Verfügbarkeit: Non-equilibrium thermodynamics of heterogeneous systems

Non-equilibrium thermodynamics of heterogeneous systems:

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Bibliographische Detailangaben
Hauptverfasser:	Kjelstrup, Signe (VerfasserIn), Bedeaux, Dick 1941- (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Hackensack, NJ [u.a.] World Scientific 2008
Schriftenreihe:	Series on advances in statistical mechanics 16
Schlagworte:	Termodinámica de no equilibrio Nonequilibrium thermodynamics Nichtgleichgewichtsthermodynamik Transportprozess Heterogenes System
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Literaturverz. S. 393 - 413
Beschreibung:	XV, 434 S. Ill., graph. Darst.
ISBN:	9789812779137 9812779132

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Datensatz im Suchindex

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adam_text	Contents Preface vu 1 Scope 1 1.1 What is non-equilibrium thermodynamics? ......... 1 1.2 Non-equilibrium thermodynamics in the context of other theories ......................... 4 1.3 The purpose of this book ................... 4 2 Why Non-Equilibrium Thermodynamics? 7 2.1 Simple flux equations ..................... 8 2.2 Flux equations with coupling terms ............. 9 2.3 Experimental designs and controls .............. 11 2.4 Entropy production, work and lost work .......... 12 2.5 Consistent thermodynamic models .............. 14 3 Thermodynamic Relations for Heterogeneous Systems 17 3.1 Two homogeneous phases separated by a surface in global equilibrium ........................... 18 3.2 The contact line in global equilibrium ............ 22 3.3 Defining thermodynamic variables for the surface ..... 23 3.4 Local thermodynamic identities ............... 29 3.5 Defining local equilibrium .................. 32 3.A Appendix: Partial molar properties ............. 35 3.A.1 Homogeneous phases ................. 36 3.A.2 The surface ...................... 38 3.A.3 The standard state .................. 40 Part A: General Theory 45 4 The Entropy Production for a Homogeneous Phase 47 4.1 Balance equations ....................... 49 4.2 The entropy production .................... 51 χ Contents 4.2.1 Why one should not use the dissipation function . 56 4.2.2 States with minimum entropy production ..... 57 4.3 Examples ............................ 58 4.4 Frames of reference for fluxes in homogeneous systems . . 64 4.4.1 Definitions of frames of reference .......... 64 4.4.2 Transformations between the frames of reference . 66 4.A Appendix: The first law and the heat flux ......... 67 5 The Excess Entropy Production for the Surface 73 5.1 The discrete nature of the surface .............. 74 5.2 The behavior of the electric fields and potential through the surface ............................. 75 5.3 Balance equations ....................... 77 5.4 The excess entropy production ................ 79 5.4.1 Reversible processes at the interface and the Nernst equation ....................... 84 5.4.2 The surface potential jump at the hydrogen electrode ....................... 86 5.5 Examples ............................ 87 6 The Excess Entropy Production for a Three Phase Contact Line 91 6.1 The discrete nature of the contact line ........... 92 6.2 Balance equations ....................... 94 6.3 The excess entropy production ................ 95 6.4 Stationary states ....................... 96 6.5 Concluding comment ..................... 97 7 Flux Equations and Onsager Relations 99 7.1 Flux-force relations ...................... 99 7.2 Onsager s reciprocal relations ................ 100 7.3 Relaxation to equilibrium. Consequences of violating Onsager relations ....................... 104 7.4 Force-flux relations ...................... 105 7.5 Coefficient bounds ...................... 106 7.6 The Curie principle applied to surfaces and contact lines . 108 8 Transport of Heat and Mass 111 8.1 The homogeneous phases ................... 112 8.2 Coefficient values for homogeneous phases ......... 114 8.3 The surface .......................... 117 8.3.1 Heats of transfer for the surface .......... 119 Contents xj 8.4 Solution for the heterogeneous system ............ 122 8.5 Scaling relations between surface and bulk resistivities . . 125 9 Transport of Heat and Charge 127 9.1 The homogeneous phases ................... 128 9.2 The surface .......................... 130 9.3 Thermoelectric coolers .................... 132 9.4 Thermoelectric generators .................. 