Your search keyword '"PHYSICAL laws"' showing total 14 results

1. Weak Scale Supersymmetry Emergent from the String Landscape.

Author

Baer, Howard, Barger, Vernon, Martinez, Dakotah, and Salam, Shadman

Subjects

*PHYSICAL laws, *COSMOLOGICAL constant, *SUPERSYMMETRY, *DISTRIBUTION (Probability theory), *MODELS & modelmaking, *STRING theory

Abstract

Superstring flux compactifications can stabilize all moduli while leading to an enormous number of vacua solutions, each leading to different 4 − d laws of physics. While the string landscape provides at present the only plausible explanation for the size of the cosmological constant, it may also predict the form of weak scale supersymmetry which is expected to emerge. Rather general arguments suggest a power-law draw to large soft terms, but these are subject to an anthropic selection of a not-too-large value for the weak scale. The combined selection allows one to compute relative probabilities for the emergence of supersymmetric models from the landscape. Models with weak scale naturalness appear most likely to emerge since they have the largest parameter space on the landscape. For finetuned models such as high-scale SUSY or split SUSY, the required weak scale finetuning shrinks their parameter space to tiny volumes, making them much less likely to appear compared to natural models. Probability distributions for sparticle and Higgs masses from natural models show a preference for Higgs mass m h ∼ 125 GeV, with sparticles typically beyond the present LHC limits, in accord with data. From these considerations, we briefly describe how natural SUSY is expected to be revealed at future LHC upgrades. This article is a contribution to the Special Edition of the journal Entropy, honoring Paul Frampton on his 80th birthday. [ABSTRACT FROM AUTHOR]

Published

2024

2. It Ain't Necessarily So: Ludwig Boltzmann's Darwinian Notion of Entropy.

Author

Gimbel, Steven

Subjects

*SECOND law of thermodynamics, *HISTORY of physics, *PHYSICAL laws, *TOPOLOGICAL entropy

Abstract

Ludwig Boltzmann's move in his seminal paper of 1877, introducing a statistical understanding of entropy, was a watershed moment in the history of physics. The work not only introduced quantization and provided a new understanding of entropy, it challenged the understanding of what a law of nature could be. Traditionally, nomological necessity, that is, specifying the way in which a system must develop, was considered an essential element of proposed physical laws. Yet, here was a new understanding of the Second Law of Thermodynamics that no longer possessed this property. While it was a new direction in physics, in other important scientific discourses of that time—specifically Huttonian geology and Darwinian evolution, similar approaches were taken in which a system's development followed principles, but did so in a way that both provided a direction of time and allowed for non-deterministic, though rule-based, time evolution. Boltzmann referred to both of these theories, especially the work of Darwin, frequently. The possibility that Darwin influenced Boltzmann's thought in physics can be seen as being supported by Boltzmann's later writings. [ABSTRACT FROM AUTHOR]

Published

2024

3. Small and Simple Systems That Favor the Arrow of Time.

Author

Chamberlin, Ralph V.

Subjects

*PHYSICAL laws, *THERMAL equilibrium, *NONEQUILIBRIUM thermodynamics, *SECOND law of thermodynamics, *RING theory, *ENTROPY

Abstract

The 2nd law of thermodynamics yields an irreversible increase in entropy until thermal equilibrium is achieved. This irreversible increase is often assumed to require large and complex systems to emerge from the reversible microscopic laws of physics. We test this assumption using simulations and theory of a 1D ring of N Ising spins coupled to an explicit heat bath of N Einstein oscillators. The simplicity of this system allows the exact entropy to be calculated for the spins and the heat bath for any N , with dynamics that is readily altered from reversible to irreversible. We find thermal-equilibrium behavior in the thermodynamic limit, and in systems as small as N = 2 , but both results require microscopic dynamics that is intrinsically irreversible. [ABSTRACT FROM AUTHOR]

Published

2024

4. Introduction for the Special Issue: Statistical Fluid Dynamics.

Author

Ammar, Amine, Chinesta, Francisco, and Valette, Rudy

Subjects

*FLUID dynamics, *PHYSICAL laws, *STRUCTURAL mechanics, *PROPERTIES of matter, *STATISTICS

Published

2022

5. Equilibration and "Thermalization" in the Adapted Caldeira–Leggett Model.

Author

Albrecht, Andreas

Subjects

*DECOHERENCE (Quantum mechanics), *PHYSICAL laws, *EMPLOYEE motivation, *QUANTUM entanglement

Abstract

I explore the processes of equilibration exhibited by the Adapted Caldeira–Leggett (ACL) model, a small unitary "toy model" developed for numerical studies of quantum decoherence between an SHO and an environment. I demonstrate how dephasing allows equilibration to occur in a wide variety of situations. While the finite model size and other "unphysical" aspects prevent the notions of temperature and thermalization from being generally applicable, certain primitive aspects of thermalization can be realized for particular parameter values. I link the observed behaviors to intrinsic properties of the global energy eigenstates, and argue that the phenomena I observe contain elements which might be key ingredients that lead to ergodic behavior in larger more realistic systems. The motivations for this work range from curiosity about phenomena observed in earlier calculations with the ACL model to much larger questions related to the nature of equilibrium, thermalization, and the emergence of physical laws. [ABSTRACT FROM AUTHOR]

Published

2022

6. The Second Law, Asymmetry of Time and Their Implications.

Author

Klimenko, Alexander Y.

