1-ID-B,C,E: High-energy X-ray Scattering
XSD
Chemistry, Life Sciences, Materials Science, Physics
Chemistry, Life Sciences, Materials Science, Physics
1-ID is a dedicated high-energy x-ray scattering beamline operating in the 42-130 keV range. The x-ray optics are optimized for high-energy x-ray usage and high-energy resolution, and several focusing modes are available. Supported high-energy techniques include macroscopic stress/texture determination, single-grain diffraction microscopy (HEDM), pair-distribution function measurements, powder diffraction, and small-angle scattering. Support for various in-situ environments is available including thermo-mechanical deformation. A conical slit for 3D mapping is available in 1-ID-C.
Beamline Specifications
Source : Undulator 2.3cm - 2.4m or 2.1m length
Monochromator Type : High-resolution Mono
Energy Range : 42-116 keV
Resolution : 1 x 10-4
Flux : 2 x 1011 @80 keV
Beam Size Hxv :
Focused : 1µm x 1µm
Unfocused : 1.5mm x 1mm
Source : Undulator 2.3cm - 2.4m or 2.1m length
Monochromator Type : Si(111) Bent Double-Laue
Energy Range : 42-136 keV
Resolution : 1.3 x 10-3
Flux : 6 x 1012 @80 keV
Beam Size Hxv :
Focused : 1µm x 1µm
Unfocused : 1.5mm x 1mm
Monochromator Type : High-resolution Mono
Energy Range : 42-116 keV
Resolution : 1 x 10-4
Flux : 2 x 1011 @80 keV
Beam Size Hxv :
Focused : 1µm x 1µm
Unfocused : 1.5mm x 1mm
Source : Undulator 2.3cm - 2.4m or 2.1m length
Monochromator Type : Si(111) Bent Double-Laue
Energy Range : 42-136 keV
Resolution : 1.3 x 10-3
Flux : 6 x 1012 @80 keV
Beam Size Hxv :
Focused : 1µm x 1µm
Unfocused : 1.5mm x 1mm
Quick Stats
Current Status
Operational/Accepting General Users
Operational/Accepting General Users
Access Mode
On-site Remote
On-site Remote
Special Capabilities
High-brilliance, high-energy x-rays. Special modes include refractive-lens focusing down to the micron level, and use of a secondary high-energy resolution monochromator.
High-brilliance, high-energy x-rays. Special modes include refractive-lens focusing down to the micron level, and use of a secondary high-energy resolution monochromator.
Beamline Contacts
Beamline Techniques
High-energy x-ray diffraction
Tomography
Small-angle x-ray scattering
Fluorescence spectroscopy
Pair distribution function
Phase contrast imaging
Endstations
1-ID-B
White beam station, used for high-energy x-ray optics and limited-scope imaging.
White beam station, used for high-energy x-ray optics and limited-scope imaging.
1-ID-C
Mono beam station, used for resonant diffraction, imaging, powder diffraction and x-ray optics development.
Mono beam station, used for resonant diffraction, imaging, powder diffraction and x-ray optics development.
1-ID-C
Includes diffracted beam apertures (conical and spiral slits) for 3D diffraction.
Includes diffracted beam apertures (conical and spiral slits) for 3D diffraction.
1-ID-E
Mono beam station, used for HEDM grain tracking (near-, far- and very-far-field modes), imaging and SAXS/WAXS.
Mono beam station, used for HEDM grain tracking (near-, far- and very-far-field modes), imaging and SAXS/WAXS.
1-ID-E
Primary end-station with many in-situ capabilities.
Primary end-station with many in-situ capabilities.
Detectors
5x GE-41RT area detector
Ge & Si solid state detectors
Pixirad 3 CdTe area detector
2x PointGrey CCD + scintillators
Dexela 2923 area detector
Varex 4343 area detector
Pilatus2M-CdTe (detector pool- needs request)
Equipment
4-circle diffractometer
Conical and spiral slits
Multi-DOF sample-manipulation systems
MTS servo-hydraulic 15kN load frame
RI Infrared furnace
Linkam TS1500 furnace
RF furnace
Additional Information
Additional Information
https://www.aps.anl.gov/Sector-1/1-ID
https://www.aps.anl.gov/Sector-1/1-ID
Software
The beamline is run by Linux workstations and VME-based electronics. The VME-based equipment is controlled by EPICS. There are several software clients that use EPICS including MEDM, Python/Bluesky and SPEC. Other computers, such as PCs, are used to run specialized pieces of equipment (e.g., area detectors). FPGAs and associated code (SoftGlue) used for detector-motion synchronization in high-demand applications.
The beamline is run by Linux workstations and VME-based electronics. The VME-based equipment is controlled by EPICS. There are several software clients that use EPICS including MEDM, Python/Bluesky and SPEC. Other computers, such as PCs, are used to run specialized pieces of equipment (e.g., area detectors). FPGAs and associated code (SoftGlue) used for detector-motion synchronization in high-demand applications.
Beamline Controls and Data Acquisition
The beamline is run by Linux workstations and VME-based electronics. The VME-based equipment is controlled by EPICS. There are several software clients that use EPICS including MEDM, Python/Bluesky and SPEC. Other computers, such as PCs, are used to run specialized pieces of equipment (e.g., area detectors). FPGAs and associated code (SoftGlue) used for detector-motion synchronization in high-demand applications.
The beamline is run by Linux workstations and VME-based electronics. The VME-based equipment is controlled by EPICS. There are several software clients that use EPICS including MEDM, Python/Bluesky and SPEC. Other computers, such as PCs, are used to run specialized pieces of equipment (e.g., area detectors). FPGAs and associated code (SoftGlue) used for detector-motion synchronization in high-demand applications.