83rd Annual Meeting of the APS Southeastern Section
Volume 61, Number 19
Thursday–Saturday, November 10–12, 2016;
Charlottesville, Virginia
Session L3: Magnetism
8:30 AM–10:54 AM,
Saturday, November 12, 2016
Room: Monroe Room
Chair: Puru Jea, Virginia Commonwealth University
Abstract ID: BAPS.2016.SES.L3.3
Abstract: L3.00003 : Magnetism in Nanosystems
9:42 AM–10:18 AM
Preview Abstract
Abstract
Author:
Jian Zhou
(Virginia Commonwealth Univ)
Magnetism is an old physics topic that has been receiving new concept in
recent years. One of the reason is the discussion of magnetism in
nanostructured systems, especially in two-dimensional (2D) thin films. Among
different types of magnetic couplings, ferromagnetism is the simplest but
most useful one. In the present talk, I will discuss some ferromagnetic thin
films with their novel and interesting properties. Using first-principles
calculations we have discovered and demonstrated a series of transition
metal (TM) liganded ferromagnetic tri-layer thin films, including
FeC$_{\mathrm{2}}$, MnO$_{\mathrm{2}}$, and RuI$_{\mathrm{3}}$. The 2D
FeC$_{\mathrm{2}}$ can be chemically exfoliated from bulk
ThFeC$_{\mathrm{2}}$ compound, which has a Curie temperature of
\textasciitilde 245 K, and shows a 100{\%} spin polarization at the Fermi
level. The MnO$_{\mathrm{2}}$ layer has a strain modulated Curie temperature
in the range of 140--220 K, and shows a semiconducting conductivity.
Furthermore, we show that the MnO$_{\mathrm{2}}$ is a good substrate to
support a single layer of Sb/Bi. The combined system possesses a large band
gap of quantum spin Hall effect (without time-reversal symmetry) and a large
anomalous Hall effect, in their low energy state. In order to achieve
intrinsic and robust quantum anomalous Hall effect in experimentally
feasible 2D materials, we propose that TM halide family is a good candidate.
Using ferromagnetic RuI$_{\mathrm{3}}$ thin film as an example, we show that
its Curie temperature is \textasciitilde 360 K. At the Fermi level it shows
a clear Dirac cone in the spin down channel, which can be opened once the
spin rotational symmetry is broken by including spin-orbit coupling. We
demonstrate a large band gap of quantum anomalous Hall effect emerges inside
the band gap, and the metallic edge band can be clearly seen in a nanoribbon
model. These findings broaden the potential applications of low-dimensional
magnetic materials.
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2016.SES.L3.3