Coverart for item
The Resource Non-equilibrium evaporation and condensation processes : analytical solutions, Yuri B. Zudin

Non-equilibrium evaporation and condensation processes : analytical solutions, Yuri B. Zudin

Label
Non-equilibrium evaporation and condensation processes : analytical solutions
Title
Non-equilibrium evaporation and condensation processes
Title remainder
analytical solutions
Statement of responsibility
Yuri B. Zudin
Creator
Author
Subject
Language
eng
Summary
This monograph presents a comprehensive treatment of analytical solutions to problems in the area of non-equilibrium evaporation and condensation processes. The book covers, among others, topics such as systems of conversation equations for molecular fluxes of mass, momentum and energy within the Knudsen layer, spherical growth of vapor bubbles in volumes of highly superheated liquid. The target audience primarily comprises research experts in the field of thermodynamics and fluid dynamics, but the book may also be beneficial for graduate students alike
Member of
Cataloging source
N$T
http://library.link/vocab/creatorName
Zudin, I︠U︡. B.
Dewey number
  • 536/.44
  • 620
Index
index present
LC call number
QC304
Literary form
non fiction
Nature of contents
  • dictionaries
  • bibliography
Series statement
Mathematical engineering
http://library.link/vocab/subjectName
  • Evaporation
  • Condensation
  • Nonequilibrium thermodynamics
Label
Non-equilibrium evaporation and condensation processes : analytical solutions, Yuri B. Zudin
Instantiates
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Preface; Contents; 1 Introduction to the Problem; 1.1 Kinetic Molecular Theory; 1.2 Discussing the Boltzmann Equation; 1.3 Precise Solution to the Boltzmann Equation; 1.4 Intensive Phase Change; References; 2 Nonequilibrium Effects on the Phase Interface; 2.1 Conservation Equations of Molecular Flows; 2.1.1 The Distribution Function; 2.1.2 Molecular Flows; 2.2 Evaporation into Vacuum; 2.2.1 The Hertz-Knudsen Equation; 2.2.2 Modifications of the Hertz-Knudsen Equation; 2.3 Extrapolated Boundary Conditions; 2.4 Accommodation Coefficients; 2.5 Linear Kinetic Theory; 2.5.1 Low Intensity Processes
  • 2.5.2 Impermeable Interface (Heat Transport)2.5.3 Impermeable Interface (Momentum Transport); 2.5.4 Phase Change; 2.5.5 Special Boundary Conditions; 2.6 Introduction into the Problem of Strong Evaporation; 2.6.1 Conservation Equations; 2.6.2 The Model of Crout; 2.6.3 The Model of Anisimov; 2.6.4 The Model of Rose; 2.6.5 The Mixing Model; References; 3 Approximate Kinetic Analysis of Strong Evaporation; 3.1 Conservation Equations; 3.2 Mixing Surface; 3.3 Limiting Mass Flux; 3.4 Conclusions; References; 4 Semi-empirical Model of Strong Evaporation; 4.1 Strong Evaporation
  • 4.2 Approximate Analytical Models4.3 Analysis of the Available Approaches; 4.4 The Semi-empirical Model; 4.4.1 Linear Jumps; 4.4.2 Nonlinear Jumps; 4.4.3 Summarized Jumps; 4.4.4 Design Relations; 4.5 Validation of the Semi-empirical Model; 4.5.1 Monatomic Gas \left( \varvec{\beta = 1} \right) ; 4.5.2 Monatomic Gas \varvec{(0 \lt \beta \le 1)} ; 4.5.3 Sonic Evaporation \left( \varvec{0 \lt \beta \le 1} \right) ; 4.5.4 Polyatomic Gas \left( \varvec{\beta = 1} \right) ; 4.5.5 Maximum Mass Flow; 4.6 Final Remarks; 4.7 Conclusions; References; 5 Approximate Kinetic Analysis of Strong Condensation
  • 5.1 Macroscopic Models5.2 Strong Evaporation; 5.3 Strong Condensation; 5.4 The Mixing Model; 5.5 Solution Results; 5.6 Sonic Condensation; 5.7 Supersonic Condensation; 5.8 Conclusions; References; 6 Linear Kinetic Analysis of Evaporation and Condensation; 6.1 Conservation Equations; 6.2 Equilibrium Coopling Conditions; 6.3 Linear Kinetic Analysis; 6.3.1 Linearized System of Equations; 6.3.2 Symmetric and Asymmetric Cases; 6.3.3 Kinetic Jumps; 6.3.4 Short Description; 6.4 Conclusions; References; 7 Binary Schemes of Vapor Bubble Growth; 7.1 Limiting Schemes of Growth
  • 7.2 The Energetic Thermal Scheme7.2.1 The Jakob Number; 7.2.2 The Plesset-Zwick Formula; 7.2.3 Solution of Scriven; 7.2.4 Approximations; 7.3 Binary Schemes of Growth; 7.3.1 The Viscous-Inertial Scheme; 7.3.2 The Nonequilibrium-Thermal Scheme; 7.3.3 The Inertial-Thermal Scheme; 7.3.4 The Region of High Superheatings; 7.4 Conclusions; References; 8 The Pressure Blocking Effect in a Growing Vapor Bubble; 8.1 The Inertial-Thermal Scheme; 8.2 Pressure Blocking Effect; 8.3 The Stefan Number in the Metastable Region; 8.4 Effervescence of the Butane Drop; 8.5 Seeking an Analytical Solution
