The definition of the velocity field in many body systems

Abstract The rooted maps theory, a branch of the theory of homology, is shown to be a powerful tool for investigating the topological properties of Feynman diagrams, related to the single particle propagator in the quantum many-body systems. The numerical correspondence between the number of this class of Feynman diagrams as a function of perturbative order and the number of rooted maps as a function of the number of edges is studied. A graphical procedure to associate Feynman diagrams and rooted maps is then stated. Finally, starting from rooted maps principles, an original definition of the genus of a Feynman diagram, which totally differs from the usual one, is given.

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Discrete Time Crystals

Annual Review of Condensed Matter Physics ◽

10.1146/annurev-conmatphys-031119-050658 ◽

2020 ◽

Vol 11 (1) ◽

pp. 467-499 ◽

Cited By ~ 12

Author(s):

Dominic V. Else ◽

Christopher Monroe ◽

Chetan Nayak ◽

Norman Y. Yao

Keyword(s):

Discrete Time ◽

Quantum Dynamics ◽

Many Body ◽

Time Translation ◽

Translation Symmetry ◽

Interesting Class ◽

Many Body Systems ◽

Definition Of ◽

Many Body Interactions ◽

Time Crystals

Experimental advances have allowed for the exploration of nearly isolated quantum many-body systems whose coupling to an external bath is very weak. A particularly interesting class of such systems is those that do not thermalize under their own isolated quantum dynamics. In this review, we highlight the possibility for such systems to exhibit new nonequilibrium phases of matter. In particular, we focus on discrete time crystals, which are many-body phases of matter characterized by a spontaneously broken discrete time-translation symmetry. We give a definition of discrete time crystals from several points of view, emphasizing that they are a nonequilibrium phenomenon that is stabilized by many-body interactions, with no analog in noninteracting systems. We explain the theory behind several proposed models of discrete time crystals, and compare several recent realizations, in different experimental contexts.

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THE UNIVERSAL EQUATIONS OF MOTION FOR NONLINEAR FIELDS IN DIFFERENT BASES DESCRIBING STRONGLY INTERACTING MANY-BODY SYSTEMS WITH TWO-BODY INTERACTIONS

International Journal of Modern Physics B ◽

10.1142/s0217979295000690 ◽

1995 ◽

Vol 09 (13n14) ◽

pp. 1611-1637 ◽

Cited By ~ 3

Author(s):

J.M. DIXON ◽

J.A. TUSZYŃSKI

Keyword(s):

Plane Wave ◽

Coherent Structures ◽

Equations Of Motion ◽

Quantum Field ◽

Many Body ◽

Field Equations ◽

Strongly Interacting ◽

Highly Nonlinear ◽

Many Body Systems ◽

Definition Of

A brief account of the Method of Coherent Structures (MCS) is presented using a plane-wave basis to define a quantum field. It is also demonstrated that the form of the quantum field equations, obtained by MCS, although highly nonlinear for many-body systems with two-body interactions, is independent of the basis of states used for the definition of the field.

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Mathematical analysis of time flow

Analysis ◽

10.1515/anly-2015-5005 ◽

2016 ◽

Vol 36 (1) ◽

Cited By ~ 4

Author(s):

Rudolf Hilfer

Keyword(s):

Mathematical Analysis ◽

Stationary Solutions ◽

Bounded Mean Oscillation ◽

Many Body ◽

C Algebras ◽

Mean Oscillation ◽

Time Flow ◽

Long Time ◽

Many Body Systems ◽

Definition Of

AbstractThe mathematical analysis of time flow in physical many-body systems leads to the study of long-time limits. This article discusses the interdisciplinary problem of local stationarity, how stationary solutions can remain slowly time dependent after a long-time limit. A mathematical definition of almost invariant and nearly indistinguishable states on C*-algebras is introduced using functions of bounded mean oscillation. Rescaling of time yields generalized time flows of almost invariant and macroscopically indistinguishable states, that are mathematically related to stable convolution semigroups and fractional calculus. The infinitesimal generator is a fractional derivative of order less than or equal to unity. Applications of the analysis are given to irreversibility and to a physical experiment.

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REGULAR STRUCTURE OF LOW-LYING STATES FOR ATOMIC NUCLEI UNDER RANDOM INTERACTIONS

International Journal of Modern Physics E ◽

10.1142/s021830130801194x ◽

2008 ◽

Vol 17 (supp01) ◽

pp. 304-317

Author(s):

Y. M. ZHAO

Keyword(s):

Ground State ◽

Collective Motion ◽

Regular Structure ◽

Positive Parity ◽

Many Body ◽

Random Interactions ◽

Atomic Nuclei ◽

Many Body Systems

In this paper we review regularities of low-lying states for many-body systems, in particular, atomic nuclei, under random interactions. We shall discuss the famous problem of spin zero ground state dominance, positive parity dominance, collective motion, odd-even staggering, average energies, etc., in the presence of random interactions.

