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Electron paramagnetic resonance and theoretical study of gallium vacancy in <b> <i>β</i> </b>-Ga2O3

Nguyên Tiên Són, Quốc Duy Hồ, Ken Goto, Hiroshi Abe, Takeshi Ohshima, Bo Monemar, Yoshinao Kumagai, Thomas Frauenheim, Péter Deák

2020Applied Physics Letters46 citationsDOIOpen Access PDF

Abstract

Unintentionally doped n-type β-Ga2O3 becomes highly resistive after annealing at high temperatures in oxygen ambient. The annealing process also induces an electron paramagnetic resonance (EPR) center, labeled IR1, with an electron spin of S = 1/2 and principal g-values of gxx = 2.0160, gyy = 2.0386, and gzz = 2.0029 with the principal axis of gzz being 60° from the [001]* direction and gyy along the b-axis. A hyperfine (hf) structure due to the hf interaction between the electron spin and nuclear spins of two equivalent Ga atoms with a hf splitting of ∼29 G (for 69Ga) has been observed. The center can also be created by electron irradiation. Comparing the Ga hf constants determined by EPR with corresponding values calculated for different Ga vacancy-related defects, the IR1 defect is assigned to the double negative charge state of either the isolated Ga vacancy at the tetrahedral site (V2−Ga(I)) or the VGa(I)–Gaib–VGa(I) complex.

Topics & Concepts

Electron paramagnetic resonanceHyperfine structureVacancy defectGalliumNuclear magnetic resonanceChemistryParamagnetismElectron nuclear double resonanceMaterials scienceAtomic physicsCrystallographyCondensed matter physicsPhysicsOrganic chemistryGa2O3 and related materialsAdvanced Photocatalysis TechniquesZnO doping and properties
Electron paramagnetic resonance and theoretical study of gallium vacancy in <b> <i>β</i> </b>-Ga2O3 | Litcius