通过折叠奇异性打破耦合同源伦盖尔-爱泼斯坦振荡器中的强对称性

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-04-11 DOI:10.1007/s00332-024-10033-7
Naziru M. Awal, Irving R. Epstein, Tasso J. Kaper, Theodore Vo
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引用次数: 0

摘要

我们研究了一对对称耦合、完全相同的伦盖尔-爱泼斯坦振荡器,耦合可以通过快变量和慢变量进行。我们发现了大量强对称性破缺节奏,在这些节奏中,两个振荡器表现出质地不同的振荡,其振幅相差多达一个数量级。对耦合系统中折叠奇点的分析表明,位于对称轴外的一个关键折叠节点是造成强对称破缺的主要机制。穿过这个折叠节点附近会导致振荡器振幅分裂,其中一个振荡器受限于保持小振幅,而另一个振荡器则产生大振幅振荡或混合模式振荡。分析还揭示了参数空间中的一个组织中心,在该中心,系统发生了非对称卡瓦爆炸,其中一个振荡器在以爆炸点为中心的参数值区间内表现出一系列极限循环卡瓦,而另一个振荡器则进行小振幅振荡。其他折叠奇点也会影响强对称破缺节奏的特性。我们将这些强对称破缺节律与接近对称状态的不对称节律(如同相或反相振荡)进行对比。除了对称性破缺节律,我们还发现了反相极限周期的爆发,它介导了从小振幅反相振荡到大振幅反相振荡的过渡。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Strong Symmetry Breaking in Coupled, Identical Lengyel–Epstein Oscillators via Folded Singularities

We study pairs of symmetrically coupled, identical Lengyel-Epstein oscillators, where the coupling can be through both the fast and slow variables. We find a plethora of strong symmetry breaking rhythms, in which the two oscillators exhibit qualitatively different oscillations, and their amplitudes differ by as much as an order of magnitude. Analysis of the folded singularities in the coupled system shows that a key folded node, located off the symmetry axis, is the primary mechanism responsible for the strong symmetry breaking. Passage through the neighborhood of this folded node can result in splitting between the amplitudes of the oscillators, in which one is constrained to remain of small amplitude, while the other makes a large-amplitude oscillation or a mixed-mode oscillation. The analysis also reveals an organizing center in parameter space, where the system undergoes an asymmetric canard explosion, in which one oscillator exhibits a sequence of limit cycle canards, over an interval of parameter values centered at the explosion point, while the other oscillator executes small amplitude oscillations. Other folded singularities can also impact properties of the strong symmetry breaking rhythms. We contrast these strong symmetry breaking rhythms with asymmetric rhythms that are close to symmetric states, such as in-phase or anti-phase oscillations. In addition to the symmetry breaking rhythms, we also find an explosion of anti-phase limit cycle canards, which mediates the transition from small-amplitude, anti-phase oscillations to large-amplitude, anti-phase oscillations.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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