书籍详情
多孔介质中的流体:输运与相变(英文)
作者:(荷)亨克·惠因克
出版社:哈尔滨工业大学出版社
出版时间:2021-07-01
ISBN:9787560394923
定价:¥68.00
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内容简介
本书共九章,主要介绍了多孔介质中的流体。通过多孔介质的介绍引入了第一章的孔隙空间及孔隙度的几何学;第二章主要介绍了热力学,描写了热力学势与平衡以及热力学的基本性质;第三章通过对界面张力的描写介绍了固体的润湿和毛细现象;第四章介绍了一些现象,如融化、冷凝和结晶等;第五章和第六章分别介绍了管流和单相流动;第七章介绍了非承压含水层;第八章和第九章介绍了不饱和流和二相流等问题。本书可用作相关专业硕士研究生教材。
作者简介
亨克·惠因克,Hendrik Pieter (Henk) Huinink is a physical chemist who graduated at the Wageningen University, The Netherlands (1998), with a PhD in soft matter physics. From 1998-1999 he was research associate at the Shell Research and Technology Center Amsterdam (SRTCA),where he investigated the influence of confinement on the morphology of block copolymers. He joined the Applied Physics Department of the Eindhoven Universitv of Technologv (The Netherlands) in 1999, where he started to work on modeling of transport in porous media and thin films. In those years he became more and more involved in NMR imaging studies on transport phenonema. In 2005 he became assistant professor at the Eindhoven University of Technology in the group Transport in Permeable Media (TPM). He guides a group of about 5-7 PhD students doing experimental work on transport processes in porous materials and polymer films. He teaches several courses at BSc and MSc level: statistical physics, microfluidics and porous media. Recently, he has started to redirect his research activities towards the kinetics of charging and discharging heat storage materials. For that purpose he spent a sabbatical in 2015 at the Friederich-Alexander University (Erlangen, Germany),where he studied hydration transitions in inorganic crystals with molecular simulations.
目录
Preface
Acknowledgements
About the Author
Symbols
1 Introduction
1.1 Porous materials
1.2 The geometry of the pore space and porosity
1.3 Pore sizes and the pore size distribution
1.4 Tortuosity
1.5 Guide to the reader
Further reading
2 Recap of thermodynamics
2.1 Fundamental equations
2.2 Thermodynamic potentials and equilibrium
2.3 Chemical potentials
Further reading
3 Wetting of solids and capillarity
3.1 Interfaces and interracial tension
3.2 Wetting and contact angle
3.3 Capillary pressure
3.4 Stresses in materials
Further reading
4 Phase transitiofis and confinement
4.1 Melting
4.2 Condensation
4.3 Crystallization
Further reading
5 Pipe flow
5.1 Stokes flow
5.2 Flow through a tube
Further reading
6 Single phase flow
6.1 Darcy's law
6.2 Permeability and geometry
6.3 Heterogeneity in the permeability
Further reading
7 Unconfined aquifers
7.1 Dupuit equation
7.2 Steady state applications and wells
Further reading
8 Unsaturated flow
8.1 Capillary suction
8.2 Beyond the sharp front approach
8.3 Capillary suction revisited
8.4 The role of vapor transport
Further reading
9 Two phase flow
9.1 Front motion
9.2 The front zone
9.3 Relative permeability and residual saturation
9.4 Viscous fingering
Further reading
Appendices
A Thermodynamic potentials
B Energy of a liquid film
C Interfacial areas of a spherical cap
D Bruggeman equation
编辑手记
Acknowledgements
About the Author
Symbols
1 Introduction
1.1 Porous materials
1.2 The geometry of the pore space and porosity
1.3 Pore sizes and the pore size distribution
1.4 Tortuosity
1.5 Guide to the reader
Further reading
2 Recap of thermodynamics
2.1 Fundamental equations
2.2 Thermodynamic potentials and equilibrium
2.3 Chemical potentials
Further reading
3 Wetting of solids and capillarity
3.1 Interfaces and interracial tension
3.2 Wetting and contact angle
3.3 Capillary pressure
3.4 Stresses in materials
Further reading
4 Phase transitiofis and confinement
4.1 Melting
4.2 Condensation
4.3 Crystallization
Further reading
5 Pipe flow
5.1 Stokes flow
5.2 Flow through a tube
Further reading
6 Single phase flow
6.1 Darcy's law
6.2 Permeability and geometry
6.3 Heterogeneity in the permeability
Further reading
7 Unconfined aquifers
7.1 Dupuit equation
7.2 Steady state applications and wells
Further reading
8 Unsaturated flow
8.1 Capillary suction
8.2 Beyond the sharp front approach
8.3 Capillary suction revisited
8.4 The role of vapor transport
Further reading
9 Two phase flow
9.1 Front motion
9.2 The front zone
9.3 Relative permeability and residual saturation
9.4 Viscous fingering
Further reading
Appendices
A Thermodynamic potentials
B Energy of a liquid film
C Interfacial areas of a spherical cap
D Bruggeman equation
编辑手记
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