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Random-walk shielding-potential viscosity model for warm dense metals

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 Added by Yuqing Cheng
 Publication date 2021
  fields Physics
and research's language is English




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The collective effect on the viscosity is essential for warm dense metals. The statistics of random-walk ions and the Debye shielding effect describing the collective properties are introduced in the random-walk shielding-potential viscosity model (RWSP-VM). As a test, the viscosities of several metals (Be, Al, Fe and U) are obtained, which cover from low-Z to high-Z elements. The results indicate that RWSP-VM is a universal accurate and highly efficient model for calculating the viscosity of metals in warm dense state.



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71 - F. Le Vot , E. Abad , S. B. Yuste 2017
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305 - Liubov Tupikina 2020
Continuous time random Walk model has been versatile analytical formalism for studying and modeling diffusion processes in heterogeneous structures, such as disordered or porous media. We are studying the continuous limits of Heterogeneous Continuous Time Random Walk model, when a random walk is making jumps on a graph within different time-length. We apply the concept of a generalized master equation to study heterogeneous continuous-time random walks on networks. Depending on the interpretations of the waiting time distributions the generalized master equation gives different forms of continuous equations.
334 - A.V. Plyukhin 2009
In a simple model of a continuous random walk a particle moves in one dimension with the velocity fluctuating between V and -V. If V is associated with the thermal velocity of a Brownian particle and allowed to be position dependent, the model accounts readily for the particles drift along the temperature gradient and recovers basic results of the conventional thermophoresis theory.
85 - Miquel Montero 2019
The random walk with hyperbolic probabilities that we are introducing is an example of stochastic diffusion in a one-dimensional heterogeneous media. Although driven by site-dependent one-step transition probabilities, the process retains some of the features of a simple random walk, shows other traits that one would associate with a biased random walk and, at the same time, presents new properties not related with either of them. In particular, we show how the system is not fully ergodic, as not every statistic can be estimated from a single realization of the process. We further give a geometric interpretation for the origin of these irregular transition probabilities.
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