, Geophysics, Geosystems, 22(8):e2021GC009662. https://doi.org/10.1029/2021GC009662
Screaton, E.J., Torres, M.E., Dugan, B., Heeschen, K.U., Mountjoy, J.J., Ayres, C., Rose, P.S., Pecher, I.A., Barnes, P.M., and LeVay, L.J., 2019. Sedimentation controls on methane-hydrate dynamics across glacial/interglacial stages: an example from International Ocean Discovery Program Site U1517, Hikurangi Margin. Geochemistry, Geophysics, Geosystems, 20(11):4906–4921. https://doi.org/10.1029/2019GC008603
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Shankar, U., Ojha, M., and Ghosh, R., 2021. Assessment of gas hydrate reservoir from inverted seismic impedance and porosity in the northern Hikurangi margin, New Zealand. Marine and Petroleum Geology, 123:104751. https://doi.org/10.1016/j.marpetgeo.2020.104751
Shreedharan, S., Ikari, M., Wood, C., Saffer, D., Wallace, L., and Marone, C., 2022. Frictional and lithological controls on shallow slow slip at the northern Hikurangi margin. Geochemistry, Geophysics, Geosystems, 23(2):e2021GC010107. https://doi.org/10.1029/2021GC010107
Shreedharan, S., Saffer, D., Wallace, L.M., and Williams, C., 2023. Ultralow frictional healing explains recurring slow slip events. Science, 379(6633):712–717. https://doi.org/10.1126/science.adf4930
Solomon, E.A., Becker, K., Kopf, A.J., and Davis, E.E., 2019. Listening down the pipe. Oceanography, 32(1):98–101. https://doi.org/10.5670/oceanog.2019.128
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Underwood, M.B., in press. Composition of fine-grained sediment in the Hikurangi Trough: evidence for intermingling among axial gravity flows, transverse gravity flows and margin-parallel ocean currents. Sedimentology. https://doi.org/10.1111/sed.13067
Underwood, M.B., Dugan, B., and Cardona, S., 2022. How clay mineral assemblages affect instability on the upper slope of the Hikurangi subduction zone, New Zealand. Geophysical Research Letters, 49(21):e2022GL100529. https://doi.org/10.1029/2022GL100529
Vick, T., 2022. Sedimentation, sediment strength, and origin of Tuaheni landslide complex, Hikurangi margin, offshore North Island New Zealand [MS thesis]. Colorado School of Mines, Golden, CO. https://hdl.handle.net/11124/15477
Wang, L., 2019. Magnetostratigraphy at station U1518 on the northern margin of the Hikurangi subduction zone in New Zealand [MS thesis]. University of Science and Technology of China, Anhui, China. https://cdmd.cnki.com.cn/Article/CDMD-10596-1020719169.htm
Wang, M., Barnes, P., Morgan, J., Bell, R.E., Fagereng, A., Savage, H.M., Saffer, D.M., Wallace, L.M., Petronotis, K.E., and Scientists, S., 2019. Structural analysis of compactive deformation in the incoming sedimentary section of the Hikurangi Subduction Margin, New Zealand: results from IODP 375 expedition. Acta Geologica Sinica - English Edition, 93(S1):157. https://doi.org/10.1111/1755-6724.14005
Wang, M., Barnes, P.M., Morgan, J.K., Bell, R.E., Moore, G.F., Wang, M., Fagereng, A., Savage, H., Gamboa, D., Harris, R.N., Henrys, S., Mountjoy, J., Tréhu, A.M., Saffer, D., Wallace, L., and Petronotis, K., 2023. Compactive deformation of incoming calcareous pelagic sediments, northern Hikurangi subduction margin, New Zealand: implications for subduction processes. Earth and Planetary Science Letters, 605:118022. https://doi.org/10.1016/j.epsl.2023.118022
Warren-Smith, E., Fry, B., Wallace, L., Chon, E., Henrys, S., Sheehan, A., Mochizuki, K., Schwartz, S., Webb, S., and Lebedev, S., 2019. Episodic stress and fluid pressure cycling in subducting oceanic crust during slow slip. Nature Geoscience, 12(6):475–481. https://doi.org/10.1038/s41561-019-0367-x
Wei, L., 2021. Gas hydrate reservoirs and associated methane migration mechanisms on continental margins [PhD dissertation]. The Ohio State University, Columbus, OH. https://www.proquest.com/docview/2699772873
