Competition of moiré network sites to form electronic quantum dots in reconstructed MoX${}_2$/WX${}_2$ heterostructures

Abstract: Twisted bilayers of two-dimensional semiconductors offer a versatile platform to engineer quantum states for charge carriers using moir\'e superlattice effects. Among the systems of recent interest are twistronic MoSe${}{2}$/WSe${}{2}$ and MoS${}{2}$/WS${}{2}$ heterostructures, which undergo reconstruction into preferential stacking domains and highly strained domain wall networks, determining the electron/hole localization across moir\'e superlattices. Here, we present a catalogue of options for the formation of self-organized quantum dots and wires in lattice-reconstructed marginally twisted MoSe${}{2}$/WSe${}{2}$ and MoS${}{2}$/WS${}{2}$ bilayers, fine tuned by the twist angle between the monolayers from perfect alignment to $\theta \sim 1^{\circ}$, and by choosing parallel or anti-parallel orientation of their unit cells. The proposed scenarios of the quantum dots and wires formation are found using multi-scale modelling that takes into account the features of strain textures caused by twirling of domain wall networks.