Permeability is the primary control on fluid flow in the Earth’s crust and is key to a surprisingly wide range of geological processes, because it controls the advection of heat and solutes and the generation of anomalous pore pressures. The practical importance of permeability – and the potential for large, dynamic changes in permeability – is highlighted by ongoing issues associated with hydraulic fracturing for hydrocarbon production (“fracking”), enhanced geothermal systems, and geologic carbon sequestration. Although there are thousands of research papers on crustal permeability, this is the first book-length treatment. This book bridges the historical dichotomy between the hydrogeologic perspective of permeability as a static material property and the perspective of other Earth scientists who have long recognized permeability as a dynamic parameter that changes in response to tectonism, fluid production, and geochemical reactions.
Edited by:
Tom Gleeson (University of Victoria),
Steve Ingebritsen (United States Geological Survey)
Imprint: Wiley-Blackwell
Country of Publication: United States
Dimensions:
Height: 279mm,
Width: 216mm,
Spine: 31mm
Weight: 1.792kg
ISBN: 9781119166566
ISBN 10: 111916656X
Series: Wiley Works
Pages: 472
Publication Date: 25 November 2016
Audience:
College/higher education
,
Professional and scholarly
,
A / AS level
,
Further / Higher Education
Format: Hardback
Publisher's Status: Active
List of contributors, xi About the companion websites, xvii 1 Introduction, 1 Tom Gleeson and Steven Ingebritsen 2 DigitalCrust –a 4D data system of material properties for transforming research on crustal fluid flow, 6 Ying Fan, Stephen Richard, R. Sky Bristol, Shanan E. Peters, Steven E. Ingebritsen, Nils Moosdorf, Aaron Packman, Tom Gleeson, I. Zaslavsky, S. Peckham, Lawrence Murdoch, Michael Fienen, Michael Cardiff, David Tarboton, Norman Jones, Richard Hooper, Jennifer Arrigo, D. Gochis, J. Olson and David Wolock Part I: The physics of permeability, 13 3 The physics of permeability, 15 Tom Gleeson and Steven E. Ingebritsen 4 A pore-scale investigation of the dynamic response of saturated porous media to transient stresses, 16 Christian Huber and Yanqing Su 5 Flow of concentrated suspensions through fractures: small variations in solid concentration cause significant in-plane velocity variations, 27 Ricardo Medina, Jean E. Elkhoury, Joseph P. Morris, Romain Prioul, Jean Desroches and Russell L. Detwiler 6 Normal stress-induced permeability hysteresis of a fracture in a granite cylinder, 39 A. P. S. Selvadurai 7 Linking microearthquakes to fracture permeability evolution, 49 Takuya Ishibashi, Noriaki Watanabe, Hiroshi Asanuma and Noriyoshi Tsuchiya 8 Fractured rock stress–permeability relationships from in situ data and effects of temperature and chemical–mechanical couplings, 65 Jonny Rutqvist Part II: Static permeability, 83 9 Static permeability, 85 Tom Gleeson and Steven E. Ingebritsen Part II(A): Sediments and sedimentary rocks 10 How well can we predict permeability in sedimentary basins? Deriving and evaluating porosity–permeability equations for noncemented sand and clay mixtures, 89 Elco Luijendijk and Tom Gleeson 11 Evolution of sediment permeability during burial and subduction, 104 Hugh Daigle and Elizabeth J. Screaton Part II(B): Igneous and metamorphic rocks 12 Is the permeability of crystalline rock in the shallow crust related to depth, lithology, or tectonic setting?, 125 Mark Ranjram, Tom Gleeson and Elco Luijendijk 13 Understanding heat and groundwater flow through continental flood basalt provinces: Insights gained from alternative models of permeability/depth relationships for the Columbia Plateau, United States, 137 Erick R. Burns, Colin F. Williams, Steven E. Ingebritsen, Clifford I. Voss, Frank A. Spane and Jacob DeAngelo 14 Deep fluid circulation within crystalline basement rocks