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Interplay between intercalated oxygen superstructures and monolayerh-BN on Cu(100)
Ma, Chuanxu,Park, Jewook,Liu, Lei,Kim, Yong-Sung,Yoon, Mina,Baddorf, Arthur P.,Gu, Gong,Li, An-Ping American Physical Society 2016 Physical Review B Vol.94 No.6
<P>The confinement effect of intercalated atoms in van der Waals heterostructures can lead to interesting interactions between the confined atoms or molecules and the overlaying two-dimensional (2D) materials. Here we report the formation of ordered Cu(100) p(2 x 2) oxygen superstructures by oxygen intercalation under the monolayer hexagonal boron nitride (h-BN) on Cu after annealing. By using scanning tunneling microscopy and x-ray photoelectron spectroscopy, we identify the superstructure and reveal its roles in passivating the exposed Cu surfaces, decoupling h-BN and Cu, and disintegrating h-BN monolayers. The oxygen superstructure appears as a 2D pattern on the exposed Cu surface or quasi-1D stripes of paired oxygen intercalated in the interface of h-BN and Cu predominantly oriented along the moire modulations. The oxygen superstructure is shown to etch the overlaying h-BN monolayer in a thermal annealing process. After extended annealing, the h-BN monolayer disintegrates into nanoislands with zigzag edges. We discuss the implications of these findings on the stability and oxidation resistance of h-BN and relate them to challenges in process integration and 2D heterostructures.</P>
Electric modulation of conduction in multiferroic Ca-doped BiFeO<sub>3</sub> films
Yang, C.-H.,Seidel, J.,Kim, S. Y.,Rossen, P. B.,Yu, P.,Gajek, M.,Chu, Y. H.,Martin, L. W.,Holcomb, M. B.,He, Q.,Maksymovych, P.,Balke, N.,Kalinin, S. V.,Baddorf, A. P.,Basu, S. R.,Scullin, M. L.,Rames Nature Publishing Group 2009 Nature materials Vol.8 No.6
Many interesting materials phenomena such as the emergence of high-Tc superconductivity in the cuprates and colossal magnetoresistance in the manganites arise out of a doping-driven competition between energetically similar ground states. Doped multiferroics present a tantalizing evolution of this generic concept of phase competition. Here, we present the observation of an electronic conductor–insulator transition by control of band-filling in the model antiferromagnetic ferroelectric BiFeO<SUB>3</SUB> through Ca doping. Application of electric field enables us to control and manipulate this electronic transition to the extent that a p–n junction can be created, erased and inverted in this material. A ‘dome-like’ feature in the doping dependence of the ferroelectric transition is observed around a Ca concentration of ∼1/8, where a new pseudo-tetragonal phase appears and the electric modulation of conduction is optimized. Possible mechanisms for the observed effects are discussed on the basis of the interplay of ionic and electronic conduction. This observation opens the door to merging magnetoelectrics and magnetoelectronics at room temperature by combining electronic conduction with electric and magnetic degrees of freedom already present in the multiferroic BiFeO<SUB>3</SUB>.