Academia.eduAcademia.edu

Outline

Title
Abstract
Introduction
Multi-Fractality Analysis
References
All Topics
Physics

Multifractality of the entanglement Hamiltonian eigenmodes

Profile image of Mohammad PouranvariMohammad Pouranvari

2019, Physical Review B

https://doi.org/10.1103/PHYSREVB.99.155121
visibility

description

8 pages

link

1 file

Abstract

We study the fractal properties of single-particle eigen-modes of entanglement Hamiltonian in free fermion models. One of these modes that has the highest entanglement information and thus called maximally entangled mode (MEM) is specially considered. In free Fermion models with Anderson localization, fractality of MEM is obtained numerically and compared with the fractality of Hamiltonian eigen-mode at Fermi level. We show that both eigen-modes have similar fractal properties: both have same single fractal dimension in delocalized phase which equals the dimension of the system, and both show multi-fractality at phase transition point. Therefore, we conclude that, fractal behavior of MEM -in addition to the fractal behavior of Hamiltonian eigen-mode -can be used as a quantum phase transition characterization.

Related papers

Statistical Mechanics and Quantum Fields on Fractals
Eric Akkermans

Contemporary Mathematics, 2013

Fractals define a new and interesting realm for a discussion of basic phenomena in quantum field theory and statistical mechanics. This interest results from specific properties of fractals, e.g., their dilatation symmetry and the corresponding absence of Fourier mode decomposition. Moreover, the existence of a set of distinct dimensions characterizing the physical properties (spatial or spectral) of fractals make them a useful testing ground for dimensionality dependent physical problems. This paper addresses specific problems including the behavior of the heat kernel and spectral zeta functions on fractals and their importance in the expression of spectral properties in quantum physics. Finally, we apply these results to specific problems such as thermodynamics of quantum radiation by a fractal blackbody.

View PDFchevron_right
Energy level dynamics in systems with weakly multifractal eigenstates: Equivalence to one-dimensional correlated fermions at low temperatures
Vladimir Kravtsov

2000

It is shown that the parametric spectral statistics in the critical random matrix ensemble with multifractal eigenvector statistics are identical to the statistics of correlated 1D fermions at finite temperatures. For weak multifractality the effective temperature of fictitious 1D fermions is proportional to T ef f ∝ (1 − dn)/n ≪ 1, where dn is the fractal dimension found from the n-th moment of inverse participation ratio. For large energy and parameter separations the fictitious fermions are described by the Luttinger liquid model which follows from the Calogero-Sutherland model. The low-temperature asymptotic form of the two-point equal-parameter spectral correlation function is found for all energy separations and its relevance for the low temperature equal-time density correlations in the Calogero-Sutherland model is conjectured.

View PDFchevron_right
Multifractality of open quantum systems
Agustin Bilen

Physical review, 2019

We study the eigenstates of open maps whose classical dynamics is pseudointegrable and for which the corresponding closed quantum system has multifractal properties. Adapting the existing general framework developed for open chaotic quantum maps, we specify the relationship between the eigenstates and the classical structures, and we quantify their multifractality at different scales. Based on this study, we conjecture that quantum states in such systems are distributed according to a hierarchy of classical structures, but these states are multifractal instead of ergodic at each level of the hierarchy. This is visible for sufficiently long-lived resonance states at scales smaller than the classical structures. Our results can guide experimentalists in order to observe multifractal behavior in open systems.

View PDFchevron_right
Universal aspects in the behavior of the entanglement spectrum in one dimension: Scaling transition at the factorization point and ordered entangled structures
Silvio De Siena

Physical Review B, 2013

We investigate the scaling of the entanglement spectrum and of the Rényi block entropies and determine its universal aspects in the ground state of critical and noncritical one-dimensional quantum spin models. In all cases, the scaling exhibits an oscillatory behavior that terminates at the factorization point and whose frequency is universal. Parity effects in the scaling of the Rényi entropies for gapless models at zero field are thus shown to be a particular case of such universal behavior. Likewise, the absence of oscillations for the Ising chain in transverse field is due to the vanishing value of the factorizing field for this particular model. In general, the transition occurring at the factorizing field between two different scaling regimes of the entanglement spectrum corresponds to a quantum transition to the formation of finite-range, ordered structures of quasi-dimers, quasitrimers, and quasi-polymers. This entanglement-driven transition is superimposed to and independent of the long-range magnetic order in the broken symmetry phase. Therefore, it conforms to recent generalizations that identify and classify the quantum phases of matter according to the structure of ground-state entanglement patterns. We characterize this form of quantum order by a global order parameter of entanglement defined as the integral, over blocks of all lengths, of the Rényi entropy of infinite order. Equivalently, it can be defined as the integral of the bipartite single-copy or geometric entanglement. The global entanglement order parameter remains always finite at fields below the factorization point and vanishes identically above it.