133 9.5 Solution for the heterogeneous system ............ 135 10 Transport of Mass and Charge 139 10.1 The electrolyte ......................... 140 10.2 The electrode surfaces .................... 143 10.3 Solution for the heterogeneous system ............ 146 10.4 A salt power plant ...................... 147 10.5 Electric power from volume flow ............... 148 10.6 Ionic mobility model for the electrolyte ........... 150 10.7 Ionic and electronic model for the surface .......... 154 Part B: Applications 155 11 Evaporation and Condensation 157 11.1 Evaporation and condensation in a pure fluid ....... 158 11.1.1 The entropy production and the flux equations . . 158 11.1.2 Interface resistivities from kinetic theory ..... 165 11.2 The sign of the heats of transfer of the surface ....... 167 11.3 Coefficients from molecular dynamics simulations ..... 169 11.4 Evaporation and condensation in a two-component fluid . 176 11.4.1 The entropy production and the flux equations . . 176 11.4.2 Interface resistivities from kinetic theory ..... 179 12 Multi-Component Heat and Mass Diffusion 183 12.1 The homogeneous phases ................... 184 12.2 The Maxwell-Stefan equations for multi-component diffusion ............................ 186 12.3 The Maxwell-Stefan equations for the surface ....... 188 12.4 Multi-component diffusion .................. 192 12.4.1 Prigogine s theorem ................. 192 12.4.2 Diffusion in the solvent frame of reference ..... 193 12.4.3 Other frames of reference .............. 195 12.4.4 An example: Kinetic demixing of oxides ...... 200 xii Contents 12.5 A relation between the heats of transfer and the enthalpy .......................... 202 13 A Nonisothermal Concentration Cell 205 13.1 The homogeneous phases ................... 207 13.1.1 Entropy production and flux equations for the anode ....................... 207 13.1.2 Position dependent transport coefficients ..... 210 13.1.3 The profiles of the homogeneous anode ...... 211 13.1.4 Contributions from the cathode .......... 212 13.1.5 The electrolyte contribution ............ 213 13.2 Surface contributions ..................... 214 13.2.1 The anode surface .................. 214 13.2.2 The cathode surface ................ 217 13.3 The thermoelectric potential ................ 218 14 The Transported Entropy 221 14.1 The Seebeck coefficient of cell a ............... 222 14.2 The transported entropy of Pb2+ in cell a ......... 226 14.3 The transported entropy of the cation in cell b ....... 227 14.4 The transported entropy of the ions cell с ......... 228 14.5 Transformation properties .................. 230 14.6 Concluding comments ..................... 232 15 Adiabatic Electrode Reactions 235 15.1 The homogeneous phases ................... 236 15.1.1 The silver phases ................... 236 15.1.2 The silver chloride phases .............. 236 15.1.3 The electrolyte .................... 237 15.2 The interfaces ......................... 237 15.2.1 The silver-silver chloride interfaces ......... 237 15.2.2 The silver chloride-electrolyte interfaces ...... 239 15.3 Temperature and electric potential profiles ......... 240 16 The Liquid Junction Potential 249 16.1 The flux equations for the electrolyte ............ 250 16.2 The liquid junction potential ................. 253 16.3 Liquid junction potential calculations compared ...... 255 16.4 Concluding comments ..................... 258 Contents xjjj 17 The Formation Cell 261 17.1 The isothermal cell...................... 263 17.1.1 The electromotive force ............... 263 17.1.2 The transference coefficient of the salt in the electrolyte .................... 263 17.1.3 An electrolyte with a salt concentration gradient . 265 17.1.4 The Planck potential derived from ionic fluxes and forces ....................... 267 17.2 A non-isothermal cell with a non-uniform electrolyte . . . 268 17.2.1 The homogeneous anode phase ........... 269 17.2.2 The electrolyte .................... 270 17.2.3 The surface of the anode .............. 272 17.2.4 The homogeneous phases and the surface of the cathode ...................... 273 17.2.5 The cell potential .................. 275 17.3 Concluding comments ..................... 275 18 Power from Regular and Thermal Osmosis 277 18.1 The potential work of a salt power plant .......... 277 18.2 The membrane as a barrier to transport of heat and mass ............................ 279 18.3 Membrane transport of heat and mass ........... 