The
presence of ferroelectric polarization in 2D materials is extremely
rare due to the effect of the surface depolarizing field. Here, we
use first-principles calculations to show the largest out-of-plane
polarization observed in a monolayer in functionalized MXenes (Sc2CO2). The switching of polarization in this new
class of ferroelectric materials occurs through a previously unknown
intermediate antiferroelectric structure, thus establishing three
states for applications in low-dimensional nonvolatile memory. We
show that the armchair domain interface acts as an 1D metallic nanowire
separating two insulating domains. In the case of the van der Waals
bilayer we observe, interestingly, the presence of an ultrathin 2D
electron/hole gas (2DEG) on the top/bottom layers, respectively, due
to the redistrubution of charge carriers. The 2DEG is nondegenerate
due to spin–orbit coupling, thus paving the way for spin–orbitronic
devices. The coexistence of ferroelectricity, antiferroelectricity,
2DEG, and spin–orbit splitting in this system suggests that
such 2D polar materials possess high potential for device application
in a multitude of fields ranging from nanoelectronics to photovoltaics.