Add to ORKGThis chapter is the 6th of the book "Structural Characterization Techniques: Advances and Applications in Clean Energy ". It starts with a general introduction on the diffraction techniques applied to hydrogen storage materials (section 6.1 and 6.2). It describes further in detail the in situ Powder Diffraction Experiment and gives exampels of successful investigations (section 6.3 and 6.4).JRC.C.1-Energy Storag
In situ diffraction techniques above all, offer the unique opportunity of probing in real time and u...
Materials for reversible hydrogen storage in the solid state constitute a subject of intensive resea...
In this article, the capabilities of soft and hard X-ray techniques, including X-ray absorption (XAS...
'Real life' energy-related materials such as solid-state hydrogen storage compounds or components of...
Synchrotron radiation is an advanced collimated light source with high intensity. It has particular ...
The world today is facing increasing energy demands and a simultaneous demand for cleaner and more e...
Diffraction-based methods offer unique advantages for elucidating the pathways by which materials ab...
Neutron powder diffraction is extensively used for the development and fundamental understanding of ...
Hydrogen forms more compounds than any other element in the Periodic Table, yet methods for accurate...
Hydrogen forms more compounds than any other element in the Periodic Table, yet methods for accurate...
The potential of neutron powder diffraction in the location of hydrogen atoms in molecular materials...
We introduce here diffraction in general, as well as neutron and powder diffraction in particular as...
The methods of structural characterization of metal and chemical hydrides are reviewed. The existing...
Powder diffraction is the mostly widely used crystallographic method, with applications spanning all...
Energy materials form the central part of energy devices. An essential part of their function is the...
In situ diffraction techniques above all, offer the unique opportunity of probing in real time and u...
Materials for reversible hydrogen storage in the solid state constitute a subject of intensive resea...
In this article, the capabilities of soft and hard X-ray techniques, including X-ray absorption (XAS...
'Real life' energy-related materials such as solid-state hydrogen storage compounds or components of...
Synchrotron radiation is an advanced collimated light source with high intensity. It has particular ...
The world today is facing increasing energy demands and a simultaneous demand for cleaner and more e...
Diffraction-based methods offer unique advantages for elucidating the pathways by which materials ab...
Neutron powder diffraction is extensively used for the development and fundamental understanding of ...
Hydrogen forms more compounds than any other element in the Periodic Table, yet methods for accurate...
Hydrogen forms more compounds than any other element in the Periodic Table, yet methods for accurate...
The potential of neutron powder diffraction in the location of hydrogen atoms in molecular materials...
We introduce here diffraction in general, as well as neutron and powder diffraction in particular as...
The methods of structural characterization of metal and chemical hydrides are reviewed. The existing...
Powder diffraction is the mostly widely used crystallographic method, with applications spanning all...
Energy materials form the central part of energy devices. An essential part of their function is the...
In situ diffraction techniques above all, offer the unique opportunity of probing in real time and u...
Materials for reversible hydrogen storage in the solid state constitute a subject of intensive resea...
In this article, the capabilities of soft and hard X-ray techniques, including X-ray absorption (XAS...