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Gate-Controlled VO2 Phase Transition for High-Performance Smart Window

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arxiv 1810.00942 v2 pith:6HGY22LJ submitted 2018-08-31 physics.app-ph cond-mat.str-el

Gate-Controlled VO2 Phase Transition for High-Performance Smart Window

classification physics.app-ph cond-mat.str-el
keywords phasesmarttransitionwindowtransmittanceabilityelectric-fieldenergy
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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VO2 material is promising for developing energy-saving "smart window", owing to its thermochromic property induced by metal-insulator transition (MIT). However, its practical application is greatly limited by the relatively high critical transition temperature (~68oC), low luminous transmittance (<60%) and poor solar energy regulation ability (<15%). Here we developed a reversible and non-volatile electric-field control on the MIT of monoclinic VO2 film. With a solid electrolyte layer assisted gating treatment, we modulated the insertion/extraction of hydrogens into/from VO2 lattice at room temperature, causing tri-state phase transitions accompanied with controllable transmission adjustment. The dramatic increase of visible/infrared transmittance during the phase transition from the metallic (lightly H-doping) to insulating (heavily H-doping) phase leads to an increased solar energy regulation ability up to 26.5%, while keep 70.8% visible-luminous transmittance. These results beat all previous records and even exceeded the theoretical limit for traditional VO2 smart window, removing intrinsic disadvantages of VO2 for energy-saving utilizations. Our findings not only demonstrated an electric-field controlled phase modulation strategy, but also open the door for high-performance VO2-based smart window applications.

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