View PDFchevron_right
On the asymptotic properties of quantum dynamics in the presence of fractal spectrum
Giorgio Mantica

On the asymptotic properties of quantum dynamics in the presence of a fractal spectrum

View PDFchevron_right
Entropy of entanglement and multifractal exponents for random states
Bertrand Georgeot

Physical Review A, 2009

We relate the entropy of entanglement of ensembles of random vectors to their generalized fractal dimensions. Expanding the von Neumann entropy around its maximum we show that the first order only depends on the participation ratio, while higher orders involve other multifractal exponents. These results can be applied to entanglement behavior near the Anderson transition.

View PDFchevron_right
Multifractality of quantum wave packets
Bertrand Georgeot

We study a version of the mathematical Ruijsenaars-Schneider model and reinterpret it physically in order to describe the spreading with time of quantum wave packets in a system where multifractality can be tuned by varying a parameter. We compare different methods to measure the multifractality of wave packets and identify the best one. We find the multifractality to decrease with time until it reaches an asymptotic limit, which is different from the multifractality of eigenvectors but related to it, as is the rate of the decrease. Our results could guide the study of experimental situations where multifractality is present in quantum systems.

View PDFchevron_right
Fractal character of wave functions in one-dimensional incommensurate systems
Aristides Zdetsis

Physical review. B, Condensed matter, 1986

The electronic wave functions of simple one-dimensional systems with a modulation potential incommensurate with that of the underlying lattice are determined by a direct diagonalization method. The existence of the metal-insulator transition is also obtained by a renormalization-group method. Numerical evidence for a fractal character of the wave functions is obtained and the fractal dimensionality D is calculated as a function of the strength of the modulation potential Vo. At the critical point Vo-2t, we find that D =0.80+0. 15. The wave functions can also be characterized by the localization length i, and the amplitude correlation length g.

View PDFchevron_right
Entanglement in disordered systems at criticality
Varga Imre

physica status solidi (c), 2008

Entanglement is a physical resource of a quantum system just like mass, charge or energy. Moreover it is an essential tool for many purposes of nowadays quantum information processing, e.g. quantum teleportation, quantum cryptography or quantum computation. In this work we investigate an extended system of N qubits. In our system a qubit is the absence or presence of an electron at a site of a tight-binding system. Several measures of entangle-ment between a given qubit and the rest of the system and also the entanglement between two qubits and the rest of the system is calculated in a one-electron picture in the presence of disorder. We invoke the power law band random matrix model which even in one dimension is able to produce multifractal states that fluctuate at all length scales. The concurrence, the tangle and the entanglement entropy all show interesting scaling properties.

View PDFchevron_right
Entanglement measure for the universal classes of fractons
Wellington da Cruz

Physica A: Statistical Mechanics and its Applications, 2005

We introduce the notion of entanglement measure for the universal classes of fractons as an entanglement between ocuppation-numbers of fractons in the lowest Landau levels and the rest of the many-body system of particles. This definition came as an entropy of the probability distributionà la Shannon. Fractons are charge-flux systems classified in universal classes of particles or quasiparticles labelled by a fractal or Hausdorff dimension defined within the interval 1 < h < 2 and associated with the fractal quantum curves of such objects. They carry rational or irrational values of spin and the spin-statistics connection takes place in this fractal approach to the fractional spin particles. We take into account the fractal von Neumann entropy associated with the fractal distribution function which each universal class of fractons satisfies. We consider the fractional quantum Hall effect-FQHE given that fractons can model Hall states. According to our formulation entanglement between occupaton-numbers in this context increases with the universality classes of the quantum Hall transitions considered as fractal sets of dual topological quantum numbers filling factors. We verify that the Hall states have stronger entanglement between ocuppation-numbers and so we can consider this resource for fracton quantum computing.

