5,140 research outputs found
Superfluidity and localization in Bosonic glasses
Bosonic excitations within long-range ordered, but strongly inhomogeneous phases have been studied in quite some detail. My thesis focuses instead on understanding the insulating, localized phase of disordered bosonic systems. In particular I study localization properties of strongly interacting bosons and spin systems in a disorder potential at zero temperature. I focus on simple, prototypical spin models (Ising model and XY model) in random fields on a Cayley tree with large connectivity. Regarding the nature of the quantum phase transition in strong disorder I find the following results: i) With a uniformly distributed disorder non-extensive excitations in the disordered phase are all localized. ii)Moreover, I find that the order arises due to a collective condensation, which is qualitatively distinct from a Bose Einstein condensation of single particle excitations into a delocalized state. In particular, in non-frustrated Bose glasses, I do not find evidence for a boson mobility edge in the Bose glass. These results are qualitatively different from claims in the recent literatures . Considering that (many body) localization of bosons is a kind of quantum glass transition, it is an interesting question to ask what phenomena occur, if the ingredients for more conventional (classical) glassy physics are added to a disordered bosons system, namely: random, frustrated interactions between the bosons. One can still think about such a system as bosons in a disordered potential, where the disordered potential is, at least partly, self-generated by random frustrated interactions between the bosons. This question takes us to the study of another type of disordered systems: glassy systems. Those are typically characterized by low temperature phases with an inhomogeneous density or magnetization pattern, which is extremely long-lived due
to the occurrence of non-trivial ergodicity breaking. I study a solvable model of hard core bosons (pseudospins) subject to disorder and frustrating interactions. This solvable model provides insight into the possibility of coexistence of super uidity and glassy density order, as well as into the nature of the coexistence phase (the superglass). In particular, for the considered mean field model I prove the existence of a superglass phase. This complements the numerical evidence for such phases provided by quantum Monte Carlo investigations in finite dimensions and on random graphs. Those were, however, limited to finite temperature, and could thus not fully elucidate the structure of the phases at T = 0. In contrast, my analytical approach allows one to understand the quantum phase transition between glassy superfluid and insulator, and the non-trivial role played by glassy correlations. When the frustrated interactions are strong enough, the superfluid order may be destroyed. As I will show in a mean field model, this happens within the glass phase of the system, where a disorder induced superfluid-insulator phase transition takes place to give way to a frustrated Bose glass. The glassy background on top of which this happens leads to many interesting phenomena which seem not to have been noticed before. To understand the nature of the glassy superfluid-insulator quantum phase transition at zero temperature and the transport properties on the insulating, Bose glass side of the transition is the goal of the third part of my thesis. To address the above questions, I studied an exactly solvable model of a glassy superfluid-insulator quantum phase transition on a Bethe lattice geometry with high connectivity. My main results can be summarized as follows: i) I found that the superfluid-insulator transition is shifted to stronger hopping. This is a result of the pseudo gap in the density of states of the glass state, which tends to strongly disfavor the onset of superfluidity. ii) In the glassy insulator, the discrete local energy levels become broadened due to the quantum fluctuations.The level-broadening process appears as a phase transition which has strong similarities with an Anderson localization transition, and has implications on many body localization. By using the locator expansion for bosons I found that, the glassy insulator has a finite mobility edge for the bosonic excitations, which, however, does not close upon approaching the SI quantum phase transition point. This finding helps to understand the nature of the superfluid-to-frustrated Bose glass transition: the superfluid emerges as a collective phase ordering phenomenon at zero temperature, and not as a condensation in to a single particle delocalized state, in contrast to opposite predictions in the recent literatures. The existence of a mobility edge in the insulator suggests the possibility of phononless, activated transport in the bosonic insulator, which might be a candidate explanation for the experimentally seen activated transport, which has remained a mystery for a long time
Spinor Walls in Five-Dimensional Warped Spacetime
We study domain wall solutions of a real spinor field coupling with
gravitation in five dimensions. We find that the nonlinear spinor field
supports a class of soliton configurations which could be viewed as a wall
embedded in five dimensions. We begin with an illuminating solution of the
spinor field in the absence of gravitation. In a further investigation, we
exhibit three sets of solutions of the spinor field with nonconstant curvature
