Design and fabrication of prototype piezoelectric adjustable X-ray mirrors

Julian Walker; Tianning Liu; Mohit Tendulkar; David N Burrows; Casey T DeRoo; Ryan Allured; Edward N Hertz; Vincenzo Cotroneo; Paul B Reid; Eric D Schwartz; Thomas N Jackson; Susan Trolier-McKinstry

doi:10.1364/OE.26.027757

Design and fabrication of prototype piezoelectric adjustable X-ray mirrors

Opt Express. 2018 Oct 15;26(21):27757-27772. doi: 10.1364/OE.26.027757.

Authors

Julian Walker, Tianning Liu, Mohit Tendulkar, David N Burrows, Casey T DeRoo, Ryan Allured, Edward N Hertz, Vincenzo Cotroneo, Paul B Reid, Eric D Schwartz, Thomas N Jackson, Susan Trolier-McKinstry

PMID: 30469836
DOI: 10.1364/OE.26.027757

Abstract

Lynx, a next generation X-ray observatory concept currently under study, requires lightweight, high spatial resolution X-ray mirrors. Here we detail the development and fabrication of one of the candidate technologies for Lynx, piezoelectric adjustable X-ray optics. These X-ray mirrors are thin glass shell mirrors with Cr/Ir X-ray reflective coatings on the mirror side and piezoelectric thin film actuators on the actuator side. Magnetron sputtering was used to deposit metal electrodes and metal-oxide piezoelectric layers. The piezoelectric (Pb_0.995(Zr_0.52Ti_0.48)_0.99Nb_0.01O₃) was divided into 112 independent piezoelectric actuators, with 100% yield achieved. We discuss the fabrication procedure, residual thermal stresses and tuning of the Cr/Ir coating stress for the purposes of stress balancing.