281 18.4 Osmosis ............................ 283 18.5 Thermal osmosis ........................ 285 19 Modeling the Polymer Electrolyte Fuel Cell 289 19.1 The potential work of a fuel cell ............... 290 19.2 The cell and its five subsystems ............... 291 19.3 The electrode backing and the membrane .......... 293 19.3.1 The entropy production in the homogeneous phases ......................... 293 19.3.2 The anode backing .................. 295 19.3.3 The membrane .................... 298 19.3.4 The cathode backing ................ 300 19.4 The electrode surfaces .................... 301 19.4.1 The anode catalyst surface ............. 304 19.4.2 The cathode catalyst surface ............ 306 19.5 A model in agreement with the second law ......... 307 19.6 Concluding comments ..................... 310 xiv Contents 20 Measuring Membrane Transport Properties 311 20.1 The membrane in equilibrium with electrolyte solutions . . 312 20.2 The membrane resistivity ................... 312 20.3 Ionic transport numbers ................... 316 20.4 The transference number of water and the water permeability ...................... 319 20.5 The Seebeck coefficient .................... 322 20.6 Interdiffusion coefficients ................... 323 21 The Impedance of an Electrode Surface 327 21.1 The hydrogen electrode. Mass balances ........... 328 21.2 The oscillating field ...................... 331 21.3 Reaction Gibbs energies ................... 332 21.4 The electrode surlace impedance ............... 332 21.4.1 The adsorption-diffusion layer in front of the catalyst ...................... 332 21.4.2 The charge transfer reaction ............ 336 21.4.3 The impedance spectrum .............. 337 21.5 A test of the model ...................... 338 21.6 The reaction overpotential .................. 339 22 Non-Equilibrium Molecular Dynamics Simulations 341 22.1 The system .......................... 344 22.1.1 The interaction potential .............. 346 22.2 Calculation techniques .................... 347 22.3 Verifying the assumption of local equilibrium ........ 351 22.3.1 Local equilibrium in a homogeneous binary mixture ........................ 351 22.3.2 Local equilibrium in a gas-liquid interface ..... 353 22.4 Verifications of the Onsager relations ............ 356 22.4.1 A homogeneous binary mixture ........... 356 22.4.2 A gas-liquid interface ................ 358 22.5 Linearity of the flux-force relations ............. 359 22.6 Molecular mechanisms .................... 359 23 The Non-Equilibrium Two-Phase van der Waals Model 361 23.1 Van der Waals equation of states .............. 363 23.2 Van der Waals square gradient model for the interfacial region .............................. 366 23.3 Balance equations ....................... 369 23.4 The entropy production .................... 371 23.5 Flux equations ......................... 372 Contents xv 23.6 A numerical solution method ................. 373 23.7 Procedure for extrapolation of bulk densities and fluxes . . 376 23.8 Defining excess densities ................... 378 23.9 Thermodynamic properties of Gibbs surface ........ 379 23.10 An autonomous surface .................... 380 23.11 Excess densities depend on the choice of dividing surface . 384 23.11.1 Properties of dividing surfaces ........... 384 23.11.2 Surface excess densities for two dividing surfaces ........................ 385 23.11.3 The surface temperature from excess density differences .................. 386 23.12 The entropy balance and the excess entropy production . . 388 23.13 Resistivities to heat and mass transfer ........... 390 23.14 Concluding comments . .................... 392 References 393 Symbol Lists 415 Index 423 About the Authors 433
adam_txt	Contents Preface vu 1 Scope 1 1.1 What is non-equilibrium thermodynamics? . 1 1.2 Non-equilibrium thermodynamics in the context of other theories . 4 1.3 The purpose of this book . 4 2 Why Non-Equilibrium Thermodynamics? 7 2.1 Simple flux equations . 8 2.2 Flux equations with coupling terms . 9 2.3 Experimental designs and controls . 11 2.4 Entropy production, work and lost work . 12 2.5 Consistent thermodynamic models . 14 3 Thermodynamic Relations for Heterogeneous Systems 17 3.1 Two homogeneous phases separated by a surface in global equilibrium . 18 3.2 The contact line in global equilibrium . 22 3.3 Defining thermodynamic variables for the surface . 23 3.4 Local thermodynamic identities . 29 3.5 Defining local equilibrium . 