IV. Ecosmomics: Independent Complex Network Systems, Computational Programs, Genetic Ecode Scripts

A. A Procreative Ecode: An Ecosmome to Geonome Complementary Hereditary Endowment

Zhou, Zheng, et al. Fractal Quantum Phase Transitions: Critical Phenomena Beyond Renormalization. arXiv:2105.05851. We note this entry by Fudan University, Chongqing University, Technical University of Munich and Princeton University physicists as they proceed to find one more instance of nature’s dynamic preference even way down in this long arcane, foundational realm.

Quantum critical points connecting different phases have broad implications in modern many-body physics. Their universal features are determined using the renormalization group (RG) theory, since salient properties at the phase transition point can be discerned by coarse-graining the local fluctuations and focusing on the physics at the long wavelength limit. Based on this observation, a wide class of universal phenomena can be revealed by symmetry, locality, and dimensionality. Here we investigate a special type fractal symmetry. (1)

Zhu, Hao-Fu, et al. Rapid cooling of the Cassiopeia A neutron star due to superfluid quantum criticality. arXiv:2410.21945.. As one present example of the wide and deep instrumental and theoretic compass of Earthuman scientific acumen, University of Science and Technology of China, Hefei astrophysicists describe their discoveries of this preferred critical behavior even across quantum cosmological realms.

The rapid cooling of the neutron star in Cassiopeia A is speculated to arise from a neutrino emission due to the onset of 3P2-wave neutron superfluidity in the core. Here, we show that such phenomena can be explained once the non-Fermi liquid behavior induced by superfluid quantum criticality is included into the theoretical description. The good agreement between our results and observational cooling data implicates the pivotal role played by the these nonlinear dynamics even in such quantum cosmological realms. (Abstract)

Zimatore, Giovanna, et al. Self-organization of Whole-Gene Expression through Coordinated Chromatin Structural Transition. Biophysics Reviews. September, 2021. Five geneticists posted in Italy, Japan, and Poland including Masa Tsuchiya provide still another, significant genomic example of nature’s persistence to reach and reside at an optimum reciprocal poise.

The human DNA molecule is a long polymer collapsed into the micrometer space of the cell nucleus. This simple consideration leads to gene-by-gene regulation which better contrasts with the physical reality in the presence of cell state transitions that involvef thousands of genes. This state of affairs invites a statistical mechanics approach where specificity arises from a selective unfolding of chromatin driving the rewiring of gene expression patterns. The arising of “expression waves” marking state transitions can be related to chromatin reorganization through self-organized critical control of whole-genome. (Excerpt)

Zimmern, Vincent. Why Brain Criticality is Clinically Revelant. Frontiers in Neural Circuits. August, 2020. A UT Southwestern Medical Center child neurologist provides an actual survey of the palliative implications of this by now accepted, phenomenal condition whence our brains seek and become poised at this optimum dynamic state.

The past 25 years have seen increased number of publications related to criticality in neuroscience. But recent writings on this topic make brief mention of clinical applications to such disorders as epilepsy, neurodegenerative disease, neonatal hypoxia, along with sleep issues and developmental-behavioral pediatrics. In this scoping review, studies of brain criticality involving human data of all ages are evaluated for their clinical relevance. In regard, the prime concepts behind criticality (e.g., phase transitions, long-range temporal correlation, self-organized criticality, power laws, branching processes) will precede their neurological occasion. (Excerpt)

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