Asymptotic Growth of the Local Ground-State Entropy of the Ideal Fermi Gas in a Constant Magnetic Field

Leschke, Hajo; Sobolev, Alexander V.; Spitzer, Wolfgang

doi:10.1007/s00220-020-03907-w

Cited by 11 publications

(8 citation statements)

References 28 publications

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“…The following corollary is our main result. It combines Theorem 8 in [10], which can be stated as the corollary for the case B ε = V ε = 0, with our Theorem 3.5.…”

Section: Setting and Main Resultsmentioning

confidence: 86%

“…This allows us to focus on bounding the error term that arises, as we introduce a perturbation to H 0 . Our main result is Corollary 3.6 and relies on the exact calculations of the leading term for H = H 0 , see [10], and the estimates we will prove in this paper.…”

Section: Setting and Main Resultsmentioning

confidence: 88%

“…This quantity is the local entropy or entanglement entropy of the ground state restricted to LΛ. Under the assumption that Λ has C 2 boundary, the leading term of order L for the operator H = H 0 has been calculated by Leschke, Sobolev and Spitzer in [10]. This allows us to focus on bounding the error term that arises, as we introduce a perturbation to H 0 .…”

Section: Setting and Main Resultsmentioning

confidence: 99%

“…If we assume V ε > 0 pointwise, then all eigenvalues of H are strictly larger than B 0 and hence 1 I (H) = 0. But Theorem 8 in [10], which we will elaborate on shortly, states, that the leading order asymptotic expansion of tr h α (1 LΛ 1 I (H 0 )1 LΛ ) for large L is of order O(L) and does not vanish. On the other hand, if we assume that V ε < 0 pointwise, there is a spectral gap of the form (B 0 , B 0 + δ] in the spectrum of H. Hence, we can move b to B 0 + δ without changing the operators.…”

Section: Setting and Main Resultsmentioning

confidence: 99%

“…Entanglement entropy of the ground state of the latter Landau Hamiltonian (for the ground state with chemical potential µ = B 0 ) has been studied in [11,18,19] with some additional assumptions on the region Λ. The case of µ = B 0 has been solved by Charles and Estienne in [3] and then for arbitrary µ by Leschke, Sobolev and Spitzer in [10], both under some regularity assumptions on the boundary ∂Λ. Our main result is Corollary 3.6.…”

Section: Introductionmentioning

confidence: 99%

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On the stability of the area law for the entanglement entropy of the Landau Hamiltonian

Pfeiffer

2021

Preprint

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We consider the two-dimensional ideal Fermi gas subject to a magnetic field which is perpendicular to the Euclidean plane R 2 and whose strength B(x) at x ∈ R 2 converges to some B 0 > 0 as x → ∞. Furthermore, we allow for an electric potential Vε which vanishes at infinity. They define the single-particle Landau Hamiltonian of our Fermi gas (up to gauge fixing). Starting from the ground state of this Fermi gas with chemical potential µ ≥ B 0 we study the asymptotic growth of its bipartite entanglement entropy associated to LΛ as L → ∞ for some fixed bounded region Λ ⊂ R 2 . We show that its leading order in L does not depend on the perturbations Bε := B 0 − B and Vε if they satisfy some mild decay assumptions. Our result holds for all α-Rényi entropies α > 1/3; for α ≤ 1/3, we have to assume in addition some differentiability of the perturbations Bε and Vε. The case of a constant magnetic field Bε = 0 and with Vε = 0 was treated recently for general µ by Leschke, Sobolev and Spitzer. Our result thus proves the stability of that area law under the same regularity assumptions on the boundary ∂Λ.

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“…The following corollary is our main result. It combines Theorem 8 in [10], which can be stated as the corollary for the case B ε = V ε = 0, with our Theorem 3.5.…”

Section: Setting and Main Resultsmentioning

confidence: 86%

Section: Setting and Main Resultsmentioning

confidence: 88%

Section: Setting and Main Resultsmentioning

confidence: 99%

Section: Setting and Main Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

On the stability of the area law for the entanglement entropy of the Landau Hamiltonian

Pfeiffer

2021

Preprint

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Logarithmically Enhanced Area-Laws for Fermions in Vanishing Magnetic Fields in Dimension Two

