스핀 글라스

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말뭉치

1. A diverse collection of condensed matter systems, such as ferroelectrics (11) and magnetic spin glasses (12), can be described by the TFIM.^[1]
2. Spin glasses are frustrated magnetic systems and a hallmark of their “glassiness” is the presence of a rugged energy landscape with many local minima.^[2]
3. A phenomenological theory of the ordered phase of short-range quantum Ising spin glass is developed in terms of droplet excitations, and presented in detail.^[3]
4. The magnetic disorder of spin glass compared to a ferromagnet is analogous to the positional disorder of glass (left) compared to quartz (right).^[4]
5. The term "glass" comes from an analogy between the magnetic disorder in a spin glass and the positional disorder of a conventional, chemical glass, e.g., a window glass.^[4]
6. It is the time dependence which distinguishes spin glasses from other magnetic systems.^[4]
7. Upon reaching T c , the sample becomes a spin glass and further cooling results in little change in magnetization.^[4]
8. We investigate the performance of continuous-time quantum walks as a tool for finding spin glass ground states, a problem that serves as a useful model for realistic optimization problems.^[5]
9. By performing detailed numerics, we uncover significant ways in which solving spin glass problems differs from applying quantum walks to the search problem.^[5]
10. Importantly, unlike for the search problem, parameters such as the hopping rate of the quantum walk do not need to be set precisely for the spin glass ground state problem.^[5]
11. An algorithm which is essentially a quantum walk on a spin glass, although presented using different terminology, has been analysed by Hastings (2019).^[5]
12. The spin glass, a network of frustrated spins with random bonds, exhibits a low temperature, non-ergodic phase with all spins frozen in a complex metastable state.^[6]
13. The spin glass and MBL phases have qualitative similarities; both are characterized by a breakdown of the ergodic behavior on which the foundations of statistical mechanics rest.^[6]
14. Both models show that the spin glass phase is accompanied by MBL, but that the MBL phase persists beyond the limit of the glass phase into paramagnetic phases.^[6]
15. In this phase the eigenstates are delocalized, the ETH is obeyed, and there is no spin glass order.^[6]
16. The phase transition in spin glasses is an intractable problem, since we must strive many-body system with complicated interactions with change of their signs depending on the distance between spins.^[7]
17. Several thermodynamic quantities are calculated numerically as well as spin self-interaction and spin glass order parameter for spin S=1/2.^[8]
18. Detailed discussion on quantum spin glasses and its application in solving combinatorial optimization problems is required for better understanding of quantum annealing concepts.^[9]
19. Fulfilling this requirement, the book highlights recent development in quantum spin glasses including Nishimori line, replica method and quantum annealing methods along with the essential principles.^[9]
20. Classical spin models from ferromagnetic spin systems to spin glasses 3.^[9]
21. The Ising spin glass model in a transverse field has a zero temperature phase transition driven solely by quantum fluctuations.^[10]
22. At the Conference on “Complex Quantum Systems out of Equilibrium” in Murcia, Spain I presented my latest work with Dmitry Abanin on the relation between MBL and spin glasses.^[11]
23. We show that a third, intermediate, state can emerge in a long-range one-dimensional spin glass under the applica- tion of a transverse field.^[11]
24. At small applied fields and low temperatures the spin glass order remains, as characterized by the Edwards-Anderson order parameter.^[11]
25. The ”quantum spin glass” is therefore neither ergodic, nor many-body localized.^[11]
26. In its simplest form, the emergent hierarchical order in spin glasses is mimicked by Derrida’s hierarchical models, which I will briefly review.^[12]
27. The main aim of this talk then concerns the fate of the spin glass phase under the addition of a constant perpendicular magnetic field.^[12]
28. The underlying principle of erasure of hierarchical spin glass order will be discussed.^[12]
29. In this talk I will discuss the possibility of many-body localization (MBL) in a model of quantum spin glass, namely, the quantum Sherrington-Kirkpatrick (SK) model.^[13]
30. Yet, the model captures the essential properties of the spin glass: its qualitative features directly apply to much more general models, including Sherrington-Kirkpatrick.^[14]
31. Solving spin glass models is a complex, often NP-hard, task.^[15]
32. A comparison with recent theoretical and experimental data in spin glass is made.^[16]
33. We describe the phase diagram of the system and discuss the realizability and detectability of the quantum spin glass and antiglass phases.^[17]
34. As a result, spin glass (6⇓⇓–9), charge glass (or charge-cluster glass) (10, 11), and superconducting vortex liquid/glass (12) all occur in the x-H-T phase diagram near the SIT.^[18]
35. The region is located within the thermodynamic spin glass phase.^[19]
36. These earlier works point to the necessity to examine a finite-connectivity quantum spin glass, in search of MBL.^[19]
37. In this section, we apply the previously described methods to the transverse-field Ising spin glass Hamiltonian (2.1).^[19]
38. Here, we immediately face an issue: the computation of the forward approximation is obstructed by the fact that the spin glass term has highly degenerate energy levels.^[19]

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위키데이터

• ID : Q1490646

Spacy 패턴 목록

• [{'LOWER': 'spin'}, {'LEMMA': 'glass'}]