and the role of hydrologic windows in the formation of the Truth or Consequences, New Mexico low-temperature geothermal system, 155 Jeffrey Pepin, Mark Person, Fred Phillips, Shari Kelley, Stacy Timmons, Lara Owens, James Witcher and Carl W. Gable 15 Hydraulic conductivity of fractured upper crust: insights from hydraulic tests in boreholes and fluid– rock interaction in crystalline basement rocks, 174 Ingrid Stober and Kurt Bucher Part III: Dynamic permeability, 189 16 Dynamic permeability, 191 Tom Gleeson and Steven E. Ingebritsen Part III(A): Oceanic crust 17 Rapid generation of reaction permeability in the roots of black smoker systems, Troodos ophiolite, Cyprus, 195 Johnson R. Cann, Andrew M. Mccaig and Bruce W. D. Yardley Part III(B): Fault zones 18 The permeability of active subduction plate boundary faults, 209 Demian M. Saffer 19 Changes in hot spring temperature and hydrogeology of the Alpine Fault hanging wall, New Zealand, induced by distal South Island earthquakes, 228 Simon C. Cox, Catriona D. Menzies, Rupert Sutherland, Paul H. Denys, Calum Chamberlain and Damon A. H. Teagle 20 Transient permeability in fault stepovers and rapid rates of orogenic gold deposit formation, 249 Steven Micklethwaite, Arianne Ford, Walter Witt and Heather A. Sheldon 21 Evidence for long-timescale (>103 years) changes in hydrothermal activity induced by seismic events, 260 Trevor Howald, Mark Person, Andrew Campbell, Virgil Lueth, Albert Hofstra, Donald Sweetkind, Carl W. Gable, Amlan Banerjee, Elco Luijendijk, Laura Crossey, Karl Karlstrom, Shari Kelley and Fred M. Phillips Part III(C): Crustal-scale behavior 22 The permeability of crustal rocks through the metamorphic cycle: an overview, 277 Bruce Yardley 23 An analytical solution for solitary porosity waves: dynamic permeability and fluidization of nonlinear viscous and viscoplastic rock, 285 James A. D. Connolly and Y. Y. Podladchikov 24 Hypocenter migration and crustal seismic velocity distribution observed for the inland earthquake swarms induced by the 2011 Tohoku-Oki earthquake in NE Japan: implications for crustal fluid distribution and crustal permeability, 307 T. Okada, T. Matsuzawa, N. Umino, K. Yoshida, A. Hasegawa, H. Takahashi, T. Yamada, M. Kosuga, Tetsuya Takeda, A. Kato, T. Igarashi, K. Obara, S. Sakai, A. Saiga, T. Iidaka, T. Iwasaki, N. Hirata, N. Tsumura, Y. Yamanaka, T. Terakawa, H. Nakamichi, T. Okuda, S. Horikawa, H. Katao, T. Miura, A. Kubo, T. Matsushima, K. Goto and H. Miyamachi 25 Continental-scale water-level response to a large earthquake, 324 Zheming Shi, Guang-Cai Wang, Michael Manga and Chi-Yuen Wang Part III(D): Effects of fluid injection at the scale of a reservoir or ore-deposit 26 Development of connected permeability in massive crystalline rocks through hydraulic fracture propagation and shearing accompanying fluid injection, 337 Giona Preisig, Erik Eberhardt, Valentin Gischig, Vincent Roche, Mirko van der Baan, Benoit Valley, Peter K. Kaiser, Damien Duff and Robert Lowther 27 Modeling enhanced geothermal systems and the essential nature of large-scale changes in permeability at the onset of slip, 353 Stephen A. Miller 28 Dynamics of permeability evolution in stimulated geothermal reservoirs, 363 Joshua Taron, Steve E. Ingebritsen, Stephen Hickman and Colin F. Williams 29 The dynamic interplay between saline fluid flow and rock permeability in magmatic–hydrothermal systems, 373 Philipp Weis Part IV: Conclusion, 393 30 Toward systematic characterization, 395 Tom Gleeson and Steven E. Ingebritsen References, 398 Index, 447
Steve Ingebritsen, USGS,?Menlo Park California. Tom Gleeson, University of Victoria, Canada.
Reviews for Crustal Permeability
This book represents an excellent resource and reference for any professional earth scientist concerned with earth systems and processes influenced by the flow of fluids. The Leading Edge, April 2017