Pfeiffer,

Spitzer

2024

Integr. Equ. Oper. Theory

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We consider fermionic ground states of the Landau Hamiltonian, $$H_B$$ H B , in a constant magnetic field of strength $$B>0$$ B > 0 in $${\mathbb {R}}^2$$ R 2 at some fixed Fermi energy $$\mu >0$$ μ > 0 , described by the Fermi projection $$P_B:=1(H_B\le \mu )$$ P B : = 1 ( H B ≤ μ ) . For some fixed bounded domain $$\Lambda \subset {\mathbb {R}}^2$$ Λ ⊂ R 2 with boundary set $$\partial \Lambda $$ ∂ Λ and an $$L>0$$ L > 0 we restrict these ground states spatially to the scaled domain $$L \Lambda $$ L Λ and denote the corresponding localised Fermi projection by $$P_B(L\Lambda )$$ P B ( L Λ ) . Then we study the scaling of the Hilbert-space trace, $$\textrm{tr} f(P_B(L\Lambda ))$$ tr f ( P B ( L Λ ) ) , for polynomials f with $$f(0)=f(1)=0$$ f ( 0 ) = f ( 1 ) = 0 of these localised ground states in the joint limit $$L\rightarrow \infty $$ L → ∞ and $$B\rightarrow 0$$ B → 0 . We obtain to leading order logarithmically enhanced area-laws depending on the size of LB. Roughly speaking, if 1/B tends to infinity faster than L, then we obtain the known enhanced area-law (by the Widom–Sobolev formula) of the form $$L \ln (L) a(f,\mu ) |\partial \Lambda |$$ L ln ( L ) a ( f , μ ) | ∂ Λ | as $$L\rightarrow \infty $$ L → ∞ for the (two-dimensional) Laplacian with Fermi projection $$1(H_0\le \mu )$$ 1 ( H 0 ≤ μ ) . On the other hand, if L tends to infinity faster than 1/B, then we get an area law with an $$L \ln (\mu /B) a(f,\mu ) |\partial \Lambda |$$ L ln ( μ / B ) a ( f , μ ) | ∂ Λ | asymptotic expansion as $$B\rightarrow 0$$ B → 0 . The numerical coefficient $$a(f,\mu )$$ a ( f , μ ) in both cases is the same and depends solely on the function f and on $$\mu $$ μ . The asymptotic result in the latter case is based upon the recent joint work of Leschke, Sobolev and the second named author [7] for fixed B, a proof of the sine-kernel asymptotics on a global scale, and on the enhanced area-law in dimension one by Landau and Widom. In the special but important case of a quadratic function f we are able to cover the full range of parameters B and L. In general, we have a smaller region of parameters (B, L) where we can prove the two-scale asymptotic expansion $$\textrm{tr} f(P_B(L\Lambda ))$$ tr f ( P B ( L Λ ) ) as $$L\rightarrow \infty $$ L → ∞ and $$B\rightarrow 0$$ B → 0 .

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Stability of the Enhanced Area Law of the Entanglement Entropy

Müller

Schulte

2020

Ann. Henri Poincaré

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We consider a multi-dimensional continuum Schrödinger operator which is given by a perturbation of the negative Laplacian by a compactly supported potential. We establish both an upper bound and a lower bound on the bipartite entanglement entropy of the ground state of the corresponding quasi-free Fermi gas. The bounds prove that the scaling behaviour of the entanglement entropy remains a logarithmically enhanced area law as in the unperturbed case of the free Fermi gas. The central idea for the upper bound is to use a limiting absorption principle for such kinds of Schrödinger operators.

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Asymptotic Growth of the Local Ground-State Entropy of the Ideal Fermi Gas in a Constant Magnetic Field

Abstract: We consider the ideal Fermi gas of indistinguishable particles without spin but with electric charge, confined to a Euclidean plane $${{\mathbb {R}}}^2$$ R 2 perpendicular to an external constant magnetic field of strength $$B>0$$ B > 0 . We assume this (i… Show more

Cited by 11 publications

References 28 publications

On the stability of the area law for the entanglement entropy of the Landau Hamiltonian

On the stability of the area law for the entanglement entropy of the Landau Hamiltonian

Logarithmically Enhanced Area-Laws for Fermions in Vanishing Magnetic Fields in Dimension Two

Stability of the Enhanced Area Law of the Entanglement Entropy

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