bulk spacetimes and three sets of solutions corresponding to three constant
curvature bulk spacetimes. We demonstrate that some of these solutions in
specific conditions have the energy density distributions of domain walls for
the spinor field, where the scalar curvature is regular everywhere. Therefore,
the configurations of these walls can be interpreted as spinor walls which are
interesting spinor field realizations of domain walls. In order to investigate
the stability of these spinor configurations, the linear perturbations are
considered. The localization of the zero mode of tensor perturbation is also
discussed.Comment: 31 pages,5 figure
Influence of Reciprocal links in Social Networks
In this Letter, we empirically study the influence of reciprocal links, in
order to understand its role in affecting the structure and function of
directed social networks. Experimental results on two representative datesets,
Sina Weibo and Douban, demonstrate that the reciprocal links indeed play a more
important role than non-reciprocal ones in both spreading information and
maintaining the network robustness. In particular, the information spreading
process can be significantly enhanced by considering the reciprocal effect. In
addition, reciprocal links are largely responsible for the connectivity and
efficiency of directed networks. This work may shed some light on the in-depth
understanding and application of the reciprocal effect in directed online
social networks
Extending low energy effective field theory with a complete set of dimension-7 operators
We present a complete and independent set of dimension-7 operators in the low
energy effective field theory (LEFT) where the dynamical degrees of freedom are
the standard model five quarks and all of the neutral and charged leptons. All
operators are non-Hermitian and are classified according to their baryon
() and lepton () numbers violated. Including
Hermitian-conjugated operators, there are in total , , ,
operators with , , , respectively. We perform the tree-level matching with the standard
model effective field theory (SMEFT) up to dimension-7 (dim-7) operators in
both LEFT and SMEFT. As a phenomenological application we study the effective
neutrino-photon interactions due to dim-7 lepton number violating operators
that are induced and much enhanced at one loop from dim-6 operators that in
turn are matched from dim-7 SMEFT operators. We compare the cross sections of
various neutrino-photon scattering with their counterparts in the standard
model and highlight the new features. Finally we illustrate how these effective
interactions could arise from ultraviolet completion.Comment: 16 pages, 3 figure
High-Tech Service Platform Ecosystem Evolution: A Simulation Analysis using Lotka-Volterra Model
Technical service platform exerts a strong effect on supporting the innovation of the high-tech industry as a critical constituent of the modern service industry, and it can effectively enhance the development potential of technological innovation, but the degree of separation from technical service chain to high-tech industry chain is currently high. To explore how to improve the utilization efficiency of scientific and technological resources and facilitate the sustainable development of the high-tech industry by relying on technical service platform,a high-tech service platform was constructed by using Lotka-Volterra (L-V) model on the basis of ecosystem theory, the evolution path and stability conditions of high-tech service platform were analyzed followed by numerical simulation by Matlab computing. Results show that the development of hightech service platform follows the evolution path of "bilateral platform → core platform → platform ecosystem"; population evolution pattern in high-tech service platform ecosystem is decided by interdependence coefficient between populations; populations inside high-tech service platform ecosystem generate natural selection and synergistic effect and realize ecological balance among populations through evolution. Evolution of high-tech service platform system in this study provides a new theoretical framework for effective fusion and collaboration of science and technology service and industry, which is significant for elevating scientific and technological innovation level and improving technical service system construction
A Bilevel Optimization Method for Inverse Mean-Field Games
In this paper, we introduce a bilevel optimization framework for addressing
inverse mean-field games, alongside an exploration of numerical methods
tailored for this bilevel problem. The primary benefit of our bilevel
formulation lies in maintaining the convexity of the objective function and the
linearity of constraints in the forward problem. Our paper focuses on inverse
mean-field games characterized by unknown obstacles and metrics. We show
numerical stability for these two types of inverse problems. More importantly,
we, for the first time, establish the identifiability of the inverse mean-field
game with unknown obstacles via the solution of the resultant bilevel problem.
The bilevel approach enables us to employ an alternating gradient-based
optimization algorithm with a provable convergence guarantee. To validate the
effectiveness of our methods in solving the inverse problems, we have designed
comprehensive numerical experiments, providing empirical evidence of its
efficacy.Comment: 35 pages, 8 figures, 4 table
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