عنوان

Thin-film catalysts for proton exchange membrane water electrolyzers and unitized regenerative fuel cells /

(Number (ISBN

3030208583

(Number (ISBN

3030208591

(Number (ISBN

3030208605

(Number (ISBN

3030208613

(Number (ISBN

9783030208585

(Number (ISBN

9783030208592

(Number (ISBN

9783030208608

(Number (ISBN

9783030208615

Erroneous ISBN

9783030208585

Title Proper

Thin-film catalysts for proton exchange membrane water electrolyzers and unitized regenerative fuel cells /

General Material Designation

[Book]

First Statement of Responsibility

Peter Kúš.

Place of Publication, Distribution, etc.

Cham, Switzerland :

Name of Publisher, Distributor, etc.

Springer,

Date of Publication, Distribution, etc.

[2019]

Specific Material Designation and Extent of Item

1 online resource

Series Title

Springer theses,

ISSN of Series

2190-5061

Text of Note

Includes bibliographical references.

Text of Note

Intro; Supervisor's Foreword; Abstract; Acknowledgements; Contents; Abbreviations; 1 Introduction; 1.1 Hydrogen Economy; 1.2 Proton Exchange Membrane Fuel Cell (PEM-FC); 1.3 Proton Exchange Membrane Water Electrolyzer (PEM-WE); 1.4 Proton Exchange Membrane Unitized Regenerative Fuel Cell (PEM-URFC); 1.5 Performance and Efficiency of PEM-FC, PEM-WE and PEM-URFC; 1.6 Thesis Motivation and Targets; References; 2 Experimental; 2.1 Magnetron Sputtering; 2.2 Scanning Electron Microscopy (SEM); 2.3 Atomic Force Microscopy (AFM); 2.4 Photoelectron Spectroscopy (PES)

Text of Note

2.5 Electrochemical Measurements and CharacterizationsReferences; 3 Results; 3.1 PEM-WE Testing Cell Setup; 3.2 Thin-Film Catalyst Deposition and Noble Metal Loading Determination; 3.3 Thin-Film Magnetron Sputtered Anode Catalyst for PEM-WE; 3.3.1 Ir Thin-Film Catalyst Sputtered Directly on Membrane; 3.3.2 Ir Thin-Film Catalyst Sputtered on Ti Mesh GDL; 3.3.3 Ir Thin-Film Catalyst Sputtered on Ti-Coated Carbon Paper GDL; 3.3.4 Ir Supported on TiC Nanoparticles; 3.3.5 Further Optimization of Experimental PEM-WE MEA with Ir Thin-Film Catalyst Supported on TiC Particles (PEM and Anode GDL)

Text of Note

3.4 Thin-Film Magnetron Sputtered Catalyst for PEM-URFC3.4.1 Reference Performances of Dedicated PEM-WE and PEM-FC Cells; 3.4.2 Thin-Film Bifunctional Anode Catalyst for PEM-URFC (Pt-Ir Co-sputtering); 3.4.3 Thin-Film Bifunctional Anode Catalyst for PEM-URFC (Pt, Ir Sandwich Sputtering); 3.5 Round-Trip Efficiency of PEM-URFC with Thin-Film Bifunctional Anode Catalyst; References; 4 Summary and Conclusions; Author's CV

0

8

8

Text of Note

This work revolves around the hydrogen economy and energy-storage electrochemical systems. More specifically, it investigates the possibility of using magnetron sputtering for deposition of efficient thin-film anode catalysts with low noble metal content for proton exchange membrane water electrolyzers (PEM-WEs) and unitized regenerative fuel cells (PEM-URFCs). The motivation for this research derives from the urgent need to minimize the price of such electrochemical devices should they enter the mass production. Numerous experiments were carried out, correlating the actual in-cell performance with the varying position of thin-film catalyst within the membrane electrode assembly, with the composition of high-surface support sublayer and with the chemical structure of the catalyst itself. The wide arsenal of analytical methods ranging from electrochemical impedance spectroscopy through electrochemical atomic force microscopy to photoelectron spectroscopy allowed the description ofthe complex phenomena behind different obtained efficiencies. Systematic optimizations led to the design of a novel PEM-WE anode thin-film iridium catalyst which performs similarly to the standard counterparts despite using just a fraction of their noble metal content. Moreover, the layer-by-layer approach resulted in the design of a Ir/TiC/Pt bi-functional anode for PEM-URFC which is able to operate in both the fuel cell and electrolyzer regime and thus helps to cut the cost of the whole conversion system even further.

Source for Acquisition/Subscription Address

Springer Nature

Stock Number

com.springer.onix.9783030208592

International Standard Book Number

9783030208585

International Standard Book Number

9783030208608

International Standard Book Number

9783030208615

Proton exchange membrane fuel cells.

Thin films.

Proton exchange membrane fuel cells.

TECHNOLOGY & ENGINEERING-- Mechanical.

Thin films.

PHFC

PHFC

TEC-- 009070

Number

Edition

Class number

Kúš, Peter

Date of Transaction

20200823091715.0

Cataloguing Rules (Descriptive Conventions))

pn

Electronic name

[Book]

Y