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arxiv: 1807.01616 · v4 · pith:KSQ6FOYY · submitted 2018-07-04 · cond-mat.mes-hall · quant-ph

Circular dichroism in high-order harmonic generation: Heralding topological phases and transitions in Chern insulators

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classification cond-mat.mes-hall quant-ph
keywords topologicalhigh-harmonicgenerationcircularcleardichroismemissionfundamental
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Topological materials are of interest to both fundamental science and advanced technologies, because topological states are robust with respect to perturbations and dissipation. Experimental detection of topological invariants is thus in great demand, but it remains extremely challenging. Ultrafast laser-matter interactions, and in particular high-harmonic generation (HHG), meanwhile, were proposed several years ago as tools to explore the structural and dynamical properties of various matter targets. Here we show that the high-harmonic emission signal produced by a circularly-polarized laser contains signatures of the topological phase transition in the paradigmatic Haldane model. In addition to clear shifts of the overall emissivity and harmonic cutoff, the high-harmonic emission shows a unique circular dichroism, which exhibits clear changes in behavior at the topological phase boundary. Our findings pave the way to understand fundamental questions about the ultrafast electron-hole pair dynamics in topological materials via non-linear high-harmonic generation spectroscopy.

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