Subjects

*PHYSICAL laws, *SECOND law of thermodynamics

Abstract

33297594 5 Coretti A., Rondoni L., Bonella S. Fluctuation Relations for Dissipative Systems in Constant External Magnetic Field: Theory and Molecular Dynamics Simulations. The fluctuation theorem demonstrates that, in the presence of antecedent causality, reversible microscopic dynamics such as Newtonian dynamics or quantum dynamics lead to asymmetric distributions of the values of fluxes in the system if it is out of equilibrium. Explaining the asymmetry of the directions of time (the time arrow) is one of the major challenges for modern science. [Extracted from the article]

Published

2022

7. Thermodynamic Analysis for Buoyancy-Induced Couple Stress Nanofluid Flow with Constant Heat Flux.

Author

Adesanya, Samuel O., Ogunseye, Hammed A., Falade, J. A., and Lebelo, R. S.

Subjects

*THERMODYNAMICS, *NANOFLUIDS, *HEAT flux, *HOMOTOPY theory, *FLUID velocity measurements, *PHYSICAL laws

Abstract

This paper addresses entropy generation in the flow of an electrically-conducting couple stress nanofluid through a vertical porous channel subjected to constant heat flux. By using the Buongiorno model, equations for momentum, energy, and nanofluid concentration are modelled, solved using homotopy analysis and furthermore, solved numerically. The variations of significant fluid parameters with respect to fluid velocity, temperature, nanofluid concentration, entropy generation, and irreversibility ratio are investigated, presented graphically, and discussed based on physical laws. [ABSTRACT FROM AUTHOR]

Published

2017

8. Invalid Microstate Densities for Model Systems Lead to Apparent Violation of Thermodynamic Law.

Author

Michaelian, Karo and Santamaría-Holek, Ivan

Subjects

*PHYSICAL laws, *THERMODYNAMICS, *STATISTICAL mechanics, *THERMODYNAMIC laws, *MICROSTATES (Statistical mechanics)

Abstract

It is often incorrectly assumed that the number of microstates … (E,V, N, … ) available to an isolated system can have arbitrary dependence on the extensive variables E,V, N, … However, this is not the case for systems which can, in principle, reach thermodynamic equilibrium since restrictions arise from the underlying equilibrium statistical mechanic axioms of independence and a priori equal probability of microstates. Here we derive a concise criterion specifying the condition on W which must be met in order for a system to be able, in principle, to reach thermodynamic equilibrium. Natural quantum systems obey this criterion and therefore can, in principle, reach thermodynamic equilibrium. However, models which do not respect this criterion will present inconsistencies when treated under equilibrium thermodynamic formalism. This has relevance to a number of recent models in which negative heat capacity and other violations of fundamental thermodynamic law have been reported. [ABSTRACT FROM AUTHOR]

Published

2017

9. Life's a Gas: A Thermodynamic Theory of Biological Evolution.

Author

Skene, Keith R.

Subjects

*THERMODYNAMICS, *BIOLOGICAL evolution, *PHYSICAL laws, *BIODIVERSITY, *MAXIMUM entropy method, *NATURAL selection

Abstract

This paper outlines a thermodynamic theory of biological evolution. Beginning with a brief summary of the parallel histories of the modern evolutionary synthesis and thermodynamics, we use four physical laws and processes (the first and second laws of thermodynamics, diffusion and the maximum entropy production principle) to frame the theory. Given that open systems such as ecosystems will move towards maximizing dispersal of energy, we expect biological diversity to increase towards a level, Dmax, representing maximum entropic production (Smax). Based on this theory, we develop a mathematical model to predict diversity over the last 500 million years. This model combines diversification, post-extinction recovery and likelihood of discovery of the fossil record. We compare the output of this model with that of the observed fossil record. The model predicts that life diffuses into available energetic space (ecospace) towards a dynamic equilibrium, driven by increasing entropy within the genetic material. This dynamic equilibrium is punctured by extinction events, which are followed by restoration of Dmax through diffusion into available ecospace. Finally we compare and contrast our thermodynamic theory with the MES in relation to a number of important characteristics of evolution (progress, evolutionary tempo, form versus function, biosphere architecture, competition and fitness). [ABSTRACT FROM AUTHOR]

Published

2015

10. Entropy, Information and Complexity or Which Aims the Arrow of Time?

Author

Mikhailovsky, George E. and Levich, Alexander P.

