부산대학교 도서관

Crystal collimation offers a viable alternative to the commonly used pinhole collimation in small‐angle X‐ray scattering (SAXS) for specific applications requiring highest angular resolution. This scheme is not affected by the parasitic scattering and diffraction‐limited beam broadening. The Darwin width of the rocking curve of the crystals mainly defines the ultimate beam divergence. For this purpose, a dispersive Si‐111 crystal collimation set‐up based on two well conditioned pseudo channel‐cut crystals (pairs of well polished, independent parallel crystals) using a higher‐order reflection (Si‐333) has been developed. The gain in resolution is obtained at the expense of flux. The system has been installed at the TRUSAXS beamline ID02 (ESRF) for reducing the horizontal beam divergence in high‐resolution mesurements. The precise mechanics of the system allows reproducible alignment of the Bragg condition. The high resolution achieved at a sample–detector distance of 31 m is demonstrated by ultra‐small‐angle X‐ray scattering measurements on a model system consisting of micrometre‐sized polystyrene latex particles with low polydispersity. A dispersive Si‐111 crystal collimation set‐up based on two well conditioned pseudo channel‐cut crystals using higher‐order reflections has been developed and installed at the TRUSAXS beamline ID02 at the ESRF. This scheme is not limited by either the scattering or the diffraction by the slits, offering the highest angular resolution at the expense of flux for ultra‐small‐angle X‐ray scattering (USAXS) applications. The performance is demonstrated by USAXS measurements on micrometre‐sized spherical particles with low polydispersity. [ABSTRACT FROM AUTHOR]