Studying the effect of boron doping and temperature on antiferromagnetic domains in epitaxial Cr₂O₃ films using diamond magnetometry

The antiferromagnetic (AFM) magnetoelectric chromia (Cr₂O₃) is an archetypical oxide that permits voltage-control of the Néel vector in the presence of an applied magnetic field, but it suffers practical limitations due to its low Néel Temperature (T_N) ~ 307 K [1]. Boron doping increases T_N to 400 K and allows realizing voltage controlled Néel vector at zero magnetic field [2], a promising result for AFM spintronics. To date there is no direct measurement of T_N in B-Cr₂O_3, and it is not clear how doping affects its AFM properties. Here we use nitrogen vacancy (NV)-magnetometry [3, 4] to directly study the effect of B doping and temperature on the properties of AFM domains in 200-nm thick Cr₂O₃ and B-Cr₂O₃ films grown by pulsed laser deposition on AL₂O₃ substrates. Magnetic contrast, domain size, domain width, and T_N are compared for different temperatures, growth and interfacial conditions. By using reverse propagation protocol [3,4], we measure the magnetization profile, which shows well-defined magnetized nano-domains, affected strongly by temperature and B doping. [1] N. Wu et al., Phys. Rev. Lett. 106, 087202 (2011). [2] A. Mahmood et al. Nat. Comm. 12, 1674 (2021). [3] P. Appel et al., Nano Lett. 19, 1682 (2019). [4] A. Erickson et al., RSC Advances, Under review (2022).