Add to ORKGABSTRACT: We study the strain state of doubly clamped VO2 nanobeam devices by dynamically probing resonant frequency of the nanoscale electromechanical device across the metal−insulator transition. Simultaneous resistance and resonance measurements indicate M1−M2 phase transition in the insulating state with a drop in resonant frequency concomitant with an increase in resistance. The resonant frequency increases by ∼7 MHz with the growth of metallic domain (M2−R transition) due to the development of tensile strain in the nanobeam. Our approach to dynamically track strain coupled with simultaneous resistance and resonance measurements using electromechanical resonators enables the study of lattice-involved interactions more precisely than st...
The metal to insulator transition (MIT) of strongly correlated materials is subject to strong lattic...
Correlated electron materials can undergo a variety of phase transitions, including superconductivit...
Strain engineering is a powerful technology that exploits the stationary external or internal stress...
We study the strain state of doubly clamped VO2 nanobeam devices by dynamically probing resonant fre...
We study the strain state of doubly clamped VO<sub>2</sub> nanobeam devices by dynamically probing r...
Nanomechanical resonators provide a compelling platform to investigate and exploit phase transitions...
We investigated the effect of substrate-induced strain on the metal−insulator transition (MIT) in si...
We investigated external-stress-induced metal-insulator phase transitions in cantilevered single-cry...
Vanadium dioxide (VO2) material, known for changing physical properties due to metal-insulator trans...
Micro- and nano-mechanical systems may take advantage from using materials having multiple functiona...
Single-crystal micro-and nanomaterials often exhibit higher yield strength than their bulk counterpa...
VO2 is a particularly appealing material for the development of solid-state micro- and nanoactuators...
A Metal-insulator transition (MIT) is the ability of some materials to change between metal and insu...
ABSTRACT: The metal to insulator transition (MIT) of strongly correlated materials is subject to str...
Micro- and nano-electromechanical resonators are a fundamental building block of modern technology, ...
The metal to insulator transition (MIT) of strongly correlated materials is subject to strong lattic...
Correlated electron materials can undergo a variety of phase transitions, including superconductivit...
Strain engineering is a powerful technology that exploits the stationary external or internal stress...
We study the strain state of doubly clamped VO2 nanobeam devices by dynamically probing resonant fre...
We study the strain state of doubly clamped VO<sub>2</sub> nanobeam devices by dynamically probing r...
Nanomechanical resonators provide a compelling platform to investigate and exploit phase transitions...
We investigated the effect of substrate-induced strain on the metal−insulator transition (MIT) in si...
We investigated external-stress-induced metal-insulator phase transitions in cantilevered single-cry...
Vanadium dioxide (VO2) material, known for changing physical properties due to metal-insulator trans...
Micro- and nano-mechanical systems may take advantage from using materials having multiple functiona...
Single-crystal micro-and nanomaterials often exhibit higher yield strength than their bulk counterpa...
VO2 is a particularly appealing material for the development of solid-state micro- and nanoactuators...
A Metal-insulator transition (MIT) is the ability of some materials to change between metal and insu...
ABSTRACT: The metal to insulator transition (MIT) of strongly correlated materials is subject to str...
Micro- and nano-electromechanical resonators are a fundamental building block of modern technology, ...
The metal to insulator transition (MIT) of strongly correlated materials is subject to strong lattic...
Correlated electron materials can undergo a variety of phase transitions, including superconductivit...
Strain engineering is a powerful technology that exploits the stationary external or internal stress...