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Research Paper#Physics, Quark-Gluon Plasma, Gravitational Waves🔬 ResearchAnalyzed: Jan 3, 2026 08:48

Non-perturbative Thermodynamics of Quark-Gluon Plasma and Gravitational Waves

Published:Dec 31, 2025 07:51
1 min read
ArXiv

Analysis

This paper investigates the Quark-Gluon Plasma (QGP), a state of matter in the early universe, using non-linear classical background fields (SU(2) Yang-Mills condensates). It explores quark behavior in gluon backgrounds, calculates the thermodynamic pressure, compares continuum and lattice calculations, and analyzes the impact of gravitational waves on the QGP. The research aims to understand the non-perturbative aspects of QGP and its interaction with gravitational waves, contributing to our understanding of the early universe.
Reference

The resulting thermodynamic pressure increases with temperature but exhibits an approximately logarithmic dependence.

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Research Paper#Condensed Matter Physics, Nonlinear Dynamics🔬 ResearchAnalyzed: Jan 3, 2026 18:37

Emergent AC Effect in Coupled Nonreciprocal Condensates

Published:Dec 29, 2025 16:48
1 min read
ArXiv

Analysis

This paper explores a novel phenomenon in coupled condensates, where an AC Josephson-like effect emerges without an external bias. The research is significant because it reveals new dynamical phases driven by nonreciprocity and nonlinearity, going beyond existing frameworks like Kuramoto. The discovery of a bias-free, autonomous oscillatory current is particularly noteworthy, potentially opening new avenues for applications in condensate platforms.
Reference

The paper identifies an ac phase characterized by the emergence of two distinct frequencies, which spontaneously break the time-translation symmetry.

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Research Paper#Phase Transitions, Entropy, Complex Systems🔬 ResearchAnalyzed: Jan 3, 2026 19:15

Eigen Microstate Entropy Predicts Phase Transitions

Published:Dec 28, 2025 21:28
1 min read
ArXiv

Analysis

This paper introduces a new metric, eigen microstate entropy ($S_{EM}$), to detect and interpret phase transitions, particularly in non-equilibrium systems. The key contribution is the demonstration that $S_{EM}$ can provide early warning signals for phase transitions, as shown in both biological and climate systems. This has significant implications for understanding and predicting complex phenomena.
Reference

A significant increase in $S_{EM}$ precedes major phase transitions, observed before biomolecular condensate formation and El Niño events.

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Research Paper#Condensed Matter Physics, Spintronics🔬 ResearchAnalyzed: Jan 3, 2026 16:32

Ferroelectricity in Magnon Bose-Einstein Condensate

Published:Dec 26, 2025 16:12
1 min read
ArXiv

Analysis

This paper explores a novel ferroelectric transition in a magnon Bose-Einstein condensate, driven by its interaction with an electric field. The key finding is the emergence of non-reciprocal superfluidity, exceptional points, and a bosonic analog of Majorana fermions. This work could have implications for spintronics and quantum information processing by providing a new platform for manipulating magnons and exploring exotic quantum phenomena.
Reference

The paper shows that the feedback drives a spontaneous ferroelectric transition in the magnon superfluid, accompanied by a persistent magnon supercurrent.

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Research#physics🔬 ResearchAnalyzed: Jan 4, 2026 10:35

Acoustic Black Holes in a Shock-Wave Exciton-Polariton Condensate

Published:Dec 26, 2025 10:10
1 min read
ArXiv

Analysis

This article, sourced from ArXiv, likely presents research on the creation and study of acoustic black holes using exciton-polariton condensates. The focus is on the interaction of shock waves within this system, potentially exploring phenomena related to black hole physics in a condensed matter context. The use of ArXiv suggests a peer-review process is pending or has not yet occurred, so the findings should be considered preliminary.

