Javier Manuel MartĂ­n Alonso12h ago
Happy #WorldQuantumDay! 🌌
On April 20, Quantum Observables for Collider Physics 2026 opens at CERN, bringing entanglement, magic, and collider observables closer to the center of high-energy physics. Proud to contribute to this direction through the Theorem 4.3.1 framework. Time to move beyond correlations and start mapping quantum geometry. 🚀
🔗 doi.org https://doi.org/10.5281/zenodo.18207031
https://doi.org/10.5281/zenodo.18353640
https://doi.org/10.5281/zenodo.18764143
#QuantumAlgorithms #QuantumGravity #Physics #Entanglement #CERN #QFT
Topological Vortex Superradiance and TMST: A QCD Framework for Intrinsic Charm and Proton Structure Tests with Belle II at the Chiral Belle Polarization Upgrade

We develop a topological QCD framework in which color confinement, intrinsic charm and the proton’s partonic structure emerge from an entanglement–driven phase transition between a three–valence–quark regime and a gluon–dominated collective condensate. The central ingredient is the Two–Mode Squeezing Threshold (TMST), an entanglement–dominance threshold T_0 at which a collective vortex mode in color space becomes superradiantly amplified and stabilizes heavy quark–antiquark components (such as intrinsic charm) as quasi–topological excitations rather than rare perturbative fluctuations. This mechanism provides a first–principles, geometric explanation of intrinsic charm signals in global PDF analyses and of the gluon–cloud picture of the proton, unifying them with a topological vortex description of confinement and ER=EPR–type geometric channels. On the phenomenological side, we show how the TMST can be probed through two–particle correlation observables in high–luminosity e+e− collisions. In particular, we formulate an operational equation (Eq. 1, implemented in an open Python module) that relates an effective “entanglement temperature” T_obs derived from the log–negativity of the TMST state, to quantities extracted from two–particle correlation functions, dT_obs = (d dv) / (dv dT), providing a concrete handle to distinguish standard gluon radiation from topological vortex stabilization in heavy–flavor final states. The Chiral Belle / SuperKEKB electron–polarization upgrade and Belle II–style e+e− correlation measurements offer an especially clean environment to test this scenario, by searching for TMST–driven changes in spin– and flavor–sensitive observables associated with charm and exotic spectroscopy. The framework is formulated in a way that is directly implementable in basf2–type analysis chains and extensible to lattice QCD, global PDF fits and cold–atom analogs. Keywords QCD confinement intrinsic charm proton structure topological vortices Two–Mode Squeezing Threshold (TMST) entanglement dominance gluon condensate Belle II Chiral Belle polarization upgrade SuperKEKB e+e− correlations spin observables exotic hadron spectroscopy dark sector searches electroweak precision

Zenodo
Javier Manuel MartĂ­n AlonsoJan 31

Belle II correlations: TMST proxy testing.

DOI: https://doi.org/10.5281/zenodo.18207031

#BelleII #QFT

Topological Vortex Superradiance and TMST: A QCD Framework for Intrinsic Charm and Proton Structure Tests with Belle II at the Chiral Belle Polarization Upgrade

We develop a topological QCD framework in which color confinement, intrinsic charm and the proton’s partonic structure emerge from an entanglement–driven phase transition between a three–valence–quark regime and a gluon–dominated collective condensate. The central ingredient is the Two–Mode Squeezing Threshold (TMST), an entanglement–dominance threshold T_0 at which a collective vortex mode in color space becomes superradiantly amplified and stabilizes heavy quark–antiquark components (such as intrinsic charm) as quasi–topological excitations rather than rare perturbative fluctuations. This mechanism provides a first–principles, geometric explanation of intrinsic charm signals in global PDF analyses and of the gluon–cloud picture of the proton, unifying them with a topological vortex description of confinement and ER=EPR–type geometric channels. On the phenomenological side, we show how the TMST can be probed through two–particle correlation observables in high–luminosity e+e− collisions. In particular, we formulate an operational equation (Eq. 1, implemented in an open Python module) that relates an effective “entanglement temperature” T_obs derived from the log–negativity of the TMST state, to quantities extracted from two–particle correlation functions, dT_obs = (d dv) / (dv dT), providing a concrete handle to distinguish standard gluon radiation from topological vortex stabilization in heavy–flavor final states. The Chiral Belle / SuperKEKB electron–polarization upgrade and Belle II–style e+e− correlation measurements offer an especially clean environment to test this scenario, by searching for TMST–driven changes in spin– and flavor–sensitive observables associated with charm and exotic spectroscopy. The framework is formulated in a way that is directly implementable in basf2–type analysis chains and extensible to lattice QCD, global PDF fits and cold–atom analogs. Keywords QCD confinement intrinsic charm proton structure topological vortices Two–Mode Squeezing Threshold (TMST) entanglement dominance gluon condensate Belle II Chiral Belle polarization upgrade SuperKEKB e+e− correlations spin observables exotic hadron spectroscopy dark sector searches electroweak precision