View PDFchevron_right

References (54)

  1. P. W. Anderson, Phys. Rev. 109, 1492 (1958).
  2. F. Evers and A. D. Mirlin, Rev. Mod. Phys. 80, 1355 (2008).
  3. F. Wegner, Z. Phys. B, 36, 206 (1980).
  4. H. E. Stanley, L. A. N. Amaral, A. L. Goldberger, S. Havlin, P. Ch. Ivanov, C.-K. Pengb, Physica A: Statistical Mechanics and its Applications, 270, 309, (1999).
  5. P. Ch. Ivanov, L. A. N. Amaral, A. L. Goldberger, S. Havlin, M. G. Rosenblum, H. E. Stanley, Z. R. Struzik, Chaos: An Interdisciplinary Journal of Nonlinear Science, 11, 3,(2001).
  6. A. Davis, A. Marshak, W. Wiscombe, R. Cahalan, Journal of Geophysical Research: Atmospheres, 99, 8055 (1994).
  7. Y. Tessier, S. Lovejoy, P. Hubert, D. Schertzer, S. Pec- knold, Journal of Geophysical Research: Atmospheres, 101, 26427, (1996). S. Lovejoy, D. Schertzer, Journal of Geophysical Research: Atmospheres, 95, 2021 (1990).
  8. L. Biferale, G. Boffetta, A. Celani, B. J. Devenish, A. Lan- otte, and F. Toschi, Phys. Rev. Lett. 93, 064502 (2004).
  9. C. Meneveau, K. R. Sreenivasan, Nuclear Physics B, 2, 0920, (1987).
  10. D. Schertzer et al, Fractals 05, 427 (1997).
  11. R. R. Prasad, C. Meneveau, and K. R. Sreenivasan, Phys. Rev. Lett. 61, 74 (1988).
  12. C. Meneveau, K. R. Sreenivasan, P. Kailasnath, M. S. Fan, Phys. Rev. A 41, 894 (1990).
  13. R. Benzi, G. Paladin, G. Parisi, A. Vulpiani , Journal of Physics A: Mathematical and General, 61, 3521 (1984).
  14. L . Zunino, B. M. Tabak, A. Figliola, D. G. Perez, M. Garavaglia, O. A. Rosso, Physica A: Statistical Mechanics and its Applications, 387, 6558 (2008).
  15. K. Matia, Y. Ashkenazy, H. E. Stanley, Europhysics Let- ters, 61, 422 (2003).
  16. X. Sun, H. Chen, Z. Wu,Y. Yuan, Physica A: Statistical Mechanics and its Applications, 291, 553 (2001).
  17. P. Oswiecimka, J. Kwapien, S. Drozdz, Physica A: Statis- tical Mechanics and its Applications, 347, 626 (2005).
  18. P. Oswiecimka, S. Drozdz, J. Kwapien, A. Z. Gorski, Acta Physica Polonica A 117, 637 (2010).
  19. A. D. Zdetsis, C. M. Soukoulis, and E. N. Economou, Phys. Rev. B 33, 4936 (1986).
  20. C. M. Soukoulis and E. N. Economou, Phys. Rev. Lett. 52, 565 (1984).
  21. C. Castellani and L. Peliti, J. Phys. A:Math. Gen. 19 L429 (1986).
  22. H. Aoki, J. Phys. C 16, L205 (1983).
  23. V. I. Falko and K. B. Efetov, Europhysics Letters, 32, 8 (1995).
  24. A. Mildenberger and F. Evers, Phys. Rev. B 75, 041303(R) (2007).
  25. M. Janseen, Int. J. Mod. Phys. B 8, 943 (1994).
  26. A. D. Mirlin, Y.V.Fyodorov, A.Mildenberger, F.Evers, Phys. Rev. Lett. 97, 046803 (2006).
  27. X. Jia, A. R. Subramaniam, I. A. Gruzberg, and S. Chakravarty, Phys. Rev. B 77, 014208 (2008).
  28. O. Giraud, J. Martin, and B. Georgeot, Phys. Rev. A 79, 032308 (2009).
  29. X. Chen, B. Hsu, T. L. Hughes, and E. Fradkin Phys. Rev. B 86, 134201 (2012).
  30. L. J. Vasquez, A. Rodriguez, and R. A. Romer, Phys. Rev. B 78, 195106 (2008).
  31. A. Rodriguez, L. J. Vasquez, and R. A. Romer, Phys. Rev. B 78, 195107 (2008).
  32. A. Rodriguez, L. J. Vasquez, and R. A. Romer, Phys. Rev. Lett. 102, 106406 (2009)
  33. I. Klich, Phys. A: Math.Gen. 39, L85 (2006).
  34. M. Pouranvari, K. Yang, Phys. Rev. B 89, 115104 (2014).
  35. M. Pouranvari, K. Yang, Phys. Rev. B 88, 075123 (2013).
  36. M. Pouranvari, K. Yang, Phys. Rev. B 92, 245134 (2015).
  37. M. Pouranvari, A. Montakhab, Phys. Rev. B, 96, 045123 (2017).
  38. Aubry, S. Andre, G. Ann. Israel. Phys. Soc. 3, 133 (1980).
  39. R. P. A. Lima, H. R. da Cruz, J. C. Cressoni, and M. L. Lyra, Phys. Rev. B 69, 165117 (2004).
  40. A. D. Mirlin, Y. V. Fyodorov, F. M. Dittes, J. Quezada, and T. H. Seligman Phys. Rev. E 54, 3221 (1996).
  41. J.V. Jose and R. Cordery, Phys. Rev. Lett. 56, 290 (1986).
  42. A.V. Balatsky and M.I. Salkola, Phys. Rev. Lett. 76, 2386 (1996).
  43. B.L. Altshuler and L.S. Levitov, Phys. Rep. 288, 487 (1997).
  44. I.V. Ponomarev and P.G. Silvestrov, Phys. Rev. B 56, 3742 (1997).
  45. G. Casati and T. Prosen, Physica D 131, 293 (1999);
  46. F. Borgonovi, P. Conti, D. Rebuzzi, B. Hu, and B. Li, Physica D 131, 317 (1999).
  47. A. D. Mirlin and F. Evers, Phys. Rev. B 62,7920 (2000).
  48. P. Markos, Acta Physica Slovaca. Reviews and Tutorials. 56, 561 (2010).
  49. S. Drozdz and P. Oswiecimka, Phys. Rev. E 91, 030902(R) (2015).
  50. V. Eisler and I. Peschel, Journal of Physics A: Mathemat- ical and Theoretical 50, 284003 (2017)
  51. I. Peschel and M. C. Chung, EPL (Europhysics Letters) 96, 50006 (2011)
  52. A. Zhao, R. L. Chu, S. Q. Shen, Phys. Rev. B 87, 205140 (2013).
  53. F. Igloi and Y. Lin, J. Stat. Mech. (2008) P06004.
  54. Y. Wang, T. Gulden, A. Kamenev, Phys. Rev. B 95, 075401 (2017).

