Engineering Plateau Phase Transition in Quantum Anomalous Hall Multilayers
The plateau phase transition in quantum anomalous Hall (QAH) insulators corresponds to a quantum state wherein a single magnetic domain gives way to multiple magnetic domains and then re-converges back to a single magnetic domain. The layer structure of the sample provides an external knob for adjus...
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Zusammenfassung: | The plateau phase transition in quantum anomalous Hall (QAH) insulators
corresponds to a quantum state wherein a single magnetic domain gives way to
multiple magnetic domains and then re-converges back to a single magnetic
domain. The layer structure of the sample provides an external knob for
adjusting the Chern number C of the QAH insulators. Here, we employ molecular
beam epitaxy (MBE) to grow magnetic topological insulator (TI) multilayers with
an asymmetric layer structure and realize the magnetic field-driven plateau
phase transition between two QAH states with odd Chern number change {\Delta}C.
In multilayer structures with C=+-1 and C=+-2 QAH states, we find two
characteristic power-law behaviors between temperature and the scaling
variables on the magnetic field at transition points. The critical exponents
extracted for the plateau phase transitions with {\Delta}C=1 and {\Delta}C=3 in
QAH insulators are found to be nearly identical, specifically, k1~0.390+-0.021
and k2~0.388+-0.015, respectively. We construct a four-layer Chalker-Coddington
network model to understand the consistent critical exponents for the plateau
phase transitions with {\Delta}C=1 and {\Delta}C=3. This work will motivate
further investigations into the critical behaviors of plateau phase transitions
with different {\Delta}C in QAH insulators and provide new opportunities for
the development of QAH chiral edge current-based electronic and spintronic
devices. |
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DOI: | 10.48550/arxiv.2312.15072 |