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Experimental probes of emergent symmetries in the quantum Hall system

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arxiv 1008.5257 v2 pith:H5U7RERA submitted 2010-08-31 cond-mat.str-el

Experimental probes of emergent symmetries in the quantum Hall system

classification cond-mat.str-el
keywords dualityquantumsymmetrycriticalemergentevidenceexperimentalexperiments
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Experiments studying renormalization group flows in the quantum Hall system provide significant evidence for the existence of an emergent holomorphic modular symmetry $\Gamma_0(2)$. We briefly review this evidence and show that, for the lowest temperatures, the experimental determination of the position of the quantum critical points agrees to the parts \emph{per mille} level with the prediction from $\Gamma_0(2)$. We present evidence that experiments giving results that deviate substantially from the symmetry predictions are not cold enough to be in the quantum critical domain. We show how the modular symmetry extended by a non-holomorphic particle-hole duality leads to an extensive web of dualities related to those in plateau-insulator transitions, and we derive a formula relating dual pairs $(B,B_d)$ of magnetic field strengths across any transition. The experimental data obtained for the transition studied so far is in excellent agreement with the duality relations following from this emergent symmetry, and rule out the duality rule derived from the ``law of corresponding states". Comparing these generalized duality predictions with future experiments on other transitions should provide stringent tests of modular duality deep in the non-linear domain far from the quantum critical points.

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