Establishment of new design criteria for GlidCop^®X-ray absorbers

Abstract: An engineering research program has been conducted at the Advanced Photon Source (APS) in order to determine the thermomechanical conditions that lead to crack formation in GlidCop 1 , a material commonly used to fabricate X-ray absorbers at X-ray synchrotron facilities. This dispersion-strengthened copper alloy is a proprietary material and detailed technical data of interest to the synchrotron community is limited. The results from the research program have allowed new design criteria to be established for G… Show more

“…It can be found that the strain generated in the first heating cycle causes plastic deformation if the yield point is exceeded, leading to the kinematic strain hardening, which locally increases the yield strength of the material [19]. Strain hardening is caused by crystal defects in the material, which can be grain boundaries, grain boundaries, cracks, or defects.…”

“…A multi-linear kinematic hardening model was also used, then the typical equivalent stress-equivalent total strain hysteresis curves were obtained, as shown in Figure 9. Typical equivalent stress-equivalent total strain hysteresis curves for specimens [19]. Figure 9.…”

“…The image on the right shows a magnified view of the bright field. The lower left image shows a highly magnified cross-section through the 1.8 mm long scratch above [19].…”

“…Figure9. Typical equivalent stress-equivalent total strain hysteresis curves for specimens[19]. Figure9.…”

A Mini-Review on the Thermal Fatigue Properties of Copper Materials Applied at the Front-End of Synchrotron Radiation Facilities

“…It can be found that the strain generated in the first heating cycle causes plastic deformation if the yield point is exceeded, leading to the kinematic strain hardening, which locally increases the yield strength of the material [19]. Strain hardening is caused by crystal defects in the material, which can be grain boundaries, grain boundaries, cracks, or defects.…”

“…A multi-linear kinematic hardening model was also used, then the typical equivalent stress-equivalent total strain hysteresis curves were obtained, as shown in Figure 9. Typical equivalent stress-equivalent total strain hysteresis curves for specimens [19]. Figure 9.…”

“…The image on the right shows a magnified view of the bright field. The lower left image shows a highly magnified cross-section through the 1.8 mm long scratch above [19].…”

“…Figure9. Typical equivalent stress-equivalent total strain hysteresis curves for specimens[19]. Figure9.…”

A Mini-Review on the Thermal Fatigue Properties of Copper Materials Applied at the Front-End of Synchrotron Radiation Facilities

The design of the front-end layout and first high-power-density masks for the hard X-ray nano-probe beamline at SSRF

Wire-coil insert optimization for high-heat-load/flux synchrotron components