Abstract
We propose a minimalist architecture for achieving various crystalline-symmetry-protected Majorana modes in an array of coupled quantum dots. Our framework is motivated by the recent experimental demonstrations of two-site and three-site artificial Kitaev chains in a similar setup. We find that introducing a 𝜋-phase domain wall in the Kitaev chain leads to a pair of mirror-protected Majorana zero modes located at or near the junction. Joining two 𝜋 junctions into a closed loop, we can simulate two distinct classes of two-dimensional higher-order topological superconducting phases, both carrying symmetry-protected Majorana modes around the sample corners. As an extension of the 𝜋 junction, we further consider a general vertex structure where 𝑛 Kitaev chains meet, i.e., a Kitaev 𝑛 vertex. We prove that such an 𝑛 vertex, if respecting a dihedral symmetry group 𝐷𝑛, necessarily carries 𝑛 vertex-bound Majorana modes protected by the 𝐷𝑛 symmetry. Resilience of the junction and vertex Majorana bound states against disorder and correlation effects is also discussed. Our architecture paves the way for designing, constructing, and exploring a wide variety of artificial topological crystalline phases in quantum-dot experiments.
