论文信息 - Information and Statistical Measures in Classical vs. Quantum Condensed-Matter and Related Systems

Information and Statistical Measures in Classical vs. Quantum Condensed-Matter and Related Systems

The presented editorial summarizes in brief the efforts of ten (10) papers collected by the Special Issue (SI) “Condensed-Matter-Principia Based Information & Statistical Measures: From Classical to Quantum”. The SI called for papers dealing with condensed-matter systems, or their interdisciplinary analogs, for which well-defined classical statistical vs. quantum information measures can be inferred while based on the entropy concept. The SI has mainly been rested upon objectives addressed by an international colloquium held in October 2019, at the University of Science and Technology (UTP) Bydgoszcz, Poland (see http://zmpf.imif.utp.edu.pl/rci-jcs/rci-jcs-4/), with an emphasis placed on the achievements of Professor Gerard Czajkowski (PGC). PGC commenced his research activity with diffusion-reaction (open) systems under the supervision of Roman S. Ingarden (Toruń), a father of Polish synergetics, and original thermodynamic approaches to self-organization. The active cooperation of PGC mainly with German physicists (Friedrich Schloegl, Aachen; Werner Ebeling, Berlin) ought to be underlined. Then, the development of Czajkowski’s research is worth underscoring, moving from statistical thermodynamics to solid state theory, pursued in terms of nonlinear solid-state optics (Franco Bassani, Pisa), and culminating very recently with large quasiparticles, termed Rydberg excitons, and their coherent interactions with light.

Adam Gadomski | Sylwia Zielinska-Raczynska

[1] Adam Gadomski,et al. Changes of Conformation in Albumin with Temperature by Molecular Dynamics Simulations , 2020, Entropy.

[2] David Ziemkiewicz,et al. Electromagnetically Induced Transparency in Media with Rydberg Excitons 2: Cross-Kerr Modulation , 2020, Entropy.

[3] Nikolay K. Vitanov,et al. Statistical Characteristics of Stationary Flow of Substance in a Network Channel Containing Arbitrary Number of Arms , 2020, Entropy.

[4] Jerzy Dajka,et al. Binary Communication with Gazeau–Klauder Coherent States , 2020, Entropy.

[5] Piotr Cofta,et al. Cross-Entropy as a Metric for the Robustness of Drone Swarms , 2020, Entropy.

[6] Jerzy Gorecki,et al. Applications of Information Theory Methods for Evolutionary Optimization of Chemical Computers , 2020, Entropy.

[7] David Ziemkiewicz,et al. Electromagnetically Induced Transparency in Media with Rydberg Excitons 1: Slow Light , 2020, Entropy.

[8] Arieh Ben-Naim,et al. Entropy and Information Theory: Uses and Misuses , 2019, Entropy.

[9] David Ziemkiewicz,et al. Fractal Plasmons on Cantor Set Thin Film , 2019, Entropy.

[10] Miriam Kosik,et al. Interaction and Entanglement of a Pair of Quantum Emitters near a Nanoparticle: Analysis beyond Electric-Dipole Approximation , 2020, Entropy.