Related papers

Fractality of certain quantum states
Daniel Wójcik

We prove the theorem announced in Phys. Rev. Lett. 85:5022, 2001 concerning the existence and properties of fractal states for the Schrödinger equation in the infinite one-dimensional well.

View PDFchevron_right
Quantum fractal eigenstates
giulio maspero

Physica D: Nonlinear Phenomena, 1999

We study quantum chaos in open dynamical systems and show that it is characterized by quantum fractal eigenstates located on the underlying classical strange repeller. The states with longest life times typically reveal a scars structure on the classical fractal set.

View PDFchevron_right
Fractal states in quantum information processing
Gregg Jaeger

Physics Letters A, 2006

The fractal character of some quantum properties has been shown for systems described by continuous variables. Here, a definition of quantum fractal states is given that suits the discrete systems used in quantum information processing, including quantum coding and quantum computing.

View PDFchevron_right
A note on Decoherence and Fractal Hamiltonians
Evgeny I Zelenov

2020

The article contains the description of a coherent conservation regime in the spin bath quantum decoherence model.

View PDFchevron_right
Entanglement and area law with a fractal boundary in a topologically ordered phase
Alioscia Hamma

Physical Review A, 2010

Quantum systems with short range interactions are known to respect an area law for the entanglement entropy: the von Neumann entropy S associated to a bipartition scales with the boundary p between the two parts. Here we study the case in which the boundary is a fractal. We consider the topologically ordered phase of the toric code with a magnetic field. When the field vanishes it is possible to analytically compute the entanglement entropy for both regular and fractal bipartitions (A, B) of the system, and this yields an upper bound for the entire topological phase. When the A-B boundary is regular we have S/p = 1 for large p. When the boundary is a fractal of Hausdorff dimension D, we show that the entanglement between the two parts scales as S/p = γ ≤ 1/D, and γ depends on the fractal considered.

View PDFchevron_right

Related topics

  • Physics
    • 580 California St., Suite 400
    San Francisco, CA, 94104
    © 2025 Academia. All rights reserved