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Emergence of a Renormalized 1/N Expansion in Quenched Critical Many-Body Systems

Physical Review Letters ◽

10.1103/physrevlett.126.110602 ◽

2021 ◽

Vol 126 (11) ◽

Author(s):

Benjamin Geiger ◽

Juan Diego Urbina ◽

Klaus Richter

Keyword(s):

Many Body ◽

Many Body Systems

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Dynamic Kibble-Zurek scaling framework for open dissipative many-body systems crossing quantum transitions

Physical Review Research ◽

10.1103/physrevresearch.2.023211 ◽

2020 ◽

Vol 2 (2) ◽

Cited By ~ 5

Author(s):

Davide Rossini ◽

Ettore Vicari

Keyword(s):

Many Body ◽

Quantum Transitions ◽

Many Body Systems

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Continuous Phase Transition without Gap Closing in Non-Hermitian Quantum Many-Body Systems

Physical Review Letters ◽

10.1103/physrevlett.125.260601 ◽

2020 ◽

Vol 125 (26) ◽

Cited By ~ 2

Author(s):

Norifumi Matsumoto ◽

Kohei Kawabata ◽

Yuto Ashida ◽

Shunsuke Furukawa ◽

Masahito Ueda

Keyword(s):

Phase Transition ◽

Continuous Phase ◽

Many Body ◽

Continuous Phase Transition ◽

Many Body Systems ◽

Gap Closing

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Universal relations for ultracold reactive molecules

Science Advances ◽

10.1126/sciadv.abd4699 ◽

2020 ◽

Vol 6 (51) ◽

pp. eabd4699

Author(s):

Mingyuan He ◽

Chenwei Lv ◽

Hai-Qing Lin ◽

Qi Zhou

Keyword(s):

Critical Role ◽

Interaction Strength ◽

Quantum Correlations ◽

Polar Molecules ◽

Many Body ◽

Density Correlation ◽

Ultracold Polar Molecules ◽

Unexplored Area ◽

Many Body Systems

The realization of ultracold polar molecules in laboratories has pushed physics and chemistry to new realms. In particular, these polar molecules offer scientists unprecedented opportunities to explore chemical reactions in the ultracold regime where quantum effects become profound. However, a key question about how two-body losses depend on quantum correlations in interacting many-body systems remains open so far. Here, we present a number of universal relations that directly connect two-body losses to other physical observables, including the momentum distribution and density correlation functions. These relations, which are valid for arbitrary microscopic parameters, such as the particle number, the temperature, and the interaction strength, unfold the critical role of contacts, a fundamental quantity of dilute quantum systems, in determining the reaction rate of quantum reactive molecules in a many-body environment. Our work opens the door to an unexplored area intertwining quantum chemistry; atomic, molecular, and optical physics; and condensed matter physics.

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Epidemic growth and Griffiths effects on an emergent network of excited atoms

Nature Communications ◽

10.1038/s41467-020-20333-7 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

T. M. Wintermantel ◽

M. Buchhold ◽

S. Shevate ◽

M. Morgado ◽

Y. Wang ◽

...

Keyword(s):

Complex Systems ◽

Power Laws ◽

Excitation Density ◽

Griffiths Phase ◽

Many Body ◽

Excited Atoms ◽

Equilibrium Dynamics ◽

Many Body Systems ◽

Excitation Number ◽

Non Equilibrium

AbstractWhether it be physical, biological or social processes, complex systems exhibit dynamics that are exceedingly difficult to understand or predict from underlying principles. Here we report a striking correspondence between the excitation dynamics of a laser driven gas of Rydberg atoms and the spreading of diseases, which in turn opens up a controllable platform for studying non-equilibrium dynamics on complex networks. The competition between facilitated excitation and spontaneous decay results in sub-exponential growth of the excitation number, which is empirically observed in real epidemics. Based on this we develop a quantitative microscopic susceptible-infected-susceptible model which links the growth and final excitation density to the dynamics of an emergent heterogeneous network and rare active region effects associated to an extended Griffiths phase. This provides physical insights into the nature of non-equilibrium criticality in driven many-body systems and the mechanisms leading to non-universal power-laws in the dynamics of complex systems.

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