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Capacity of entanglement and distribution of density matrix eigenvalues in gapless systems

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arxiv 1708.08924 v1 pith:FP4PGZJP submitted 2017-08-29 cond-mat.str-el cond-mat.stat-mechhep-th

Capacity of entanglement and distribution of density matrix eigenvalues in gapless systems

classification cond-mat.str-el cond-mat.stat-mechhep-th
keywords distributionalphacapacityeigenvaluesentanglementfictitiousformulafunction
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We propose that the properties of the capacity of entanglement (COE) in gapless systems can efficiently be investigated through the use of the distribution of eigenvalues of the reduced density matrix (RDM). The COE is defined as the fictitious heat capacity calculated from the entanglement spectrum. Its dependence on the fictitious temperature can reflect the low-temperature behavior of the physical heat capacity, and thus provide a useful probe of gapless bulk or edge excitations of the system. Assuming a power-law scaling of the COE with an exponent $\alpha$ at low fictitious temperatures, we derive an analytical formula for the distribution function of the RDM eigenvalues. We numerically test the effectiveness of the formula in relativistic free scalar boson in two spatial dimensions, and find that the distribution function can detect the expected $\alpha=3$ scaling of the COE much more efficiently than the raw data of the COE. We also calculate the distribution function in the ground state of the half-filled Landau level with short-range interactions, and find a better agreement with the $\alpha=2/3$ formula than with the $\alpha=1$ one, which indicates a non-Fermi-liquid nature of the system.

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