Woodhouse, A., Barnes, P.M., Shorrock, A., Strachan, L.J., Crundwell, M., Bostock, H.C., Hopkins, J., Kutterolf, S., Pank, K., Behrens, E., Greve, A., Bell, R., Cook, A., Petronotis, K., LeVay, L., Jamieson, R.A., Aze, T., Wallace, L., Saffer, D., and Pecher, I., 2022. Trench floor depositional response to glacio-eustatic changes over the last 45 ka, northern Hikurangi subduction margin, New Zealand. New Zealand Journal of Geology and Geophysics. https://doi.org/10.1080/00288306.2022.2099432
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Zhang, J., 2021. Quantification of pore pressure in subduction zones and its implication for the slip behavior of the plate interface [PhD dissertation]. University of Bremen, Bremen, Germany. https://media.suub.uni-bremen.de/handle/elib/5815
Conferences
Allen, A.K., and Kitajima, H., 2020. Effects of lithology on the mechanical properties of the input materials at the Hikurangi margin. Presented at the 2020 Japan Geoscience Union/American Geophysical Union Joint Meeting, Chiba, Japan, 24–28 May 2020. https://confit.atlas.jp/guide/event/jpgu2020/subject/SCG62-P04/advanced
Barnes, P., Gamboa, D., Bell, R.E., Moore, G.F., Mountjoy, J.J., Paganoni, M., Clennell, M.B., Cook, A., McNamara, D.D., Underwood, M., Rabinowitz, H., Noda, A., Meneghini, F., Kutterolf, S., Hashimoto, Y., Engelmann de Oliveira, C., Pecher, I.A., Wallace, L.M., Saffer, D.M., LeVay, L.J., Petronotis, K.E., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Revisiting the giant Ruatoria debris flow on the Hikurangi margin, New Zealand: results from IODP Expeditions 372 and 375, Site U1520. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0310.html
Barnes, P., Saffer, D.M., Wallace, L.M., Pecher, I.A., Petronotis, K.E., and LeVay, L., 2018. Drilling and coring the northern Hikurangi subduction margin to unlock the secrets of slow slip. Presented at the 2018 American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-03.html
Behboudi, E., Lokmer, I., McNamara, D., Manzocchi, T., Wallace, L., Saffer, D., Barnes, P., Pecher, I., Lee, H., Kim, G.Y., Wu, H.-Y., Petronotis, K., LeVay, L., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2020. Stress orientation variability along the Hikurangi subduction margin: insights from borehole image logging. Presented at the 2020 European Geosciences Union General Assembly, Online, 4–8 May 2020. https://doi.org/10.5194/egusphere-egu2020-20603
Bell, R.E., Gray, M., Morgan, J.V., Henrys, S.A., Barker, D.H.N., Bangs, N.L., Barnes, P., Wallace, L.M., Saffer, D.M., and Petronotis, K.E., 2018. Validating a full-waveform inversion velocity model at the north Hikurangi subduction margin using IODP drilling data. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0297.html
Chesley, C.J., Naif, S., and Key, K., 2020. Subducting topography generates upper plate porosity that promotes slow slip at the Hikurangi Margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Online, 1–17 December 2020. https://abstractsearch.agu.org/meetings/2020/FM/T055-06.html
Dugan, B., Pecher, I.A., Nole, M., Mountjoy, J.J., Barnes, P.M., LeVay, L., IODP Expedition 372 Scientists, and IODP Expedition 375 Scientists, 2018. Formation pore pressure through the Tuaheni landslide complex and the gas hydrate stability zone at IODP Expedition 372 Site U1517, Hikurangi Margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0313.html
Epstein, G.S., and Bebout, G.E., 2018. Reconciling records of forearc dynamics and fluid generation with estimates of carbon output in forearc springs and arc volcanic gases. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/DI33B-0033.html
Epstein, G.S., Bebout, G.E., Christensen, B.W., Sumino, H., Wada, I., Werner, C.A., and Hilton, D.R., 2020. Multidisciplinary assessment of volatile release beneath North Island, New Zealand: geologic, geochemical, and thermodynamic forward modeling approach. Presented at the American Geophysical Union Fall Meeting, Online, 1–17 December 2020. https://abstractsearch.agu.org/meetings/2020/FM/T022-08.html
