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100   $a20180420d20142014  uy             0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 00$aComputational models for CO2 geo-sequestration and compressed air energy storage /$feditors, Rafid Al-Khoury, Faculty of Civil Engineering and Geosciences, Delft University of Technology, Delft, The Netherlands,  Jochen Bundschuh, University of Southern Queensland, Faculty of Health, Engineering and Sciences and National Centre for Engineering in Agriculture, Toowoomba, Queensland, Australia, Royal Institute of Technology (KTH), Stockholm, Sweden
210  1$aBoca Raton :$cCRC Press,$d[2014].
210  4$dİ2014
215   $a1 online resource (566 p.)
225 1 $aSustainable Energy Developments,$x2164-0645 ;$vVolume 10
300   $aA Balkema book.
311   $a1-306-89523-5 
311   $a1-138-01520-2 
320   $aIncludes bibliographical references.
327   $aFront Cover; About the book series; Editorial board; Table of contents; Contributors; Foreword by Jacob Bear; Editors' preface; About the editors; Acknowledgements; 1. Geological CO2 sequestration and compressed air energy storage - An introduction; PART I: CO2 Geo-sequestration; 2. On the theory of CO2 geo-sequestration; PART I.I: Reactive transport modeling; 3. Modeling multiscale-multiphase-multicomponent reactive flows in porous media: Application to CO2 sequestration and enhanced geothermal energy using PFLOTRAN
327   $a4. Pore-network modeling of multi-component reactive transport under (variably-) saturated conditions5. Reactive transport modeling issues of CO2 geological storage; PART I.II: Numerical modeling; 6. Role of computational science in geological storage of CO2; 7. A robust implicit pressure explicit mass method for multi-phase multi-component flow including capillary pressure and buoyancy; 8. Simulation of CO2 sequestration in brine aquifers with geomechanical coupling; 9. Model development for the numerical simulation of CO2 storage in naturally fractured saline aquifers
327   $a10. Coupled partition of unity-level set finite element formulation for CO2 geo-sequestrationPART I.III: Aquifer optimization; 11. Optimization and data assimilation for geological carbon storage; 12. Density-driven natural convection flow of CO2 in heterogeneous porous media; PART II: Compressed air energy storage; 13. An introduction to the compressed air energy storage; 14. Simulation of an isobaric adiabatic compressed air energy storage combined cycle; 15. Rigorous process simulation of compressed air energy storage (CAES) in porous media systems
327   $a16. Detailed system level simulation of compressed air energy storageBook series page
330   $aThis book addresses two distinct, but related and highly important geoenvironmental applications: CO2 sequestration in underground formation, and Compressed Air Energy Storage (CAES). Sequestration of carbon dioxide in underground formations is considered an effective technique and a viable strategy for the mitigation of global warming and climate change. However, the short-term and long-term consequences of such an operation might be catastrophic if the involved hydro-chemo-physical and mechanical processes at the regional level are not properly addressed. Compressed air energy storage is a relatively new field of geoenvironmental application, but gaining a lot of momentum due to its effective utilization for energy storage. Renewable energy sources, such as wind energy, can be efficiently stored in the form of a compressed air in underground formations at off-peak times, and re-utilized upon demand. However, pumping and releasing compressed air can cause hydromechanical effects on the region, causing subsidence, upheaving and minor earthquakes. Considering the great potentials of these two geoenvironmental applications and their consequences, it is vital to model the involved flow processes and develop numerical tools, which are capable of describing such processes in an accurate, stable and computationally efficient manner. This book aims at attaining such models and numerical tools.--$cProvided by publisher.
410  0$aSustainable energy developments ;$vVolume 10.
517 3 $aComputational models for CO2 geo-sequestration and compressed air energy storage
606   $aGeological carbon sequestration$xMathematical models
606   $aCompressed air$xUnderground storage$xMathematical models
606   $aCompressed air$xUnderground storage$xEnvironmental aspects
606   $aGeological carbon sequestration$xEnvironmental aspects
615  0$aGeological carbon sequestration$xMathematical models.
615  0$aCompressed air$xUnderground storage$xMathematical models.
615  0$aCompressed air$xUnderground storage$xEnvironmental aspects.
615  0$aGeological carbon sequestration$xEnvironmental aspects.
676   $a628.5/32
686   $aMAT000000$aTEC009020$aTEC010000$2bisacsh
702   $aAl-Khoury$b Rafid
702   $aBundschuh$b Jochen
801  0$bFlBoTFG
801  1$bFlBoTFG
906   $aBOOK
912   $a9910789244603321
996   $aComputational models for CO2 geo-sequestration and compressed air energy storage$93699006
997   $aUNINA