Key Takeaways

    Reference

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    Research Paper#Quantum Physics, Condensed Matter Physics🔬 ResearchAnalyzed: Jan 4, 2026 00:00

    Quantum Breakdown Condensate: A Disorder-Free Quantum Glass

    Published:Dec 26, 2025 03:46
    1 min read
    ArXiv

    Analysis

    This paper introduces a novel phase of matter, the quantum breakdown condensate, which behaves like a disorder-free quantum glass. It's significant because it challenges existing classifications of phases and presents a new perspective on quantum systems with spontaneous symmetry breaking. The use of exact diagonalization and analysis of the model's properties, including its edge modes, order parameter, and autocorrelations, provides strong evidence for this new phase. The finding of a finite entropy density and a first-order phase transition is particularly noteworthy.
    Reference

    The condensate has an SSB order parameter being the local in-plane spin, which points in angles related by the chaotic Bernoulli (dyadic) map and thus is effectively random.

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    Research#Solitons🔬 ResearchAnalyzed: Jan 10, 2026 07:58

    Perturbation Theory Advances for Dark Solitons in Nonlinear Schrödinger Equation

    Published:Dec 23, 2025 18:30
    1 min read
    ArXiv

    Analysis

    This research explores integrable perturbation theory, a complex mathematical framework, within the context of the defocusing nonlinear Schrödinger equation and its dark solitons. The findings likely contribute to a deeper understanding of wave phenomena and could have implications in fields like fiber optics and Bose-Einstein condensates.
    Reference

    The article's context focuses on the application of integrable perturbation theory to the defocusing nonlinear Schrödinger equation.

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    Research#physics🔬 ResearchAnalyzed: Jan 4, 2026 07:22

    Local Topological Constraints on Berry Curvature in Spin--Orbit Coupled BECs

    Published:Dec 22, 2025 11:26
    1 min read
    ArXiv

    Analysis

    This article likely discusses the theoretical and/or experimental investigation of Berry curvature in Bose-Einstein condensates (BECs) with spin-orbit coupling. The focus is on how local topological constraints influence the behavior of this curvature. The research area is within condensed matter physics and quantum simulation.

    Key Takeaways

      Reference

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      Research#Dark Matter🔬 ResearchAnalyzed: Jan 10, 2026 08:48

      Exploring Dark Matter with Bose-Einstein Condensates: A Novel Approach

      Published:Dec 22, 2025 05:25
      1 min read
      ArXiv

      Analysis

      This article explores the use of Bose-Einstein condensates to model and understand dark matter, specifically incorporating logarithmic nonlinearity. The research presents a potentially innovative avenue for probing the nature of dark matter.
      Reference

      The context mentions Bose-Einstein Condensate dark matter with logarithmic nonlinearity.

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      Research#Quantum Physics🔬 ResearchAnalyzed: Jan 10, 2026 09:34

      Scattering Dynamics Explored in Bose-Einstein Condensates with Magnetic Domain Walls

      Published:Dec 19, 2025 13:47
      1 min read
      ArXiv

      Analysis

      This research explores a specific, complex phenomenon in quantum physics, contributing to a deeper understanding of matter under extreme conditions. The work provides valuable insights into the behavior of Bose-Einstein condensates, which has implications for advancements in quantum technologies.
      Reference

      The research focuses on the scattering problem within Bose-Einstein condensates.

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      Research#Physics🔬 ResearchAnalyzed: Jan 10, 2026 09:40

      Dynamical Chiral Condensate Evidence in Heavy Ion Collisions

      Published:Dec 19, 2025 10:07
      1 min read
      ArXiv

      Analysis

      This research explores the formation of a dynamical chiral condensate, a critical concept in understanding the strong force, within high-energy heavy ion collisions. The findings contribute to the ongoing study of quark-gluon plasma and the fundamental nature of matter.
      Reference

      Evidence for dynamical chiral condensate in high-energy heavy ion collisions

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      Research#DNA🔬 ResearchAnalyzed: Jan 10, 2026 10:10

      AI Predicts DNA Condensate Behavior

      Published:Dec 18, 2025 04:10
      1 min read
      ArXiv

      Analysis

      This research leverages AI to model complex biological systems, which is a promising direction for advancements in materials science. The study's focus on interfacial energy and morphology of DNA condensates could have significant implications for drug delivery and nanotechnology.
      Reference

      Predicting the Interfacial Energy and Morphology of DNA Condensates

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