Elastic Behavior of Nb₂O₅/Al₂O₃ Core–Shell Nanowires in Terms of Short-Range-Order Structures

Abstract: Single-crystalline niobium pentoxide nanowires (NWs) of length 10−15 μm and diameter 100−200 nm are synthesized by thermal oxidation of niobium substrates in a mild vacuum (3−10 mbar). Amorphous Al 2 O 3 shells of varying thicknesses (10, 30, 40, and 50 nm) are deposited on top of the wires using atomic layer deposition. Bending tests of the uncoated Nb 2 O 5 NWs and the Nb 2 O 5 /Al 2 O 3 core−shell NWs are carried out inside a scanning electron microscope using a micromanipulator with a force measurement ti… Show more

“…The results indicate that the defect concentration (e.g., dislocations) in the SrRuO 3 crystal grows rapidly with reduced thickness (Figures and S3). The presence of defects such as dislocations in the membranes may lead to local disorder of the crystal structure and thus increase the degrees of freedom of the crystal framework, which could be beneficial to the super-flexibility of freestanding SrRuO 3 membranes. − Therefore, the freestanding membranes are more likely to be deformed and even buckled under external force. From a microscopic point of view, large stress could induce structural transition accompanying a prominent distortion of the Ru–O bonds and Ru–O–Ru bond angles, , and this distortion may tolerate great structural deformation, which may contribute to the super-flexibility of freestanding SrRuO 3 membranes.…”

Super-flexibility in Freestanding Single-Crystal SrRuO₃ Conductive Oxide Membranes

“…The results indicate that the defect concentration (e.g., dislocations) in the SrRuO 3 crystal grows rapidly with reduced thickness (Figures and S3). The presence of defects such as dislocations in the membranes may lead to local disorder of the crystal structure and thus increase the degrees of freedom of the crystal framework, which could be beneficial to the super-flexibility of freestanding SrRuO 3 membranes. − Therefore, the freestanding membranes are more likely to be deformed and even buckled under external force. From a microscopic point of view, large stress could induce structural transition accompanying a prominent distortion of the Ru–O bonds and Ru–O–Ru bond angles, , and this distortion may tolerate great structural deformation, which may contribute to the super-flexibility of freestanding SrRuO 3 membranes.…”

Super-flexibility in Freestanding Single-Crystal SrRuO₃ Conductive Oxide Membranes

“…Modern technological pressure to develop miniature electronic devices with improved performance has led to the rapid expansion of research into low-dimensional metal oxide semiconductors (MOSs), which have been extensively applied in thin film transistors [1] , flat panel displays [2] , logical gates [3] , biosensing [4] , gas sensors [5−7] , smart windows [8,9] , and so on. MOS nanomaterials can also serve as nano-level interconnects and active components in optoelectronic devices and nano-electro-mechanical systems (NEMS) [5,10] .…”

Structural evolution of low-dimensional metal oxide semiconductors under external stress

Nb2O5 film optical properties and laser-induced damage by phase-change-driven tuning