Difference between revisions of "34-ID-E"
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The science area brings together a very large and scientifically diverse community with interests in materials deformation processes, recrystallization, electromigration, solid-solution precipitation, high pressure environments, and condensed matter physics | The science area brings together a very large and scientifically diverse community with interests in materials deformation processes, recrystallization, electromigration, solid-solution precipitation, high pressure environments, and condensed matter physics | ||
== History == | |||
''Main article: [[History of Beamline 34ID-E]]'' | |||
People started to build 34ID a long time ago, probably around 1500 B.C. | |||
== Overview == | == Overview == | ||
Revision as of 22:02, 6 August 2013
Welcome to the 34ID-E wiki! This is the main page.
Beamline 34ID-E uses monochromatic and polychromatic micro-beam diffraction to examine the structure of materials with sub-micron spatial resolution in all three dimensions. Properties that can be measured include local crystallographic orientations, orientation gradients and strains.
The science area brings together a very large and scientifically diverse community with interests in materials deformation processes, recrystallization, electromigration, solid-solution precipitation, high pressure environments, and condensed matter physics
History
Main article: History of Beamline 34ID-E
People started to build 34ID a long time ago, probably around 1500 B.C.
Overview
Beam Parameters
Contacts
Instrumentation
Main articles: 34ID Beamline Layout and 34ID E-Station
Operations
Data Analysis
See: LaueGo
Experimental data taken with our area detectors are saved in the NeXus format based on HDF-5.
Analysis and visualization are mostly done with LaueGo, a package developed at 34ID-E based on IGOR Pro, runs on any PC or Mac.
Data from depth-resolved measurements requires reconstruction, which is carried out by a multi-node Linux cluster at APS.
