Nonvolatile ferroelectric domain wall memory integrated on silicon.
Haoying SunJierong WangYushu WangChangqing GuoJiahui GuWei MaoJiangfeng YangYuwei LiuTingting ZhangTianyi GaoHanyu FuTingjun ZhangYufeng HaoZhengbin GuPeng WangHou-Bing HuangYuefeng NiePublished in: Nature communications (2022)
Ferroelectric domain wall memories have been proposed as a promising candidate for nonvolatile memories, given their intriguing advantages including low energy consumption and high-density integration. Perovskite oxides possess superior ferroelectric prosperities but perovskite-based domain wall memory integrated on silicon has rarely been reported due to the technical challenges in the sample preparation. Here, we demonstrate a domain wall memory prototype utilizing freestanding BaTiO 3 membranes transferred onto silicon. While as-grown BaTiO 3 films on (001) SrTiO 3 substrate are purely c-axis polarized, we find they exhibit distinct in-plane multidomain structures after released from the substrate and integrated onto silicon due to the collective effects from depolarizing field and strain relaxation. Based on the strong in-plane ferroelectricity, conductive domain walls with reading currents up to nanoampere are observed and can be both created and erased artificially, highlighting the great potential of the integration of perovskite oxides with silicon for ferroelectric domain wall memories.