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Published by Springer, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: Majestic Books, Hounslow, United Kingdom
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Condition: New. pp. 284 52:B&W 6.14 x 9.21in or 234 x 156mm (Royal 8vo) Case Laminate on White w/Gloss Lam.
Published by Springer, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: Books Puddle, New York, NY, U.S.A.
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Condition: New. pp. 284.
Published by de Gruyter, 1963
ISBN 10: 3111010597ISBN 13: 9783111010595
Seller: PBShop.store UK, Fairford, GLOS, United Kingdom
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HRD. Condition: New. New Book. Delivered from our UK warehouse in 4 to 14 business days. THIS BOOK IS PRINTED ON DEMAND. Established seller since 2000.
Published by Springer Berlin, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: Buchpark, Trebbin, Germany
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Condition: Sehr gut. 2008. Neubindung, Buchschnitt etwas zu weit abgeschnitten 4485363/12.
Published by Springer, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: Research Ink, Takoma Park, MD, U.S.A.
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Hardcover. Condition: Very Good. Dust Jacket Included. 270 pp. Advances in Polymer Science, 215. Rubber-stamped o the title page. book.
Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: Research Ink, Takoma Park, MD, U.S.A.
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Hardcover. Condition: Very Good. Dust Jacket Included. xi + 261 pp. Advances in Polymer Sciencee, 216. Rubber-stamped on half page. book.
Published by Göttingen & Toronto : Verlag für Psychologie Hogrefe, 1985
ISBN 10: 3801702200ISBN 13: 9783801702205
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24 x 16,5 cm. Condition: Gut. XI, 228 Seiten ; Mit Abbildungen und Tabellen Original Broschur mit Bibliotheksklebeband. Angestaubt und verschossen. Innen mit Bibliotheksstempeln, sehr sauberes Exemplar B08-01-06C|S30 Sprache: Deutsch Gewicht in Gramm: 382.
Published by de Gruyter, 1963
ISBN 10: 3111010597ISBN 13: 9783111010595
Seller: PBShop.store US, Wood Dale, IL, U.S.A.
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Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: Romtrade Corp., STERLING HEIGHTS, MI, U.S.A.
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Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: Basi6 International, Irving, TX, U.S.A.
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Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
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Published by Springer Berlin, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: Buchpark, Trebbin, Germany
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Condition: Sehr gut. 2008. Neubindung 4485569/12.
Published by Springer, 2010
ISBN 10: 3642089151ISBN 13: 9783642089152
Seller: booksXpress, Bayonne, NJ, U.S.A.
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Published by Springer, 2010
ISBN 10: 3642089143ISBN 13: 9783642089145
Seller: booksXpress, Bayonne, NJ, U.S.A.
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Published by Springer Berlin Heidelberg, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: moluna, Greven, Germany
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Gebunden. Condition: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Highest Impact Factor of all journals ranked by ISI within Polymer ScienceShort and concise reports on physics and chemistry of polymers, each written by the world renowned expertsStill valid and useful after 5 or 10 yearsThe electro.
Published by Springer Berlin Heidelberg, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: moluna, Greven, Germany
Book Print on Demand
Gebunden. Condition: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Highest Impact Factor of all journals ranked by ISI within Polymer ScienceShort and concise reports on physics and chemistry of polymers, each written by the world renowned expertsStill valid and useful after 5 or 10 yearsThe electro.
Published by Springer Berlin Heidelberg, 2010
ISBN 10: 3642089151ISBN 13: 9783642089152
Seller: moluna, Greven, Germany
Book Print on Demand
Condition: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Highest Impact Factor of all journals ranked by ISI within Polymer ScienceShort and concise reports on physics and chemistry of polymers, each written by the world renowned expertsStill valid and useful after 5 or 10 yearsThe electro.
