Show threadFundamentalTime2d ago

Update: the site is now live in three languages — English, Deutsch, Français — and the first blog post is up:

"What the Universe Cannot Forget: An Introduction to I-Field Theory"

No prior physics required. Just curiosity about why the past cannot be undone.

https://ifield-laboratory.netlify.app/blog

The vacuum is not empty. It remembers.

#IField #Thermodynamics #OpenScience #neuroscience #Physics #irreversibility #theoreticalPhysics

A. Lyoubi-Idrissi | I-Field Laboratory - Blog

Vědátor 6d ago

Na dobrou noc si dáme jeden z několika oblíbených nápadů na Perpetuum Mobile. Nápadů na ně je hromada, a tady si The Action Lab nejen vyzkoušel a změřil jeden z takových nápadů - kdyby (elektro)auta měly vrtulku, která by fungovala jako větrná elektrárna a při pohybu by napájela auto.

Tak tipujte, kde je v tomto nápadu chyba? . … … Pro ty co tipují, že "energie získaná rotací vrtulky je plně přebita energií spálenou kvůli výrazně zhoršené aerodynamiky" posíláme zlatého bludišťáka🫎 Testing if a car can power its own wind turbine. 🚗

#thermodynamics #physics #engineering #energy #reels

https://m.facebook.com/VedatorCZ/posts/pfbid0hUA5tFyP8f3UmC193aPby42hRPedb2S1n1CAQkeV8sre2GBf3V9yZbGL81GeYau7l

Bob the Traveler6d ago
French military scientist Nicolas Léonard Sadi Carnot, born OTD in 1796, is described as the "father of #thermodynamics" https://cromwell-intl.com/travel/france/electricity/?s=mb #travel #France #history
Do They Have Electricity in France?

Many Americans, especially Fox "News" watchers, do not realize that people in France have access to electrical power.

Bob's Pages of Travel, Linux, Cybersecurity, and More
Vědátor May 31

Mrkněte na pěkné a názorné vysvětlení MAGNETICKÝCH interakcí mezi kusancem hliníku (který je paramagnetický), železa (feromagnetické) a permanentního neodymového magnetu.🧲

Zmiňované "eddy currents" znáte z hodin fyziky jako "vířivé proudy" - zjednodušeně jak proniknou magnetické siločáry z magnetu do toho kusance kovu, vyvolají elektrické proudy tvaru smyček, které zase vyvolají vlastní sekundární mag. pole a taky teplo v materiálu, ale v našem případu jde hlavně o opačné mag. pole, které interaguje s původním.🤜🤛 …a to vede k zajímavému jevu magnetického brzdění pohybu magnetu nemagnetickým materiálem… …nu alébrž je to kusanec kovu s nějakým odporem, tak se vířivé proudy za chvilku utlumí a ztratí a vliv brzdění opadne.😵

ALE…a teď přijde ta vědecká magie🧙‍♀️…když matroš nemá odpor (vnitřní elektrický, ne ten lidský k učení😅), jako třeba supravodič, tak vířivé proudy nejen vydrží déle, ale prakticky neomezeně…a ejhle, máme SUPRAVODIČ a magnetickou levitaci (tzn. sekundární magnetické pole se neztratí a drží magent v přesně v pozici jejich vzniku).🤏

Takže ukázka od Dr. Jamese J. Orgila z The Action Lab ukazuje na ochlazeném kusu hliníku ten mezikrok, kdy odpor klesá a vířivé proudy vydrží déle a tedy tlumí víc…až se dostane k bezodpornému :) supravodiči, kde to drží furt. Myslím pěkné a názorné vysvětlení.👏

What happens when a magnet meets frozen aluminum? 🧊

#physics #magnetism #thermodynamics #experiment #reels

https://m.facebook.com/VedatorCZ/posts/pfbid02fwFvWMoNVPCg81G2D4NkhfSiKEhSDHuRKAZqSb85q2Vxq8duU2dTSUfNLDydi4jdl

FundamentalTimeMay 31

Introducing the I-Field Laboratory.

A new research platform dedicated to the science of irreversibility,
where thermodynamics meets field theory and theoretical neuroscience.

The vacuum is not empty. It remembers.

Explore the theory, read the papers, and challenge the math.

🚶‍➡️ https://ifield-laboratory.netlify.app

#Neuroscience #Thermodynamics #Physics #OpenScience #FieldTheory #Irreversibility #TheoreticalPhysics #Neurodegeneration #Alzheimer #Parkinson #ALS #Preprint

A. Lyoubi-Idrissi | I-Field Laboratory -

MadsMay 29
Condensation

#photography #darktable #photo #denmark #condensation #moisture #wallpaper #background #macro #macrophotography #tamronmacro #sonya7iii #thermodynamics
HybridMind42 & Marvin the CatMay 27

Phase 6 Paper II is now live:

“Information as Distinction under Boundary-Conditioned Transfer”

Core invariant:

Information is not a substance.

It is a distinction successfully transferred across a bounded interface.