Zenodo
Javier Manuel MartĂ­n AlonsoJan 31

TMST code: entanglement threshold T₀ simulations.

GitHub → https://github.com/JavierMartinAlonso1980/entanglement-dominance-tmst
DOI → https://doi.org/10.5281/zenodo.18353640

#QFT #OpenScience

Show threadJavier Manuel MartĂ­n AlonsoJan 26

@sflorg Thanks for the bookmark and interest in follow-up! My TMST already solves Lattice QFT with precise T0 thresholds in Python/NumPy. More on GitHub soon. 😊 #QFT #OpenScience #QuantumSimulation #LatticeQCD #AIforScience

🔗 https://github.com/JavierMartinAlonso1980/entanglement-dominance-tmst

Scientific FrontlineJan 26
Researchers successfully utilized Artificial Intelligence to solve a long-standing problem in particle physics: calculating Quantum Field Theories ( #QFT ) on a lattice with optimal precision.
#Physics #QuantumScience #AI #ArtificialIntelligence #sflorg
https://www.sflorg.com/2026/01/phy01262601.html
Artificial intelligence makes quantum field theories computable

An old puzzle in particle physics has been solved: How can quantum field theories be best formulated on a lattice to optimally simulate them on a comp

Wulfy—Speaker to the machinesNov 28

@AAKL @kdkorte @avuko @Reuters

The "evil man" is my own philosophical argument.
If an evil man, fakes being good for years.
Doing everything a good man does, are they still evil?

I am unconvinced that probabilistic design is the show stopper that most lay folk think dismisses current models.

What with some big brain thinkers offering the notion the fundamental layer of our reality being deterministic quantum fields (QFT) and deterministic collapse of quantum wave function defines events.

TLDR;
👉Stochiastic universe may be factual👈
materialist deterministic illusion (which is what some AI sceptics embrace) is the fantasy LLMs expose by "working"

#QFT #AI #LLM

solobsdSep 13, 2025
Let’s talk about Quantum Field Theory https://open.spotify.com/episode/2zHDcZGAyz1Ygmck3gq1La?si=w99SVNh5Qk2WsjgCKCN_gQ #qft #physics
Quantum Field Theory

SoloBSD Podcast ¡ Episode

Spotify
Holger GiesSep 3, 2025

It's great to be at the ExHILP 2025 conference at ELI-Beamlines near Prag.

You can't say that the community doesn't have a healthy sense of self-confidence.

#ExHILP #ELI #UltraIntense #Laser #QED #QFT

RyanJun 6, 2025

#math #physics #quantum #tqft #qft #topology #logic

https://www.authorea.com/users/854182/articles/1302444-diagnosing-contextuality-in-a-topological-quantum-field-theory-a-toy-model

Andrew J. SteinmetzJun 4, 2025
Black branes are higher dimension #BlackHoles that have hydrodynamic properties. The Holographic Principle means these branes ≈ lower dimension #QFT fluids. The absorption cross-section of low energy #Gravitons by the brane is then proportional to ideal fluid viscosity. #Science #Physics #Gravity 🧪⚛️

RE: https://bsky.app/profile/did:plc:xd6msyxiymq4ldfllpeusl6h/post/3lqpocgsa2c2v