Litcius/Paper detail

A hybrid optoelectronic Mott insulator

H. Navarro, J. del Valle, Y. Kalcheim, N. M. Vargas, C. Adda, M.-H. Lee, P. Lapa, A. Rivera-Calzada, I. A. Zaluzhnyy, E. Qiu, O. Shpyrko, M. Rozenberg, A. Frano, Ivan K. Schuller

2021Applied Physics Letters22 citationsDOIOpen Access PDF

Abstract

The coupling of electronic degrees of freedom in materials to create “hybridized functionalities” is a holy grail of modern condensed matter physics that may produce versatile mechanisms of control. Correlated electron systems often exhibit coupled degrees of freedom with a high degree of tunability which sometimes lead to hybridized functionalities based on external stimuli. However, the mechanisms of tunability and the sensitivity to external stimuli are determined by intrinsic material properties which are not always controllable. A Mott metal-insulator transition (MIT) is technologically attractive due to the large changes in resistance, tunable by doping, strain, electric fields, and orbital occupancy but not, in and of itself, controllable with light. Here, an alternate approach is presented to produce optical functionalities using a properly engineered photoconductor/strongly correlated hybrid heterostructure. This approach combines a photoconductor, which does not exhibit an MIT, with a strongly correlated oxide, which is not photoconducting. Due to the intimate proximity between the two materials, the heterostructure exhibits giant volatile and nonvolatile, photoinduced resistivity changes with substantial shifts in the MIT transition temperatures. This approach can be extended to other judicious combinations of strongly correlated materials.

Topics & Concepts

HeterojunctionMaterials scienceOptoelectronicsCondensed matter physicsCoupling (piping)Mott transitionDegrees of freedom (physics and chemistry)Holy GrailMott insulatorMetal–insulator transitionHybrid systemNanotechnologyInsulator (electricity)Electrical resistivity and conductivityElectronSensitivity (control systems)Optical conductivityChemical physicsDissipative systemConductivityStrongly correlated materialPhotonicsElectronic systemsOptical couplingPhysicsElectronic and Structural Properties of OxidesChemical and Physical Properties of Materials2D Materials and Applications