Global dynamics and diffusion in the rational standard map. (English) Zbl 1491.37001
Summary: In this paper we study the dynamics of the Rational Standard Map, which is a generalization of the Standard Map. It depends on two parameters, the usual \(K\) and a new one, \(0 \leq \mu < 1\), that breaks the entire character of the perturbing function. By means of analytical and numerical methods it is shown that this system presents significant differences with respect to the classical Standard Map. In particular, for relatively large values of \(K\) the integer and semi-integer resonances are stable for some range of \(\mu\) values. Moreover, for \(K\) not small and near suitable values of \(\mu\), its dynamics could be assumed to be well represented by a nearly integrable system. On the other hand, periodic solutions or accelerator modes also show differences between this map and the standard one. For instance, in case of \(K \approx 2\pi\) accelerator modes exist for \(\mu\) less than some critical value but also within very narrow intervals when \(0.9 < \mu < 1\). Big differences for the domains of existence of rotationally invariant curves (much larger, for \(\mu\) moderate, or much smaller, for \(\mu\) close to 1 than for the standard map) appear. While anomalies in the diffusion are observed, for large values of the parameters, the system becomes close to an ergodic one.
MSC:
| 37A05 | Dynamical aspects of measure-preserving transformations |
| 37C05 | Dynamical systems involving smooth mappings and diffeomorphisms |
| 37E05 | Dynamical systems involving maps of the interval |
| 37A35 | Entropy and other invariants, isomorphism, classification in ergodic theory |
| 94A17 | Measures of information, entropy |
| 39B12 | Iteration theory, iterative and composite equations |
Keywords:
area-preserving maps; rational standard map; global dynamics; chaotic diffusion; Shannon entropyReferences:
| [1] | B.V. Chirikov, Institute of Nuclear Physics, Novosibirsk (in Russian), Preprint 267 (1969), Engl. Transl. CERN Trans. 71-40, Geneva, (1971). Available at http://www.quantware.ups-tlse.fr/chirikov/publclass.html. |
| [2] | Chirikov, B. V., A universal instability of many-dimensional oscillator systems, Phys. Rep., 52, 263 (1979) |
| [3] | Meiss, J. D., Symplectic maps, variational principles and transport, Rev. Modern Phys., 64, 795 (1992) · Zbl 1160.37302 |
| [4] | Shevchenko, I. I., The dynamical temperature and the standard map, Physica A, 386, 85 (2007) |
| [5] | Miguel, N.; Simó, C.; Vieiro, A., On the effect of islands in the diffusive properties of the standard map, for large parameter values, Found. Comput. Math., 15, 89 (2014) · Zbl 1376.37017 |
| [6] | Manos, T.; Robnik, M., Survey on the role of accelerator modes for anomalous diffusion: The case of the standard map, Phys. Rev. E, 89, Article 022905 pp. (2014) |
| [7] | Harsoula, M.; Contopoulos, G., Global and local diffusion in the standard map, Phys. Rev. E, 97, Article 022215 pp. (2018) |
| [8] | Cincotta, P. M.; Shevchenko, I. I., Correlations in area preserving maps: a Shannon entropy approach, Physica D, Article 132235 pp. (2020) · Zbl 1453.37007 |
| [9] | Gómez, G.; Mondelo, J. M.; Simó, C., A collocation method for the numerical fourier analysis of quasi-periodic functions, I: Numerical test and examples, Discrete Contin. Dyn. Syst. B, 14, 41 (2010) · Zbl 1237.37057 |
| [10] | Cincotta, P. M.; Giordano, C. M.; Simó, C., Phase space structure of multi-dimensional systems by means of the mean exponential growth factor of nearby orbits, Physica D, 182, 151-178 (2003) · Zbl 1032.37042 |
| [11] | Cincotta, P. M.; Giordano, C. M., Theory and applications of the mean exponential growth factor of nearby orbits (MEGNO) method, Lect. Notes Phys., 915, 93 (2016) |
| [12] | Guzzo, M.; Lega, E.; Froeschlé, C., A numerical study of arnold diffusion in a priori unstable systems, Comm. Math. Phys., 290, 557 (2009) · Zbl 1185.37143 |
| [13] | Arnold, V. I., On the nonstability of dynamical systems with many degrees of freedom, (Soviet Mathematical Doklady 5 (1964)), 581-585 · Zbl 0135.42602 |
| [14] | Ketoja, J. A.; MacKay, R. S., Fractal boundary for the existence of invariant circles for area-preserving maps: observations and renormalisation explanation, Physica D, 35, 318 (1989) · Zbl 0696.58032 |
| [15] | Ketoja, J. A.; MacKay, R. S., Rotationally-ordered periodic orbits for multiharmonic area-preserving twist maps, Physica D, 73, 388 (1994) · Zbl 0814.58012 |
| [16] | Fox, A.; Meiss, J. D., Critical invariant circles in asymmetric and multiharmonic generalized standard maps, Commun. Non-linear Sci. Numer. Simul., 19, 1004 (2014) · Zbl 1457.37058 |
| [17] | Martínez, R.; Simó, C., Return maps dynamical consequences and applications, Qual. Theory Dyn. Syst., 14, 353 (2015) · Zbl 1350.37068 |
| [18] | Giorgilli, A.; Lazutkin, V. F., Some remarks on the problem of ergodicity of the standard map, Phys. Lett. A, 272, 359 (2000) · Zbl 1115.37330 |
| [19] | Shevchenko, I. I., Isentropic perturbations of a chaotic domain, Phys. Lett. A, 333, 408 (2004) · Zbl 1123.37310 |
| [20] | Gradshteyn, I. S.; Ryzhik, I. M., (Table of Integrals, Series, and Products (2007), Elsevier/Academic Press: Elsevier/Academic Press Amsterdam) · Zbl 1208.65001 |
| [21] | Cincotta, P. M.; Giordano, C. M., Phase correlations in chaotic dynamics: a Shannon entropy measure, Celestial Mech. Dynam. Astronom., 130, 74 (2018) · Zbl 1448.70055 |
| [22] | Shannon, C.; Weaver, W., The Mathematical Theory of Communication (1949), Illinois U.P: Illinois U.P Urbana · Zbl 0041.25804 |
| [23] | Lesne, A., Shannon entropy: a rigorous notion at the crossroads between probability, information theory, dynamical systems and statistical physics, Math. Struct. Comput. Sci., 24, Article e240311 pp. (2014) · Zbl 1342.94059 |
| [24] | Arnol’d, V.; Avez, A., Ergodic Problems of Classical Mechanics (1989), Addison-Wesley: Addison-Wesley New York · Zbl 0167.22901 |
| [25] | Cincotta, P. M.; Simó, C., Conditional entropy, Celestial Mech. Dynam. Astronom., 73, 195 (1999) · Zbl 0968.70013 |
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