32 3.A Appendix: Partial molar properties . 35 3.A.1 Homogeneous phases . 36 3.A.2 The surface . 38 3.A.3 The standard state . 40 Part A: General Theory 45 4 The Entropy Production for a Homogeneous Phase 47 4.1 Balance equations . 49 4.2 The entropy production . 51 χ Contents 4.2.1 Why one should not use the dissipation function . 56 4.2.2 States with minimum entropy production . 57 4.3 Examples . 58 4.4 Frames of reference for fluxes in homogeneous systems . . 64 4.4.1 Definitions of frames of reference . 64 4.4.2 Transformations between the frames of reference . 66 4.A Appendix: The first law and the heat flux . 67 5 The Excess Entropy Production for the Surface 73 5.1 The discrete nature of the surface . 74 5.2 The behavior of the electric fields and potential through the surface . 75 5.3 Balance equations . 77 5.4 The excess entropy production . 79 5.4.1 Reversible processes at the interface and the Nernst equation . 84 5.4.2 The surface potential jump at the hydrogen electrode . 86 5.5 Examples . 87 6 The Excess Entropy Production for a Three Phase Contact Line 91 6.1 The discrete nature of the contact line . 92 6.2 Balance equations . 94 6.3 The excess entropy production . 95 6.4 Stationary states . 96 6.5 Concluding comment . 97 7 Flux Equations and Onsager Relations 99 7.1 Flux-force relations . 99 7.2 Onsager's reciprocal relations . 100 7.3 Relaxation to equilibrium. Consequences of violating Onsager relations . 104 7.4 Force-flux relations . 105 7.5 Coefficient bounds . 106 7.6 The Curie principle applied to surfaces and contact lines . 108 8 Transport of Heat and Mass 111 8.1 The homogeneous phases . 112 8.2 Coefficient values for homogeneous phases . 114 8.3 The surface . 117 8.3.1 Heats of transfer for the surface . 119 Contents xj 8.4 Solution for the heterogeneous system . 122 8.5 Scaling relations between surface and bulk resistivities . . 125 9 Transport of Heat and Charge 127 9.1 The homogeneous phases . 128 9.2 The surface . 130 9.3 Thermoelectric coolers . 132 9.4 Thermoelectric generators . 133 9.5 Solution for the heterogeneous system . 135 10 Transport of Mass and Charge 139 10.1 The electrolyte . 140 10.2 The electrode surfaces . 143 10.3 Solution for the heterogeneous system . 146 10.4 A salt power plant . 147 10.5 Electric power from volume flow . 148 10.6 Ionic mobility model for the electrolyte . 150 10.7 Ionic and electronic model for the surface . 154 Part B: Applications 155 11 Evaporation and Condensation 157 11.1 Evaporation and condensation in a pure fluid . 158 11.1.1 The entropy production and the flux equations . . 158 11.1.2 Interface resistivities from kinetic theory . 165 11.2 The sign of the heats of transfer of the surface . 167 11.3 Coefficients from molecular dynamics simulations . 169 11.4 Evaporation and condensation in a two-component fluid . 176 11.4.1 The entropy production and the flux equations . . 176 11.4.2 Interface resistivities from kinetic theory . 179 12 Multi-Component Heat and Mass Diffusion 183 12.1 The homogeneous phases . 184 12.2 The Maxwell-Stefan equations for multi-component diffusion . 186 12.3 The Maxwell-Stefan equations for the surface . 188 12.4 Multi-component diffusion . 192 12.4.1 Prigogine's theorem . 192 12.4.2 Diffusion in the solvent frame of reference . 193 12.4.3 Other frames of reference . 195 12.4.4 An example: Kinetic demixing of oxides . 200 xii Contents 12.5 A relation between the heats of transfer and the enthalpy . 202 13 A Nonisothermal Concentration Cell 205 13.1 The homogeneous phases . 207 13.1.1 Entropy production and flux equations for the anode . 207 13.1.2 Position dependent transport coefficients . 210 13.1.3 The profiles of the homogeneous anode . 211 13.1.4 Contributions from the cathode . 212 13.1.5 The electrolyte contribution . 213 13.2 Surface contributions . 214 13.2.1 The anode surface . 214 13.2.2 The cathode surface . 217 13.3 The thermoelectric potential . 218 14 The Transported Entropy 221 14.1 The Seebeck coefficient of cell a . 222 14.2 The transported entropy of Pb2+ in cell a . 226 14.3 The transported entropy of the cation in cell b . 227 14.4 The transported entropy of the ions cell с . 228 14.5 Transformation properties . 230 14.6 Concluding comments . 232 15 Adiabatic Electrode Reactions 235 15.1 The homogeneous phases . 236 15.1.1 The silver phases . 236 15.1.2 The silver chloride phases . 236 15.1.3 The electrolyte . 237 15.2 The interfaces . 237 15.2.1 The silver-silver chloride interfaces . 