Search:
Match:
3 results
Research#Mathematics/Computer Science (Markov Chains, Representation Theory)🔬 ResearchAnalyzed: Jan 4, 2026 06:49

Schur--Weyl duality for diagonalizing a Markov chain on the hypercube

Published:Dec 29, 2025 08:13
1 min read
ArXiv

Analysis

This article likely presents a novel application of Schur-Weyl duality, a concept from representation theory, to the analysis of Markov chains defined on hypercubes. The focus is on diagonalizing the Markov chain, which is a crucial step in understanding its long-term behavior and stationary distribution. The use of Schur-Weyl duality suggests a potentially elegant and efficient method for this diagonalization, leveraging the symmetries inherent in the hypercube structure. The ArXiv source indicates this is a pre-print, suggesting it's a recent research contribution.
Reference

The article's abstract would provide specific details on the methods used and the results obtained. Further investigation would be needed to understand the specific contributions and their significance.

PermalinkArXiv
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.

PermalinkArXiv
Research#llm🔬 ResearchAnalyzed: Jan 4, 2026 09:55

The Isogeometric Fast Fourier-based Diagonalization method

Published:Dec 23, 2025 11:24
1 min read
ArXiv

Analysis

This article likely presents a novel computational method. The title suggests a combination of isogeometric analysis (IGA) and Fast Fourier Transform (FFT) techniques for diagonalization, which is a common operation in numerical linear algebra and eigenvalue problems. The source, ArXiv, indicates this is a pre-print or research paper.
Reference

PermalinkArXiv