Control code
SPR1004225480
Dimensions
unknown
Extent
1 online resource.
File format
unknown
Form of item
online
Isbn
9783319673066
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
  • on1004225480
  • (OCoLC)1004225480
Label
Non-equilibrium evaporation and condensation processes : analytical solutions, Yuri B. Zudin
Publication
Antecedent source
unknown
Bibliography note
Includes bibliographical references and index
Carrier category
online resource
Carrier category code
  • cr
Carrier MARC source
rdacarrier
Color
multicolored
Content category
text
Content type code
  • txt
Content type MARC source
rdacontent
Contents
  • Preface; Contents; 1 Introduction to the Problem; 1.1 Kinetic Molecular Theory; 1.2 Discussing the Boltzmann Equation; 1.3 Precise Solution to the Boltzmann Equation; 1.4 Intensive Phase Change; References; 2 Nonequilibrium Effects on the Phase Interface; 2.1 Conservation Equations of Molecular Flows; 2.1.1 The Distribution Function; 2.1.2 Molecular Flows; 2.2 Evaporation into Vacuum; 2.2.1 The Hertz-Knudsen Equation; 2.2.2 Modifications of the Hertz-Knudsen Equation; 2.3 Extrapolated Boundary Conditions; 2.4 Accommodation Coefficients; 2.5 Linear Kinetic Theory; 2.5.1 Low Intensity Processes
  • 2.5.2 Impermeable Interface (Heat Transport)2.5.3 Impermeable Interface (Momentum Transport); 2.5.4 Phase Change; 2.5.5 Special Boundary Conditions; 2.6 Introduction into the Problem of Strong Evaporation; 2.6.1 Conservation Equations; 2.6.2 The Model of Crout; 2.6.3 The Model of Anisimov; 2.6.4 The Model of Rose; 2.6.5 The Mixing Model; References; 3 Approximate Kinetic Analysis of Strong Evaporation; 3.1 Conservation Equations; 3.2 Mixing Surface; 3.3 Limiting Mass Flux; 3.4 Conclusions; References; 4 Semi-empirical Model of Strong Evaporation; 4.1 Strong Evaporation
  • 4.2 Approximate Analytical Models4.3 Analysis of the Available Approaches; 4.4 The Semi-empirical Model; 4.4.1 Linear Jumps; 4.4.2 Nonlinear Jumps; 4.4.3 Summarized Jumps; 4.4.4 Design Relations; 4.5 Validation of the Semi-empirical Model; 4.5.1 Monatomic Gas \left( \varvec{\beta = 1} \right) ; 4.5.2 Monatomic Gas \varvec{(0 \lt \beta \le 1)} ; 4.5.3 Sonic Evaporation \left( \varvec{0 \lt \beta \le 1} \right) ; 4.5.4 Polyatomic Gas \left( \varvec{\beta = 1} \right) ; 4.5.5 Maximum Mass Flow; 4.6 Final Remarks; 4.7 Conclusions; References; 5 Approximate Kinetic Analysis of Strong Condensation
  • 5.1 Macroscopic Models5.2 Strong Evaporation; 5.3 Strong Condensation; 5.4 The Mixing Model; 5.5 Solution Results; 5.6 Sonic Condensation; 5.7 Supersonic Condensation; 5.8 Conclusions; References; 6 Linear Kinetic Analysis of Evaporation and Condensation; 6.1 Conservation Equations; 6.2 Equilibrium Coopling Conditions; 6.3 Linear Kinetic Analysis; 6.3.1 Linearized System of Equations; 6.3.2 Symmetric and Asymmetric Cases; 6.3.3 Kinetic Jumps; 6.3.4 Short Description; 6.4 Conclusions; References; 7 Binary Schemes of Vapor Bubble Growth; 7.1 Limiting Schemes of Growth
  • 7.2 The Energetic Thermal Scheme7.2.1 The Jakob Number; 7.2.2 The Plesset-Zwick Formula; 7.2.3 Solution of Scriven; 7.2.4 Approximations; 7.3 Binary Schemes of Growth; 7.3.1 The Viscous-Inertial Scheme; 7.3.2 The Nonequilibrium-Thermal Scheme; 7.3.3 The Inertial-Thermal Scheme; 7.3.4 The Region of High Superheatings; 7.4 Conclusions; References; 8 The Pressure Blocking Effect in a Growing Vapor Bubble; 8.1 The Inertial-Thermal Scheme; 8.2 Pressure Blocking Effect; 8.3 The Stefan Number in the Metastable Region; 8.4 Effervescence of the Butane Drop; 8.5 Seeking an Analytical Solution
Control code
SPR1004225480
Dimensions
unknown
Extent
1 online resource.
File format
unknown
Form of item
online
Isbn
9783319673066
Level of compression
unknown
Media category
computer
Media MARC source
rdamedia
Media type code
  • c
Quality assurance targets
not applicable
Reformatting quality
unknown
Sound
unknown sound
Specific material designation
remote
System control number
  • on1004225480
  • (OCoLC)1004225480

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