237 15.2.2 The silver chloride-electrolyte interfaces . 239 15.3 Temperature and electric potential profiles . 240 16 The Liquid Junction Potential 249 16.1 The flux equations for the electrolyte . 250 16.2 The liquid junction potential . 253 16.3 Liquid junction potential calculations compared . 255 16.4 Concluding comments . 258 Contents xjjj 17 The Formation Cell 261 17.1 The isothermal cell. 263 17.1.1 The electromotive force . 263 17.1.2 The transference coefficient of the salt in the electrolyte . 263 17.1.3 An electrolyte with a salt concentration gradient . 265 17.1.4 The Planck potential derived from ionic fluxes and forces . 267 17.2 A non-isothermal cell with a non-uniform electrolyte . . . 268 17.2.1 The homogeneous anode phase . 269 17.2.2 The electrolyte . 270 17.2.3 The surface of the anode . 272 17.2.4 The homogeneous phases and the surface of the cathode . 273 17.2.5 The cell potential . 275 17.3 Concluding comments . 275 18 Power from Regular and Thermal Osmosis 277 18.1 The potential work of a salt power plant . 277 18.2 The membrane as a barrier to transport of heat and mass . 279 18.3 Membrane transport of heat and mass . 281 18.4 Osmosis . 283 18.5 Thermal osmosis . 285 19 Modeling the Polymer Electrolyte Fuel Cell 289 19.1 The potential work of a fuel cell . 290 19.2 The cell and its five subsystems . 291 19.3 The electrode backing and the membrane . 293 19.3.1 The entropy production in the homogeneous phases . 293 19.3.2 The anode backing . 295 19.3.3 The membrane . 298 19.3.4 The cathode backing . 300 19.4 The electrode surfaces . 301 19.4.1 The anode catalyst surface . 304 19.4.2 The cathode catalyst surface . 306 19.5 A model in agreement with the second law . 307 19.6 Concluding comments . 310 xiv Contents 20 Measuring Membrane Transport Properties 311 20.1 The membrane in equilibrium with electrolyte solutions . . 312 20.2 The membrane resistivity . 312 20.3 Ionic transport numbers . 316 20.4 The transference number of water and the water permeability . 319 20.5 The Seebeck coefficient . 322 20.6 Interdiffusion coefficients . 323 21 The Impedance of an Electrode Surface 327 21.1 The hydrogen electrode. Mass balances . 328 21.2 The oscillating field . 331 21.3 Reaction Gibbs energies . 332 21.4 The electrode surlace impedance . 332 21.4.1 The adsorption-diffusion layer in front of the catalyst . 332 21.4.2 The charge transfer reaction . 336 21.4.3 The impedance spectrum . 337 21.5 A test of the model . 338 21.6 The reaction overpotential . 339 22 Non-Equilibrium Molecular Dynamics Simulations 341 22.1 The system . 344 22.1.1 The interaction potential . 346 22.2 Calculation techniques . 347 22.3 Verifying the assumption of local equilibrium . 351 22.3.1 Local equilibrium in a homogeneous binary mixture . 351 22.3.2 Local equilibrium in a gas-liquid interface . 353 22.4 Verifications of the Onsager relations . 356 22.4.1 A homogeneous binary mixture . 356 22.4.2 A gas-liquid interface . 358 22.5 Linearity of the flux-force relations . 359 22.6 Molecular mechanisms . 359 23 The Non-Equilibrium Two-Phase van der Waals Model 361 23.1 Van der Waals equation of states . 363 23.2 Van der Waals square gradient model for the interfacial region . 366 23.3 Balance equations . 369 23.4 The entropy production . 371 23.5 Flux equations . 372 Contents xv 23.6 A numerical solution method . 373 23.7 Procedure for extrapolation of bulk densities and fluxes . . 376 23.8 Defining excess densities . 378 23.9 Thermodynamic properties of Gibbs' surface . 379 23.10 An autonomous surface . 380 23.11 Excess densities depend on the choice of dividing surface . 384 23.11.1 Properties of dividing surfaces . 384 23.11.2 Surface excess densities for two dividing surfaces . 385 23.11.3 The surface temperature from excess density differences . 386 23.12 The entropy balance and the excess entropy production . . 388 23.13 Resistivities to heat and mass transfer . 390 23.14 Concluding comments . . 392 References 393 Symbol Lists 415 Index 423 About the Authors 433
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id	DE-604.BV035185531
illustrated	Illustrated
index_date	2024-07-02T22:59:30Z
indexdate	2024-07-09T21:26:58Z
institution	BVB
isbn	9789812779137 9812779132
language	English
lccn	2008299321
oai_aleph_id	oai:aleph.bib-bvb.de:BVB01-016992226
oclc_num	427535308
open_access_boolean
owner	DE-703 DE-91G DE-BY-TUM DE-11 DE-19 DE-BY-UBM
owner_facet	DE-703 DE-91G DE-BY-TUM DE-11 DE-19 DE-BY-UBM
physical	XV, 434 S. Ill., graph. Darst.
