Creation of New Metal Nanoparticles and Their Hydrogen-Storage and Catalytic Properties

This thesis reports the discovery of metal nanoparticles having new structures that do not exist in bulk state and that exhibit hydrogen storage ability or CO oxidation activity. Research into the reaction of hydrogen with metals has attracted much attention because of potential applications as effe...

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Bibliographic Details
Main Author: Kusada, Kohei
Format: eBook
Language:English
Published: Tokyo Springer Japan 2014, 2014
Edition:1st ed. 2014
Series:Springer Theses, Recognizing Outstanding Ph.D. Research
Subjects:
Online Access:
Collection: Springer eBooks 2005- - Collection details see MPG.ReNa
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245 0 0 |a Creation of New Metal Nanoparticles and Their Hydrogen-Storage and Catalytic Properties  |h Elektronische Ressource  |c by Kohei Kusada 
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505 0 |a From the Contents: General Introduction -- Hydrogen Storage Properties of Solid Solution Alloys Immiscible Neighboring Elements with Pd -- Systematic Study of the Hydrogen Storage Properties and the CO-oxidizing Abilities of Solid Solution Alloy Nanoparticles in an Immiscible Pd-Ru System 
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653 |a Energy storage 
653 |a Catalysis 
653 |a Energy Storage 
653 |a Nanotechnology 
653 |a Nanotechnology 
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520 |a This thesis reports the discovery of metal nanoparticles having new structures that do not exist in bulk state and that exhibit hydrogen storage ability or CO oxidation activity. Research into the reaction of hydrogen with metals has attracted much attention because of potential applications as effective hydrogen storage materials, as permeable films, or as catalysts for hydrogenation. Also, CO oxidation catalysts have been extensively developed because of their importance to CO removal from car exhaust or fuel-cell systems.  At the same time, atomic-level (solid solution) alloying has the advantage of being able to continuously control chemical and physical properties of elements by changing compositions and/or combinations of constituent elements. This thesis provides a novel strategy for the basis of inter-elemental fusion to create highly efficient functional materials for energy and material conversions