We resolve the domain-wall structure of the model antiferromagnet $text{Cr}_2text{O}_3$ using nanoscale scanning diamond magnetometry and second-harmonic-generation microscopy. We find that the 180$^circ$ domain walls are predominantly Bloch-like, and can co-exist with Neel walls in crystals with significant in-plane anisotropy. In the latter case, Neel walls that run perpendicular to a magnetic easy axis acquire a well-defined chirality. We further report quantitative measurement of the domain-wall width and surface magnetization. Our results provide fundamental input and an experimental methodology for the understanding of domain walls in pure, intrinsic antiferromagnets, which is relevant to achieve electrical control of domain-wall motion in antiferromagnetic compounds.
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