Published by Springer Berlin Heidelberg, 2010
ISBN 10: 3642089143ISBN 13: 9783642089145
Seller: moluna, Greven, Germany
Book Print on Demand
Condition: New. Dieser Artikel ist ein Print on Demand Artikel und wird nach Ihrer Bestellung fuer Sie gedruckt. Highest Impact Factor of all journals ranked by ISI within Polymer ScienceShort and concise reports on physics and chemistry of polymers, each written by the world renowned expertsStill valid and useful after 5 or 10 yearsThe electro.
Published by Springer, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: booksXpress, Bayonne, NJ, U.S.A.
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Published by Springer, 2010
ISBN 10: 3642089143ISBN 13: 9783642089145
Seller: Ria Christie Collections, Uxbridge, United Kingdom
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Published by Springer, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: Ria Christie Collections, Uxbridge, United Kingdom
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Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: Ria Christie Collections, Uxbridge, United Kingdom
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Condition: New. PRINT ON DEMAND Book; New; Fast Shipping from the UK. No. book.
Published by Springer, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: booksXpress, Bayonne, NJ, U.S.A.
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Hardcover. Condition: new.
Published by Springer Berlin Heidelberg, 2010
ISBN 10: 3642089143ISBN 13: 9783642089145
Seller: AHA-BUCH GmbH, Einbeck, Germany
Book
Taschenbuch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC).
Published by Springer Berlin Heidelberg Sep 2008, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: BuchWeltWeit Ludwig Meier e.K., Bergisch Gladbach, Germany
Book Print on Demand
Buch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC). 284 pp. Englisch.
Published by Springer Berlin Heidelberg Sep 2008, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: BuchWeltWeit Ludwig Meier e.K., Bergisch Gladbach, Germany
Book Print on Demand
Buch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC). 276 pp. Englisch.
Published by Springer Berlin Heidelberg Nov 2010, 2010
ISBN 10: 3642089143ISBN 13: 9783642089145
Seller: BuchWeltWeit Ludwig Meier e.K., Bergisch Gladbach, Germany
Book Print on Demand
Taschenbuch. Condition: Neu. This item is printed on demand - it takes 3-4 days longer - Neuware -The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC). 284 pp. Englisch.
Published by Springer Berlin Heidelberg, 2008
ISBN 10: 3540697551ISBN 13: 9783540697558
Seller: AHA-BUCH GmbH, Einbeck, Germany
Book
Buch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC).
Published by Springer Berlin Heidelberg, 2008
ISBN 10: 3540697632ISBN 13: 9783540697633
Seller: AHA-BUCH GmbH, Einbeck, Germany
Book
Buch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC).
Published by Springer Berlin Heidelberg, 2010
ISBN 10: 3642089151ISBN 13: 9783642089152
Seller: AHA-BUCH GmbH, Einbeck, Germany
Book
Taschenbuch. Condition: Neu. Druck auf Anfrage Neuware - Printed after ordering - The concept to utilize an ion-conducting polymer membrane as a solid po- mer electrolyte offers several advantages regarding the design and operation of an electrochemical cell, as outlined in Volume 215, Chapter 1 (L. Gubler, G.G. Scherer). Essentially, the solvent and/or transport medium, e.g., H O, 2 + for the mobile ionic species, e.g., H for a cation exchange membrane, is taken up by and con ned into the nano-dimensional morphology of the i- containingdomainsofthepolymer.Asaconsequence, aphaseseparationinto a hydrophilic ion-containing solvent phase and a hydrophobic polymer ba- bone phase establishes. Because of the narrow solid electrolyte gap in these cells, low ohmic losses reducing the overall cell voltage can be achieved, even at highcurrent densities. This concept was applied to fuel cell technology at a very early stage; h- ever, performance and reliability of the cells were low due to the dissatisfying membrane properties at that time. The development of per uoro sulfonate and carboxylate-type membranes, in particular for the chlor-alkali process, directly fostered the further development of proton-conducting membranes and, as a consequence, also the progress in this type of fuel cell technology (polymer electrolyte fuel cell,PEFC).