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Extraction of isotropic electron-nuclear hyperfine coupling constants of paramagnetic point defects from near-zero field magnetoresistance spectra via least squares fitting to models developed from the stochastic quantum Liouville equation

Elias B. Frantz, Nicholas J. Harmon, Stephen R. McMillan, Stephen J. Moxim, Michael E. Flatté, Patrick M. Lenahan

2020Journal of Applied Physics11 citationsDOIOpen Access PDF

Abstract

We report on a method by which we can systematically extract spectroscopic information such as isotropic electron–nuclear hyperfine coupling constants from near-zero field magnetoresistance (NZFMR) spectra. The method utilizes a least squares fitting of models developed from the stochastic quantum Liouville equation. We applied our fitting algorithm to two distinct material systems: Si/SiO2 metal oxide semiconductor field effect transistors and a-Si:H metal insulator semiconductor capacitors. Our fitted results and hyperfine parameters are in reasonable agreement with existing knowledge of the defects present in the systems. Our work indicates that the NZFMR response and fitting of the NZFMR spectrum via models developed from the stochastic quantum Liouville equation could be a relatively simple yet powerful addition to the family of spin-based techniques used to explore the chemical and structural nature of point defects in semiconductor devices and insulators.

Topics & Concepts

Hyperfine structureIsotropyCondensed matter physicsMagnetoresistanceElectronSpectral linePhysicsMagnetic fieldCoupling constantChemistryQuantum electrodynamicsQuantum mechanicsElectron and X-Ray Spectroscopy TechniquesIntegrated Circuits and Semiconductor Failure AnalysisSilicon and Solar Cell Technologies
Extraction of isotropic electron-nuclear hyperfine coupling constants of paramagnetic point defects from near-zero field magnetoresistance spectra via least squares fitting to models developed from the stochastic quantum Liouville equation | Litcius