Fagereng, A., Savage, H.M., Morgan, J., Wang, M., Meneghini, F., Barnes, P., Bell, R.E., Kitajima, H., McNamara, D.D., Saffer, D.M., Wallace, L.M., Pecher, I.A., Petronotis, K.E., and LeVay, L.J., 2018. Brittle-ductile deformation and fault slip behavior of a shallow subduction thrust, Hikurangi margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-06.html
Frahm, L., Davy, R.G., Bell, R.E., Morgan, J.V., Arai, R., Bangs, N.L., Henrys, S.A., and Barker, D.H.N., 2020. Temporal and spatial changes in full-waveform inversion velocity models along the northern Hikurangi subduction margin. Presented at the American Geophysical Union Fall Meeting, Online, 1–17 December 2020. https://abstractsearch.agu.org/meetings/2020/FM/T017-0011.html
Greve, A., Kanamatsu, T., Fagereng, A., Morgan, J., Wang, M., Savage, H.M., Kars, M.A.C., Li, X., Wallace, L.M., Saffer, D.M., and Petronotis, K.E., 2018. Magnetic fabrics of deformed soft sediments at the deformation front of the Hikurangi subduction margin. Presented at the American Geophysical Union Fall Meeting, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0305.html
Hashimoto, Y., Nishimori, R., Greve, A., and Morgan, J., 2020. Constraints on paleo-stress magnitude in Hikurangi margin, New Zealand, at Site U1518, Expedition 375. Presented at the Japan Geoscience Union/American Geophysical Union Joint Meeting, Chiba, Japan, 24–28 May 2020. https://confit.atlas.jp/guide/event/jpgu2020/subject/MIS11-15/advanced
Hashimoto, Y., Nishomori, R., Greve, A., and Morgan, J., 2020. Constraints on paleo-stress magnitude in Hikurangi Margin, New Zealand, at Site U1518, Expedition 375. Presented at the American Geophysical Union Fall Meeting, Online. https://abstractsearch.agu.org/meetings/2020/FM/T017-0013.html
Heeschen, K., Schloemer, S., Torres, M., Cook, A.E., Screaton, E., Georgiopoulou, A., Pecher, I., Mayanna, S., Barnes, P., Solomon, E., and LeVay, L., 2020. Distribution and fractionation of light hydrocarbons related to gas hydrate occurrence and biogenic production at Hikurangi Margin (IODP Site U1517), New Zealand. Presented at the 2020 European Geosciences Union General Assembly, Online, 4–8 May 2020. https://doi.org/10.5194/egusphere-egu2020-15046
Heeschen, K.U., Torres, M.E., Pecher, I.A., Schlomer, S., Owari, S., Rose, P.S., Karina, M., Schicks, J.M., Hu, G., Mountjoy, J.J., Barnes, P., LeVay, L.J., Solomon, E.A., Saffer, D.M., Wallace, L., Petronotis, K.E., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Occurrence and fractionation of light hydrocarbons in the gas-hydrate bearing sediments of IODP Site U1517, Hikurangi margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/OS13A-06.html
Jeppson, T., Kitajima, H., Ikari, M., Lee, H., Ito, Y., Harris, R.N., Shreedharan, S., Luo, M., Malie, P.R., Huepers, A., Solomon, E.A., Underwood, M., Kutterolf, S., Meneghini, F., Hashimoto, Y., Engelmann de Oliveira, C., Rabinowitz, H., Noda, A., Fulton, P.M., Saffer, D.M., Wallace, L.M., Barnes, P., Pecher, I.A., Petronotis, K.E., and LeVay, L.J., 2018. Lithology and cement controls on the evolution of compressional wave velocity and porosity in input materials at northern Hikurangi and other subduction zones. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0309.html
Koge, H., McNamara, D.D., Gamboa, D., Wu, H.-Y., Kim, G.Y., Cardona, S., Shanker, U., Barnes, P., Pecher, I.A., LeVay, L.J., Saffer, D.M., Wallace, L.M., Petronotis, K.E., Noda, A., Morgan, J., Ashi, J., Yamaguchi, A., Yamada, Y., and Hamada, Y., 2018. Constraining the deformation history of the frontal wedge of Hikurangi subduction margin with analog modeling and bedding trends from borehole logging of IODP Expedition 372. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0302.html
Leah, H.R., Fagereng, A., Meneghini, F., Morgan, J., Savage, H.M., Wang, M., Saffer, D.M., Wallace, L.M., and Petronotis, K.E., 2018. Subduction-related strain in a calcareous-pelagic shear zone: insights on deformation at the Hikurangi margin plate interface from the input sequence at Site U1520 and the Llanddwyn Island shear zone, Anglesey, UK. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0304.html
