Jahr | 2018 |
Autor(en) | Isara Chantesana, Asier Piñeiro Orioli, and Thomas Gasenzer |
Titel | Kinetic theory of non-thermal fixed points in a Bose gas |
KIP-Nummer | HD-KIP 18-78 |
KIP-Gruppe(n) | F27 |
Dokumentart | Paper |
Quelle | Phys. Rev. A 99 (2019) 043620, arXiv:1801.09490 |
doi | http://dx.doi.org/10.1103/PhysRevA.99.043620 |
Abstract (en) | We outline a kinetic theory of non-thermal fixed points for the example of a dilute Bose gas, partially reviewing results obtained earlier, thereby extending, complementing, generalizing and straightening them out. We study universal dynamics after a cooling quench, focusing on situations where the time evolution represents a pure rescaling of spatial correlations, with time defining the scale parameter. The non-equilibrium initial condition set by the quench induces a redistribution of particles in momentum space. Depending on conservation laws, this can take the form of a wave-turbulent flux or of a more general self-similar evolution, signaling the critically slowed approach to a non-thermal fixed point. We identify such fixed points using a non-perturbative kinetic theory of collective scattering between highly occupied long-wavelength modes. In contrast, a wave-turbulent flux, possible in the perturbative Boltzmann regime, builds up in a critically accelerated self-similar manner. A key result is the simple analytical universal scaling form of the non-perturbative many-body scattering matrix, for which we lay out the concrete conditions under which it applies. We derive the scaling exponents for the time evolution as well as for the power-law tail of the momentum distribution function, for a general dynamical critical exponent z and an anomalous scaling dimension η. The approach of the non-thermal fixed point is, in particular, found to involve a rescaling of momenta in time t by tβ, with β=1/z, within our kinetic approach independent of η. We confirm our analytical predictions by numerically evaluating the kinetic scattering integral as well as the non-perturbative many-body coupling function. As a side result we obtain a possible finite-size interpretation of wave-turbulent scaling recently measured by Navon et al. |
bibtex | @article{Chantesana2018qsb, author = {Chantesana, Isara and Pi{\~n}eiro Orioli, Asier and Gasenzer, Thomas}, title = {Kinetic theory of non-thermal fixed points in a Bose gas}, journal = {Phys. Rev. A}, year = {2019}, volume = {99}, pages = {043620}, doi = {10.1103/PhysRevA.99.043620}, url = {http://xxx.arxiv.org/abs/1801.09490} } |
URL | arXiv:1801.09490 [cond-mat.quant-gas] |
URL | doi:10.1103/PhysRevA.99.043620 |
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