Strain Engineering: Perfecting Freestanding Perovskite Oxide Fabrication

Freestanding oxide membranes provide a promising path for integrating devices on silicon and flexible platforms. To ensure optimal device performance, these membranes must be of high crystal quality, stoichiometric, and their morphology free from cracks and wrinkles. Often, layers transferred on substrates show wrinkles and cracks due to a lattice relaxation from an epitaxial mismatch. Doping the sacrificial layer of Sr3Al2O6 (SAO) with Ca or Ba offers a promising solution to overcome these challenges, yet its effects remain critically underexplored. A systematic study of doping Ca into SAO is presented, optimizing the pulsed laser deposition (PLD) conditions, and adjusting the supporting polymer type and thickness, demonstrating that strain engineering can effectively eliminate these imperfections. Using SrTiO3 as a case study, it is found that Ca1.5Sr1.5Al2O6 offers a near-perfect match and a defect-free freestanding membrane. This approach, using the water-soluble Bax/CaxSr3-xAl2O6 family, paves the way for producing high-quality, large freestanding membranes for functional oxide devices. This article systematically studies Ca-doped Sr3Al2O6 (orange, green, and purple) to obtain defect-free freestanding membranes. After optimizing the pulsed laser deposition (PLD) conditions and adjusting the supporting polymer (black) thickness, strain engineering is utilized to fabricate high-quality, large, and freestanding membranes for functional oxide devices. SrTiO3 (grey) is selected as a case study for the released layer. image