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Analogy between electrochemical oscillations and quantum physical processes
In (photo) electrochemical oscillations, the discretization of phase oscillators leads to a sequence of time dependent oscillator density functions which describe the passing of the oscillators through their minimum at each cycle. Two consecutive oscillator density functions are connected by a Marko...
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| Published in: | Journal of physics. Conference series 2014-01, Vol.490 (1), p.12119-4, Article 012119 |
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| Main Authors: | , |
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| container_title | Journal of physics. Conference series |
| container_volume | 490 |
| creator | Grzanna, J Lewerenz, H J |
| description | In (photo) electrochemical oscillations, the discretization of phase oscillators leads to a sequence of time dependent oscillator density functions which describe the passing of the oscillators through their minimum at each cycle. Two consecutive oscillator density functions are connected by a Markov process represented by a linear integral equation of second order which is homogeneous in the case of sustained oscillations. The kernel of the integral equation is a normalized Greens Function and represents the probability density for the periods of the oscillators. Both together, the oscillator density function and the two-dimensional probability density for the periods of the oscillators define a random walk. The relation of the model to the holographic principle is discussed briefly. Further, a detailed analysis of a kernel of the integral equation leads to a frequency distribution g for the period length. Additionally, it is possible to determine the energy E in dependence on the period length from the electrochemical process. The product g E shows qualitatively the same behaviour as the radiation of a black body, indicating that the discretization of phase oscillators, when represented by phase space analysis, show an analogy to quantum processes. |
| doi_str_mv | 10.1088/1742-6596/490/1/012119 |
| format | article |
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Two consecutive oscillator density functions are connected by a Markov process represented by a linear integral equation of second order which is homogeneous in the case of sustained oscillations. The kernel of the integral equation is a normalized Greens Function and represents the probability density for the periods of the oscillators. Both together, the oscillator density function and the two-dimensional probability density for the periods of the oscillators define a random walk. The relation of the model to the holographic principle is discussed briefly. Further, a detailed analysis of a kernel of the integral equation leads to a frequency distribution g for the period length. Additionally, it is possible to determine the energy E in dependence on the period length from the electrochemical process. 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| subjects | Analogies Black body radiation Density Discretization Frequency distribution Green's functions Integral equations Kernels Markov processes Mathematical models Oscillations Oscillators Physics Random walk |
| title | Analogy between electrochemical oscillations and quantum physical processes |
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