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D-stroi - a uniaxial load frame for X-ray diffraction and imaging.

Felix Tristan Frankus1, Adam André William Cretton2, Carsten Detlefs3

  • 1Department of Civil and Mechanical Engineering, Technical University of Denmark, Denmark.

Journal of Synchrotron Radiation
|June 18, 2026
PubMed
Summary
This summary is machine-generated.

A new miniature load frame allows remote, in situ tensile testing of small metal samples during synchrotron X-ray analysis. This system precisely tracks deformation for materials research.

Keywords:
dark-field X-ray microscopymechanical testingplastic deformation

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Area of Science:

  • Materials Science
  • Mechanical Engineering
  • Synchrotron Science

Background:

  • In situ mechanical testing within synchrotron environments is crucial for understanding material behavior under load.
  • Existing setups often face limitations in precision, sample size, and maintaining sample position during deformation.

Purpose of the Study:

  • To develop and present a remotely controlled miniature load frame for in situ tensile deformation experiments.
  • To enable precise deformation tracking of millimetre-sized metal samples within synchrotron X-ray diffraction and imaging.

Main Methods:

  • Design and implementation of a miniature load frame with remote control capabilities.
  • Integration of digital image correlation (DIC) for real-time deformation monitoring.
  • Mechanical design focused on minimizing sample center shift during tensile loading.

Main Results:

  • The load frame successfully performed in situ tensile deformation on millimetre-sized metal samples.
  • Digital image correlation provided accurate deformation tracking up to sample rupture.
  • Tensile loads up to 500 N were applied with minimal shift in the sample's center of illumination.

Conclusions:

  • The developed miniature load frame is a valuable tool for in situ mechanical testing in synchrotron environments.
  • The system's precision and stability enhance the quality of X-ray diffraction and imaging data.
  • This technology facilitates advanced research into the deformation mechanisms of metals at the microscale.