
A piezoelectric deformable X‐ray mirror for phase compensation based on global optimization
Author(s) -
Jiang Hui,
Tian Naxi,
Liang Dongxu,
Du Guohao,
Yan Shuai
Publication year - 2019
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/s1600577519003047
Subject(s) - wavefront , optics , fizeau interferometer , compensation (psychology) , interferometry , actuator , polishing , physics , figure of merit , phase (matter) , computer science , beamline , synchrotron radiation , materials science , astronomical interferometer , beam (structure) , artificial intelligence , psychology , quantum mechanics , psychoanalysis , composite material
As a strong tool for the study of nanoscience, the synchrotron hard X‐ray nanoprobe technique enables researchers to investigate complex samples with many advantages, such as in situ setup, high sensitivity and the integration of various experimental methods. In recent years, an important goal has been to push the focusing spot size to the diffraction limit of ∼10 nm. The multilayer‐based Kirkpatrick–Baez (KB) mirror system is one of the most important methods used to achieve this goal. This method was chosen by the nanoprobe beamline of the Phase‐II project at the Shanghai Synchrotron Radiation Facility. To overcome the limitations of current polishing technologies, the use of an additional phase compensator was necessary to decrease the wavefront distortions. In this experiment, a prototype phase compensator has been created to show how to obtain precise wavefront compensation. With the use of finite‐element analysis and Fizeau interferometer measurements, some important factors such as the piezoresponse, different actuator distributions, stability and hysteresis were investigated. A global optimization method based on the measured piezoresponse has also been developed. This method overcame the limitations of the previous local algorithm related to the adjustment of every single actuator for compact piezoelectric layouts. The mirror figure can approach a target figure after several iterations. The figure difference can be reduced to several nanometres, which is far better than the mirror figure errors. The prototype was also used to successfully compensate for the real wavefront errors from upstream and for its own figure errors, measured using the speckle scanning technique. The residual figure error was reduced to a root‐mean‐square value of 0.7 nm.