Gaseous and Electrochemical Hydrogen Storage Properties of Mg-Based Thin Films

This thesis introduces the preparation of a series of Mg-based thin films with different structures using magnetron sputtering, as well as the systematical investigation of their gaseous and electrochemical hydrogen storage properties under mild conditions. It reviews promising applications of Mg-based thin films in smart windows, hydrogen sensors and Ni-MH batteries, while also providing significant insights into research conducted on Mg-based hydrogen storage materials, especially the Mg-based films. Moreover, the unique experimental procedures and methods (including electric resistance, optical transmittance and electrochemical methods) used in this thesis will serve as a valuable reference for researchers in the field of Mg-based hydrogen storage films.

Nominated by Peking University as an outstanding Ph.D. thesis Reports on the important progress made in the study of Mg-based hydrogen storage thin films Introduces applications for smart windows, hydrogen sensors and NiMH batteries Provides novel experimental methods for Mg-based thin films Includes supplementary material: sn.pub/extras

Autorentext

Klappentext
In this thesis, the author introduces the preparation of a series of Mg-based thin films with different structures by magnetron sputtering, and the systematical investigation of their gaseous and electrochemical hydrogen storage properties under mild conditions. The promising applications of Mg-based thin films in smart windows, hydrogen sensors and Ni-MH batteries are also reviewed. The research work presented in this thesis offers significant perspectives on the research of Mg-based hydrogen storage materials, especially the Mg-based films. Moreover, the unique experimental procedures and methods (including the electric resistance, optical transmittance and electrochemical methods) used in this thesis can also provide valuable reference for the researchers in the field of Mg-based hydrogen storage films.

Inhalt
Introduction.- The Effects of Ti, Al Interlayers on the Hydrogen Storage Properties of 100nm Mg-Pd Films under Mild Conditions.- The Effects of Structure Tailoring on the Gaseous and Electrochemical Hydrogen Storage Properties of 500nm Mg-Pd Films under Mild Conditions.- The Effects of Morphologies on the Gaseous and Electrochemical Hydrogen Storage Properties of 200nm Mg-Pd Films.- The Effects of Different Mg-Ti Atom Ratios on the Electrochemical Hydrogen Storage Properties of Mgxti1-X-Pd Films.- Conclusions and Outlooks.