publishDate	2008
publishDateSearch	2008
publishDateSort	2008
publisher	World Scientific
record_format	marc
series	Series on advances in statistical mechanics
series2	Series on advances in statistical mechanics
spelling	Kjelstrup, Signe Verfasser aut Non-equilibrium thermodynamics of heterogeneous systems Signe Kjelstrup ; Dick Bedeaux Hackensack, NJ [u.a.] World Scientific 2008 XV, 434 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Series on advances in statistical mechanics 16 Literaturverz. S. 393 - 413 Termodinámica de no equilibrio Nonequilibrium thermodynamics Nichtgleichgewichtsthermodynamik (DE-588)4130850-5 gnd rswk-swf Transportprozess (DE-588)4185932-7 gnd rswk-swf Heterogenes System (DE-588)4159737-0 gnd rswk-swf Heterogenes System (DE-588)4159737-0 s Transportprozess (DE-588)4185932-7 s Nichtgleichgewichtsthermodynamik (DE-588)4130850-5 s DE-604 Bedeaux, Dick 1941- Verfasser (DE-588)1011535602 aut Series on advances in statistical mechanics 16 (DE-604)BV000019119 16 Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016992226&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Kjelstrup, Signe Bedeaux, Dick 1941- Non-equilibrium thermodynamics of heterogeneous systems Series on advances in statistical mechanics Termodinámica de no equilibrio Nonequilibrium thermodynamics Nichtgleichgewichtsthermodynamik (DE-588)4130850-5 gnd Transportprozess (DE-588)4185932-7 gnd Heterogenes System (DE-588)4159737-0 gnd
subject_GND	(DE-588)4130850-5 (DE-588)4185932-7 (DE-588)4159737-0
title	Non-equilibrium thermodynamics of heterogeneous systems
title_auth	Non-equilibrium thermodynamics of heterogeneous systems
title_exact_search	Non-equilibrium thermodynamics of heterogeneous systems
title_exact_search_txtP	Non-equilibrium thermodynamics of heterogeneous systems
title_full	Non-equilibrium thermodynamics of heterogeneous systems Signe Kjelstrup ; Dick Bedeaux
title_fullStr	Non-equilibrium thermodynamics of heterogeneous systems Signe Kjelstrup ; Dick Bedeaux
title_full_unstemmed	Non-equilibrium thermodynamics of heterogeneous systems Signe Kjelstrup ; Dick Bedeaux
title_short	Non-equilibrium thermodynamics of heterogeneous systems
title_sort	non equilibrium thermodynamics of heterogeneous systems
topic	Termodinámica de no equilibrio Nonequilibrium thermodynamics Nichtgleichgewichtsthermodynamik (DE-588)4130850-5 gnd Transportprozess (DE-588)4185932-7 gnd Heterogenes System (DE-588)4159737-0 gnd
topic_facet	Termodinámica de no equilibrio Nonequilibrium thermodynamics Nichtgleichgewichtsthermodynamik Transportprozess Heterogenes System
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016992226&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
volume_link	(DE-604)BV000019119
work_keys_str_mv	AT kjelstrupsigne nonequilibriumthermodynamicsofheterogeneoussystems AT bedeauxdick nonequilibriumthermodynamicsofheterogeneoussystems

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