Going beyond the bistability paradigm of the charge polarizations in ferroelectrics is highly desired for ferroelectric memory devices toward ultra-high density information storage. Here, we propose to build multistates in composite ferroelectrics, which have both the intrinsic and sliding-induced polarizations. We illustrate the concept in H-stacking bilayers of 1T'' transition-metal dichalcogenides by first-principle calculations. We find that there is at least one order of magnitude difference in the energy barriers between these two types polarizations, which suggests that the external electric fields required to flipping them are significantly different. This difference allows for a novel flipping mechanism involving layer sliding and layer-by-layer flipping for the transforming of the polarization states. As a result, sextuple switchable states can be achieved for the 1T'' bilayers by properly controlling electrical field. Our study provides a new route to design polarization multistates for developing next-generation memory devices.
Comment: 6 pages, 3 figures