Lloyd, C., Allen, A., and Kitajima, H., 2020. In-situ rock strength of the input materials and prism sediments at the Hikurangi Margin. Presented at the American Geophysical Union Fall Meeting, Online. https://abstractsearch.agu.org/meetings/2020/FM/T017-0014.html
McIntyre, A., Beard, J., Shreedharan, S., and Kitajima, H., 2020. Image analysis of drill core samples from the Hikurangi subduction margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Online, 1–17 December 2020. https://abstractsearch.agu.org/meetings/2020/FM/T017-0015.html
McNamara, D.D., Wu, H.-Y., Lee, H., Wallace, L.M., Lee, G., Heeschen, K.U., Elger, J., Saffer, D.M., Barnes, P., and Pecher, I.A., 2018. Borehole stress indicators across the Hikurangi subduction margin: preliminary insights from IODP Expedition 372. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-05.html
Meneghini, F., Boschi, C., Fagereng, A., Morgan, J., Underwood, M., Hashimoto, Y., Engelmann de Oliveira, C., Kutterolf, S., Noda, A., Rabinowitz, H.S., Savage, H.M., Wang, M., Wallace, L.M., Saffer, D.M., Barnes, P., Pecher, I.A., Petronotis, K.E., and LeVay, L.J., 2018. Lithification of volcaniclastic deposits in the Hikurangi subduction zone: preliminary characterization of fluid circulation in the incoming plate, and volatiles entering the trench. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0308.html
Morgan, J., Fagereng, A., Savage, H.M., Want, M., Meneghini, F., Barnes, P., Bell, R.E., Kitajima, H., Dugan, B., Wallace, L.M., Saffer, D.M., Pecher, I.A., Petronotis, K.E., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Seafloor overthrusting creates ductilely deformed fault rocks in marine sediments at the Hikurangi margin: implications for fault zone evolution and mechanics at IODP Site U1518. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0301.html
Noda, A., and Greve, A., 2020. Rock magnetic properties, grain size, and layer thickness of turbidites at the northern Hikurangi margin, New Zealand: results from IODP Exp. 375, Site U1520. Presented at the Japan Geoscience Union/American Geophysical Union Joint Meeting, Chiba, Japan, 24–28 May 2020. https://confit.atlas.jp/guide/event/jpgu2020/subject/MIS11-P11/advanced
Nole, M., Daigle, H., Dugan, B., Clennell, M.B., Paganoni, M., Barnes, P., Pecher, I.A., LeVay, L., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Pore morphology, permeability, and constraints on gas hydrate accumulation in sediments from the Tuaheni Landslide Complex, NZ. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/OS51F-1331.html
Owari, S., and Tomaru, H., 2020. Origin of methane in gas hydrate field, Hikurangi subduction margin: application of geochronological method using a long-lived radioisotope of iodine. Presented at the Japan Geoscience Union/American Geophysical Union Joint Meeting, Chiba, Japan, 24–28 May 2020. https://confit.atlas.jp/guide/event/jpgu2020/subject/MIS32-P07/advanced
Pecher, I., Barnes, P., Heeschen, K., Torres, M., Cook, A., Moore, G., Dugan, B., Mountjoy, J., Crutchley, G., and the Expedition 372 and 375 Scientific Party, 2018. Gas hydrates beneath the Tuaheni Landslide Complex, New Zealand. First results from IODP Expedition 372. Geophysical Research Abstracts, 20:EGU2018-4221-2011. https://meetingorganizer.copernicus.org/EGU2018/EGU2018-4221-1.pdf
Pecher, I.A., Oluwunmi, P., Djeffal, A., Bangs, N.L., Crutchley, G.J., Mountjoy, J.J., Villinger, H.W., Barnes, P., Heeschen, K.U., Dugan, B., Reagan, M.T., Moridis, G.J., Archer, R., Saffer, D.M., Wallace, L.M., LeVay, L.J., and Petronotis, K.E., 2018. Response of gas hydrate systems to subduction-zone processes on the northern Hikurangi margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-08.html
Rabinowitz, H.S., Savage, H.M., Carpenter, B., Ikari, M., and Collettini, C., 2017. Frictional behavior of carbonate-rich incoming sediment in the Hikurangi subduction zone. Presented at the American Geophysical Union Fall Meeting, New Orleans, LA, 11–15 December 2017. https://abstractsearch.agu.org/meetings/2017/FM/S52B-02.html