Subjects

*ENTROPY, *COMPLEXITY (Philosophy), *THERMODYNAMICS, *CATEGORIES (Mathematics), *PHYSICAL laws

Abstract

In this article, we analyze the interrelationships among such notions as entropy, information, complexity, order and chaos and show using the theory of categories how to generalize the second law of thermodynamics as a law of increasing generalized entropy or a general law of complification. This law could be applied to any system with morphisms, including all of our universe and its subsystems. We discuss how such a general law and other laws of nature drive the evolution of the universe, including physicochemical and biological evolutions. In addition, we determine eliminating selection in physicochemical evolution as an extremely simplified prototype of natural selection. Laws of nature do not allow complexity and entropy to reach maximal values by generating structures. One could consider them as a kind of "breeder" of such selection. [ABSTRACT FROM AUTHOR]

Published

2015

11. Recent Progresses in Characterising Information Inequalities.

Author

Chan, Terence

Subjects

*MATHEMATICAL inequalities, *KOLMOGOROV complexity, *ENTROPY, *MACHINE theory, *PHYSICAL laws, *ELECTRONIC data processing

Abstract

In this paper, we present a revision on some of the recent progresses made in characterising and understanding information inequalities, which are the fundamental physical laws in communications and compression. We will begin with the introduction of a geometric framework for information inequalities, followed by the first non-Shannon inequality proved by Zhang et al. in 1998 [1]. The discovery of this non-Shannon inequality is a breakthrough in the area and has led to the subsequent discovery of many more non-Shannon inequalities. We will also review the close relations between information inequalities and other research areas such as Kolmogorov complexity, determinantal inequalities, and group-theoretic inequalities. These relations have led to non-traditional techniques in proving information inequalities and at the same time made impacts back on those related areas by the introduction of information-theoretic tools. [ABSTRACT FROM AUTHOR]

Published

2011

12. Causality in Discrete Time Physics Derived from Maupertuis Reduced Action Principle.

Author

Riek, Roland and Chatterjee, Atanu

Subjects

*PHYSICAL laws, *PHYSICS, *CAUSATION (Philosophy)

Abstract

Causality describes the process and consequences from an action: a cause has an effect. Causality is preserved in classical physics as well as in special and general theories of relativity. Surprisingly, causality as a relationship between the cause and its effect is in neither of these theories considered a law or a principle. Its existence in physics has even been challenged by prominent opponents in part due to the time symmetric nature of the physical laws. With the use of the reduced action and the least action principle of Maupertuis along with a discrete dynamical time physics yielding an arrow of time, causality is defined as the partial spatial derivative of the reduced action and as such is position- and momentum-dependent and requests the presence of space. With this definition the system evolves from one step to the next without the need of time, while (discrete) time can be reconstructed. [ABSTRACT FROM AUTHOR]

Published

2021

13. Geometrical Optics Restricted Eavesdropping Analysis of Satellite-to-Satellite Secret Key Distillation.

Author

Pan, Ziwen and Djordjevic, Ivan B.

Subjects

*GEOMETRICAL optics, *EAVESDROPPING, *DISTILLATION, *PHYSICAL laws

Abstract

Traditionally, the study of quantum key distribution (QKD) assumes an omnipotent eavesdropper that is only limited by the laws of physics. However, this is not the case for specific application scenarios such as the QKD over a free-space link. In this invited paper, we introduce the geometrical optics restricted eavesdropping model for secret key distillation security analysis and apply to a few scenarios common in satellite-to-satellite applications. [ABSTRACT FROM AUTHOR]

Published

2021

14. The Meta-Dynamic Nature of Consciousness.

Author

Barnden, John A.

Subjects

*CONSCIOUSNESS, *PHYSICAL laws, *NATURE

Abstract

How, if at all, consciousness can be part of the physical universe remains a baffling problem. This article outlines a new, developing philosophical theory of how it could do so, and offers a preliminary mathematical formulation of a physical grounding for key aspects of the theory. Because the philosophical side has radical elements, so does the physical-theory side. The philosophical side is radical, first, in proposing that the productivity or dynamism in the universe that many believe to be responsible for its systematic regularities is actually itself a physical constituent of the universe, along with more familiar entities. Indeed, it proposes that instances of dynamism can themselves take part in physical interactions with other entities, this interaction then being "meta-dynamism" (a type of meta-causation). Secondly, the theory is radical, and unique, in arguing that consciousness is necessarily partly constituted of meta-dynamic auto-sensitivity, in other words it must react via meta-dynamism to its own dynamism, and also in conjecturing that some specific form of this sensitivity is sufficient for and indeed constitutive of consciousness. The article proposes a way for physical laws to be modified to accommodate meta-dynamism, via the radical step of including elements that explicitly refer to dynamism itself. Additionally, laws become, explicitly, temporally non-local in referring directly to quantity values holding at times prior to a given instant of application of the law. The approach therefore implicitly brings in considerations about what information determines states. Because of the temporal non-locality, and also because of the deep connections between dynamism and time-flow, the approach also implicitly connects to the topic of entropy insofar as this is related to time. [ABSTRACT FROM AUTHOR]

Published

2020