Controlling recombination in wide-bandgap materials

Abstract

It has recently become clear that our current understanding of recombination processes at localized defects or impurities in solids,is incomplete. Such recombination events govern loss mechanisms and reliability of devices and the quantum efficiency of light emit,ters, including single-photon sources for quantum information science. Work by the PI has revealed that excited states play a decis,ive role in nonradiative recombination, and hitherto neglected ?impurity Auger? processes have a large impact. The proposed project,is aimed at rigorously calculating the rate of these processes; using the acquired knowledge to significantly improve device perform,ance; and validating the approach through experimental collaborations. Correct inclusion of these mechanisms is particularly import,ant in wide-bandgap materials, where current recombination models greatly underestimate the rates. Building on the PI?s expertise, f,irst-principles approaches for accurately calculating transition rates involving excited states and Auger processes will be develope,d. A fundamental understanding of these mechanisms is essential to suppress nonradiative recombination in wide-bandgap light emitte,rs and power electronics. The methodologies will also support the characterization and design of efficient centers for applications,in which radiative recombination underlies the functionality; these include phosphors, scintillators, and single-photon emitters for, quantum information science.Computational approaches will include density functional theory, hybrid functionals, the random phase a,pproximation, and many-body perturbation theory. Experimental validation will be enabled through funded and unfunded collaborations,. Nitride semiconductors will constitute the main materials platform used to construct and validate the approach, but applications a,re much broader. The ability to predict radiative and nonradiative rates will provide a framework for analyzing and controlling loss, mechanisms in devices and emission processes in single-photon emitters. The proposed basic research on a transformative science iss,ue will open new ways of thinking about recombination phenomena and lay a foundation for future new capabilities for DoD.As an educa,tional institution, UCSB performs fundamental and unclassified research. Any data or information developed or provided by UCSB, incl,uding but not limited to publications and reports, shall be unclassified fundamental research exempt from dissemination control or r,eview requirements.

Document Details

Document Type

DoD Grant Award

Publication Date

Oct 06, 2022

Source ID

N000142212808

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