Abstract
Although indications are that a single chiral quantum anomalous Hall(QAH) edge mode might have been experimentally detected. There have been very many recent experiments which conjecture that a chiral QAH edge mode always materializes along with a pair of quasi-helical quantum spin Hall (QSH) edge modes. In this work we deal with a substantial ‘What If?’ question- in case the QSH edge modes, from which these QAH edge modes evolve, are not topologically-protected then the QAH edge modes wont be topologically-protected too and thus unfit for use in any applications. Further, as a corollary one can also ask if the topological-protection of QSH edge modes does not carry over during the evolution process to QAH edge modes then again our ‘What if?’ scenario becomes apparent. The ‘how’ of the resolution of this ‘What if?’ conundrum is the main objective of our work. We show in similar set-ups affected by disorder and inelastic scattering, transport via trivial QAH edge mode leads to quantization of Hall resistance and not that via topological QAH edge modes. This perhaps begs a substantial reinterpretation of those experiments which purported to find signatures of chiral(topological) QAH edge modes albeit in conjunction with quasi helical QSH edge modes.
Highlights
The experiment depicted in ref.1 is most probably a detection of a single topological chiral quantum anomalous Hall(QAH) edge mode
What our work reveals is that a chiral trivial QAH edge mode which exists in combination with quasi helical quantum spin Hall (QSH) edge modes gives the quantization of Hall resistance and not the chiral topological QAH edge mode when combined with trivial QSH edge modes
We distinguish three cases one in which there is just a single chiral QAH edge mode which is topological in character, the second wherein the chiral topological QAH edge mode exists alongwith a pair of trivial QSH edge modes and the case wherein a trivial QAH edge mode exists with a pair of trivial QSH edge modes
Summary
The Landauer-Buttiker formalism relating currents with voltages in a multi terminal device has been extended to QSH edge modes in refs as well as QAH samples in ref.5:. Vi is the voltage at ith probe/contact/terminal (we will be using the term probe or contact or terminal interchangeably for the same thing, i.e., a reservoir of electrons at some fixed potential) and Ii is the current passing through the same terminal. Tij is the transmission probability from the jth to ith probe and Gij is the conductance. The relations between currents and voltages at the two terminals are derived from conductance matrix [2]:
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