Science – Page 141

Inside Neutron Stars: A New Model for Ultra-Dense Matter

19.12.2025 by pricpr

$The research delineates phase transitions within a relativistic quantum field theory-the RG-consistent NJL model-demonstrating how the interplay between chiral symmetry breaking and color superconductivity manifests in distinct phases-normal quark matter, two-flavor color superconductivity, and color-flavor locking-as revealed by variations in quark number fractions, $Y_u$, $Y_d$, and $Y_s$, and demarcated by first, second-order, and crossover transitions.$

Researchers have developed a refined theoretical framework to map the behavior of quark matter at the extreme temperatures and densities found within neutron stars.

Tick-Tock Goes the Universe: Atomic Clocks Tighten the Grip on Dark Energy

19.12.2025 by pricpr

New research leveraging ultra-precise atomic clocks and lunar laser ranging data significantly narrows the possibilities for explaining the accelerating expansion of the universe.

Beyond the Wave: Modeling Quantum Reality with ‘Dough’

19.12.2025 by pricpr

A new computational model reimagines quantum particles as deformable, extended entities, offering a physically intuitive explanation for phenomena like the double-slit experiment.

Designing Quantum Experiments with AI

19.12.2025 by pricpr

Aṇubuddhi employs a three-layered cognitive architecture-integrating large language model-based intent routing, retrieval-augmented generation via semantic search, and dual-mode simulation with convergent self-refinement-to process natural language requests and iteratively refine designs, ultimately enabling experience-based procedural learning through the reuse of validated building blocks.

A new AI system translates natural language into functional quantum optics experiment designs, paving the way for more accessible scientific exploration.

Decoding Quantum Work: A New Framework for Thermodynamic Fluctuations

19.12.2025 by pricpr

Researchers have developed a unified approach to understanding how energy changes at the quantum level, classifying the roles of entanglement, coherence, and system structure.

Beyond Quantum Weirdness: Games That Reveal Hidden Order

19.12.2025 by pricpr

$The study establishes an upper bound on the performance of strategies leveraging empirical models derived from quantum state measurements, contrasting it with the performance of the Pauli strategy, and demonstrates this limit across deformed GHZ states-subject to a nonunitary transformation $A(\theta) = e^{\theta Z}e^{2i\theta Y}$ and exhibiting a noncontextual fraction computed via linear programming-and deformed one-dimensional cluster states, revealing the inherent constraints on strategic advantage in quantum scenarios where $\omega = 3/4$ for the GHZ state and $\omega = 7/8$ for the cluster state.$

New research shows how multiplayer quantum games can be used to probe the fundamental properties of complex quantum states and verify their existence.

Quantum Jumps Reveal Entanglement’s Limits

19.12.2025 by pricpr

$For a system with $ \gamma/J = 0.1 $ and $ n = 0.4 $, the subsystem entropy scales according to a volume law when detection is inefficient-characterized by $ \delta\eta = 1 - \eta > 0 $-but aligns with expectations for a fully mixed, infinite-temperature state with fixed fermion density, as described by Eq. (131), as detection approaches perfect efficiency with $ \delta\eta = 1 $.$

A new theoretical framework analyzes the dynamics of quantum jumps, demonstrating a surprising absence of phase transitions and a link between detection efficiency and entanglement structure.

Beyond Bosons and Fermions: A New Calculus of Quantum Particles

19.12.2025 by pricpr

Researchers are expanding the foundations of quantum statistics, developing a framework to describe particles that go beyond the traditional bosonic and fermionic behaviors.

Quantum Connections: Achieving Perfect Entanglement with Fermions

19.12.2025 by pricpr

$Entanglement entropy, calculated between a measured portion and the remainder of a single layer subjected to uniform Bell measurements, demonstrates a linear relationship with system size-scaling as $S = \frac{L}{2}\log 2$-and also scales linearly with the number of measurements performed-$S = N_{\mathbf{m}}\log 2$-a behavior observed across various states, including the ground state of a critical Hamiltonian $H_{0}=-\frac{1}{2}\sum_{i}c_{i}^{\dagger}c_{i+1}^{\dagger}+h.c.$ with open boundary conditions, suggesting a fundamental connection between measurement extent and entanglement scaling in this system.$

A new study reveals a method for creating maximally entangled states between fermionic systems through simple measurements and post-selection, regardless of their initial configuration.

Entangled Time: A New View of Quantum Reality

19.12.2025 by pricpr

Local subsystems become entangled with a global clock, yet variations in spacetime geometry and relative motion modulate the rate of correlation, resulting in a distinct, observer-dependent flow of time that replicates relativistic time dilation within a quantum-relational framework.

A novel framework proposes that time isn’t a fundamental constant, but emerges from the quantum relationships between observers and the universe itself.