Open Access
Interferometer‐controlled scanning transmission X‐ray microscopes at the Advanced Light Source
Author(s) -
Kilcoyne A. L. D.,
Tyliszczak T.,
Steele W. F.,
Fakra S.,
Hitchcock P.,
Franck K.,
Anderson E.,
Harteneck B.,
Rightor E. G.,
Mitchell G. E.,
Hitchcock A. P.,
Yang L.,
Warwick T.,
Ade H.
Publication year - 2003
Publication title -
journal of synchrotron radiation
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.172
H-Index - 99
ISSN - 1600-5775
DOI - 10.1107/s0909049502017739
Subject(s) - beamline , undulator , optics , microscope , advanced photon source , zone plate , physics , interferometry , materials science , diffraction , beam (structure)
Two new soft X‐ray scanning transmission microscopes located at the Advanced Light Source (ALS) have been designed, built and commissioned. Interferometer control implemented in both microscopes allows the precise measurement of the transverse position of the zone plate relative to the sample. Long‐term positional stability and compensation for transverse displacement during translations of the zone plate have been achieved. The interferometer also provides low‐distortion orthogonal x , y imaging. Two different control systems have been developed: a digital control system using standard VXI components at beamline 7.0, and a custom feedback system based on PC AT boards at beamline 5.3.2. Both microscopes are diffraction limited with the resolution set by the quality of the zone plates. Periodic features with 30 nm half period can be resolved with a zone plate that has a 40 nm outermost zone width. One microscope is operating at an undulator beamline (7.0), while the other is operating at a novel dedicated bending‐magnet beamline (5.3.2), which is designed specifically to illuminate the microscope. The undulator beamline provides count rates of the order of tens of MHz at high‐energy resolution with photon energies of up to about 1000 eV. Although the brightness of a bending‐magnet source is about four orders of magnitude smaller than that of an undulator source, photon statistics limited operation with intensities in excess of 3 MHz has been achieved at high energy resolution and high spatial resolution. The design and performance of these microscopes are described.