Mechanics of Geological MaterialsSource: Applied Mechanics Reviews:;1985:;volume( 038 ):;issue: 010::page 1256Author:M. M. Carroll
DOI: 10.1115/1.3143685Publisher: The American Society of Mechanical Engineers (ASME)
Abstract: Needed advances in various areas of energy resource recovery, underground construction, earthquake hazard reduction, and conventional and nuclear defense depend critically on the development of improved theories for mechanical and thermal behavior of geological materials. The areas include oil and gas (including off-shore and Arctic production), mining and in situ recovery, geothermal production, nuclear waste isolation, under-ocean tunneling, underground storage, nuclear test containment, and effects of surface explosions. The needed developments, some of which are detailed in earlier National Academy of Science reports, include constitutive theories for inelastic deformation, failure, and post-failure behavior, influence of microstructure and macrostructure, rock fracture (direct breakage, hydraulic fracture explosive fracture), frictional sliding, soil liquefaction, mechanics of ice, determination of in situ conditions, flow through porous media, and thermal effects. Advances in mechanics of geological materials will require adaptation of some established techniques in rheology, metal plasticity, composite materials, mixtures, etc., and also the development of some entirely new ideas and methods. The complicated nature of rocks and soils, the wide ranges of stress, temperature, strain rate, etc., the interactions encountered in geotechnical processes, and the vastly different dimensions and time scales involved, lead to a host of challenging problems in solid mechanics.
keyword(s): Flow (Dynamics) , Plasticity , Deformation , Temperature , Liquefaction , Metals , Radioactive wastes , Explosions , Mining , Porous materials , Composite materials , Dimensions , Construction , Stress , Rheology , Tunnel construction , Geothermal engineering , In situ processing (Mining) , Ocean engineering , Temperature effects , Arctic region , Energy recovery , Fracture (Process) , Ice mechanics , Solid mechanics , Underground storage , Defense industry , Earthquakes , Failure , Mixtures , Oceans , Rocks , Soil , Explosives AND Containment ,
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contributor author | M. M. Carroll | |
date accessioned | 2017-05-08T23:19:14Z | |
date available | 2017-05-08T23:19:14Z | |
date copyright | October, 1985 | |
date issued | 1985 | |
identifier issn | 0003-6900 | |
identifier other | AMREAD-25519#1256_1.pdf | |
identifier uri | http://yetl.yabesh.ir/yetl/handle/yetl/99250 | |
description abstract | Needed advances in various areas of energy resource recovery, underground construction, earthquake hazard reduction, and conventional and nuclear defense depend critically on the development of improved theories for mechanical and thermal behavior of geological materials. The areas include oil and gas (including off-shore and Arctic production), mining and in situ recovery, geothermal production, nuclear waste isolation, under-ocean tunneling, underground storage, nuclear test containment, and effects of surface explosions. The needed developments, some of which are detailed in earlier National Academy of Science reports, include constitutive theories for inelastic deformation, failure, and post-failure behavior, influence of microstructure and macrostructure, rock fracture (direct breakage, hydraulic fracture explosive fracture), frictional sliding, soil liquefaction, mechanics of ice, determination of in situ conditions, flow through porous media, and thermal effects. Advances in mechanics of geological materials will require adaptation of some established techniques in rheology, metal plasticity, composite materials, mixtures, etc., and also the development of some entirely new ideas and methods. The complicated nature of rocks and soils, the wide ranges of stress, temperature, strain rate, etc., the interactions encountered in geotechnical processes, and the vastly different dimensions and time scales involved, lead to a host of challenging problems in solid mechanics. | |
publisher | The American Society of Mechanical Engineers (ASME) | |
title | Mechanics of Geological Materials | |
type | Journal Paper | |
journal volume | 38 | |
journal issue | 10 | |
journal title | Applied Mechanics Reviews | |
identifier doi | 10.1115/1.3143685 | |
journal fristpage | 1256 | |
journal lastpage | 1260 | |
identifier eissn | 0003-6900 | |
keywords | Flow (Dynamics) | |
keywords | Plasticity | |
keywords | Deformation | |
keywords | Temperature | |
keywords | Liquefaction | |
keywords | Metals | |
keywords | Radioactive wastes | |
keywords | Explosions | |
keywords | Mining | |
keywords | Porous materials | |
keywords | Composite materials | |
keywords | Dimensions | |
keywords | Construction | |
keywords | Stress | |
keywords | Rheology | |
keywords | Tunnel construction | |
keywords | Geothermal engineering | |
keywords | In situ processing (Mining) | |
keywords | Ocean engineering | |
keywords | Temperature effects | |
keywords | Arctic region | |
keywords | Energy recovery | |
keywords | Fracture (Process) | |
keywords | Ice mechanics | |
keywords | Solid mechanics | |
keywords | Underground storage | |
keywords | Defense industry | |
keywords | Earthquakes | |
keywords | Failure | |
keywords | Mixtures | |
keywords | Oceans | |
keywords | Rocks | |
keywords | Soil | |
keywords | Explosives AND Containment | |
tree | Applied Mechanics Reviews:;1985:;volume( 038 ):;issue: 010 | |
contenttype | Fulltext |