Rabinowitz, H.S., Savage H.M., Shreedharan, S., Ikari, M., Meneghini, F., Ito, Y., Kitajima, H., Wallace, L.M., Saffer, D.M., and Petronotis, K.E., 2018. Frictional behavior of incoming sediment in the Hikurangi subduction zone at in-situ PT conditions. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0300.html
Saffer, D.M., Bell, R.E., Barnes, P., Wallace, L.M., Kitajima, H., Moore, G.F., Han, S., Pecher, I.A., Petronotis, K.E., and LeVay, L., 2018. Elastic moduli and physical properties of fault rock and protolith associated with SSEs at the northern Hikurangi margin, NZ. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-04.html
Savage, H.M., Coffey, G.L., Shreedharan, S., Polissar, P.J., Fagereng, A., Meneghini, F., Morgan, J., Wang, M., Hashimoto, Y., Wallace, L.M., Saffer, D.M., Barnes, P., Pecher, I.A., Petronotis, K.E., and LeVay, L.J., 2018. Signatures of brittle deformation in a shallow fault in the Hikurangi subduction margin. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0303.html
Screaton, E., Torres, M.E., Dugan, B., Heeschen, K.U., Mountjoy, J.J., Oware, S., Rose, P.S., Pecher, I.A., Barnes, P.M., LeVay, L.J., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Impact of sea-level and bottom water temperature change on methane-hydrate stability: IODP Site U1517, Hikurangi margin. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0312.html
Solomon, E.A., Huepers, A., Luo, M., Malie, P.R., Saffer, D.M., Torres, M.E., Wallace, L.M., Petronotis, K.E., Barnes, P., Pecher, I.A., and LeVay, L.J., 2018. Geochemical constraints on fluid-rock reactions, fluid sources, and flow pathways along the IODP Expedition 375 transect: northern Hikurangi margin. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T54C-07.html
Underwood, M., 2017. Composition of sediment inputs to the Hikurangi subduction margin: a prelude to IODP Expedition 375. Presented at the American Geophysical Union Fall Meeting, New Orleans, LA, 11–15 December 2017. https://abstractsearch.agu.org/meetings/2017/FM/T21E-01.html
Underwood, M., Rabinowitz, H.S., Noda, A., Meneghini, F., Kutterolf, S., Hashimoto, Y., Engelmann de Oliveira, C., Saffer, D.M., Wallace, L.M., Barnes, P., Pecher, I.A., Petronotis, K.E., and LeVay, L.J., 2018. Lithostratigraphy of the Hikurangi subduction inputs: results of coring during IODP Expedition 375. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0307.html
Wallace, L.M., Barnes, P., Saffer, D.M., Henrys, S.A., Barker, D.H.N., Bassett, D., Caratori Tontini, F., Kaneko, Y., Ito, Y., Mochizuki, K., Webb, S.C., Clark, K., Cochran, U.A., Litchfiend, N.J., Williams, C.A., Jr., Ellis, S.M., Fry, B., Todd, E., Bell, R.E., Petronotis, K.E., Pecher, I.A., and LeVay, L.J., 2018. The dynamics of shallow plate interface slip at the offshore Hikurangi subduction margin, New Zealand. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T52C-03.html
Wallace, L.M., Solomon, E.A., Fulton, P.M., Saffer, D.M., Petronotis, K.E., Jannasch, H.W., Davis, E.E., Rhinehart, KB., Van Hyfte, J., Grigar, K., Barnes, P., Bell, R.E., Pecher, I.A., and LeVay, L.J., 2018. IODP borehole observatories to monitor slow slip at the offshore Hikurangi subduction zone. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0293.html
Wang, X., and Liu, B., 2018. Occurrence and saturation of free gas and gas hydrate at complex tectonic and interbedded reservoir in the Hikurangi Margin, New Zealand [Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/T51I-0314.html
Wei, L., Cook, A., Nole, M., Malinverno, A., Daigle, H., Georgiopoulou, A., Barnes, P., Pecher, I.A., LeVay, L.J., the IODP Expedition 372 Scientists, and the IODP Expedition 375 Scientists, 2018. Gas hydrate accumulations in thin sands. Presented at the American Geophysical Union Fall Meeting, Washington, DC, 10–14 December 2018. https://abstractsearch.agu.org/meetings/2018/FM/OS31F-1853.html
*The Expedition-related bibliography is continually updated online. Please send updates to PubCrd@iodp.tamu.edu.