Welcome Guest
  |   0 items in your shopping cart
 

BROWSE BY STANDARDS

BROWSE BY CATEGORY

***
 
 
Join our mailing list to recieve newsletters
 

Solar Hydrogen Generation : Transition Metal Oxides in Water Photoelectrolysis

Send to friend
 
Title: Solar Hydrogen Generation : Transition Metal Oxides in Water Photoelectrolysis
Author: Jinghua Guo, Xiaobo Chen
ISBN: 0071701265 / 9780071701266
Format: Hard Cover
Pages: 208
Publisher: McGraw-Hill
Year: 2012
Availability: In Stock
     
 
  • Description
  • Contents

State-of-the-art renewable energy science research and applications

Solar Hydrogen Generation : Transition Metal Oxides in Water Photoelectrolysis provides expert techniques for extracting hydrogen from water using transition metal oxides as catalysts. The basic processes of electrochemistry and photocatalysis for hydrogen production are described along with photocatalytic reactions and semiconductor photocatalysts, particularly metal oxides.

This in-depth guide illustrates the corresponding crystal structure vs. electronic structure and optical properties vs. light absorption of transition metal oxides. Impurity and doped photocatalysts, integrated organic and inorganic systems, surface and interface chemistry, and nanostructure and morphology in photocatalysis applications are all addressed. This comprehensive resource introduces soft x-ray absorption (XAS), soft x-ray emission spectroscopy (XES), and resonant inelastic soft x-ray scattering (RIXS), followed by a description of instrumentation.

Preface

Chapter 1 : Hydrogen Generation : Electrochemistry and Photoelectrolysis
Chapter 2 : Photocatalytic Reactions, Oxidation, and Reduction
Chapter 3 : Transition Metal Oxides
Chapter 4 : Crystal Structure and Electronic Structure
Chapter 5 : Optical Properties and Light Absorption
Chapter 6 : Impurity, Dopants, and Defects
Chapter 7 : Surface and Morphology
Chapter 8 : Soft X-ray Spectroscopy and Electronic Structure

References
Index

 
 
 
About Us | Contact us
loading...
This page was created in 0.38353896141052 seconds