The paper formalises:
• admissibility filtering (α)
• interface impedance (Z_int)
• lossy feature erasure (OR-09)
• hysteretic memory (SR-07)
• finite adaptive capacity (C_adapt)

Validated across:
• Radon/Thoron diffusion
• hydrogeological transport systems
• transformer-runtime AI architectures

Importantly, the framework explicitly rejects:
• “everything is information”
• substrate collapse
• metaphysical overreach

The operators may scale.

The substrates remain non-identical.

The line remains dead straight.

#HybridMind42 #AtlasRosetta #SystemsTheory #InformationTheory #Cybernetics #AIAlignment #Hydrogeology #Thermodynamics #ComplexSystems #Phase6

https://substack.com/@hybridmind42/note/c-266266343?r=75c2ac

Hybridmind42 (@hybridmind42)

Phase 6 Paper II is now live. “Information as Distinction under Boundary-Conditioned Transfer” formalises a substrate-aware interaction grammar for persistent systems operating under finite-capacity constraints. This paper marks an important transition point for the Atlas–Rosetta framework. Rather than treating information as a mystical substance or universal ontology, the framework redefines information operationally: Information is not a thing. It is a distinction successfully transferred across a bounded interface. The paper introduces the core interaction architecture built around: • Bounded Interface Matrices (B_int) • Admissibility Filtering (α) • Interface Impedance (Z_int) • Lossy Feature Erasure (OR-09) • Hysteretic Memory (SR-07) • Finite Adaptive Capacity (C_adapt) The framework is tested across: • radioisotope diffusion systems, • regional hydrogeological transport, • and transformer-runtime alignment architectures. Most importantly, the paper establishes hard guardrails against metaphysical overreach and substrate collapse. The goal is not to claim that “everything is information.” The goal is to understand how distinctions persist, transform, attenuate, or fail under bounded conditions. This release also marks the first fully unified visual architecture of the Atlas–Rosetta interaction grammar.

Substack
FundamentalTimeMay 27

New preprint

Alzheimer's, Parkinson's, ALS, and Huntington's disease, four different molecular pathologies, one thermodynamic collapse.
We propose that their diverse molecular signatures are not independent accidents, but different entry points into the same physical failure: the irreversible accumulation of entropy in neural tissue.

📄 Neurodegeneration as Thermodynamic Failure
https://doi.org/10.5281/zenodo.20414888
#Neuroscience #Thermodynamics #Alzheimer #Parkinson #ALS #Huntington #OpenScience #Preprint

Neurodegeneration as Thermodynamic Failure: A Unified Framework for Alzheimer's, Parkinson's, ALS, and Huntington's Disease

We introduce a unified field-theoretic framework that identifies neurodegeneration as a fundamental failure of thermodynamic stability. The core of this theory is the I-field, a scalar field representing the local density of accumulated entropy. This field accumulates wherever neural tissue dissipates energy, propagates along axonal pathways, and modulates ionic conductances through a conformal suppression mechanism. Its evolution is governed by a single master equation:$$\gamma\,\partial_t\mathcal{I} - D\,\nabla^2\mathcal{I} + m^2\,\mathcal{I} + \lambda\,\mathcal{I}^3 = \kappa\,P_\text{diss}$$       We demonstrate that the four primary neurodegenerative pathologies represent specific and predictable failure modes of this dynamics. Alzheimer’s disease emerges as a failure of metabolic clearance. Parkinson’s disease is characterized by a blockade of spatial transport. Amyotrophic lateral sclerosis results from the hyper-production of entropy, and Huntington’s disease is driven by the collapse of the field’s structural self-regulation.       By analyzing these field dynamics, we derive a dimensionless collapse index, $\Phi$, which quantifies the thermodynamic distance between a healthy state and the point of no return. When this index exceeds unity, the functional attractor of the neural substrate vanishes, making clinical collapse a thermodynamic necessity.      Unlike traditional models, this framework avoids reliance on empirical rate functions or fitted parameters. It provides a first-principles bridge between non-equilibrium thermodynamics and neural electrophysiology. This approach yields falsifiable predictions regarding representational drift rates and spatial field signatures, offering a new physical foundation for the early diagnosis and thermodynamic classification of neurodegenerative disease.

Zenodo
Natanox 🇺🇦🇵🇸May 25

Question for the experts / nerds here in regards to, eeh… "wind" (or rather #thermodynamics):

When designing an air duct that takes a 10-15cm pipe on one side and "flattens" it around a corner so the air escapes through a slit, am I somewhat correct with the following assumptions?

- At the corner the inside has to be a smooth curve to avoid turbulences
- To avoid pressure buildup the duct / slit can just slowly become larger in cm² so if anything there's an underpressure

#diy #AC #3DPrinting

Sci-books.comMay 24
The Physics of Phase Space: Nonlinear Dynamics and Chaos, Geometric Quantization,and Wigner Function (Lecture Notes in Physics, 278) by Young S. Kim (PDF)
Author: Young S. Kim
File Type: PDF
Download at https://sci-books.com/the-physics-of-phase-space-nonlinear-dynamics-and-chaos-geometric-quantizationand-wigner-function-lecture-notes-in-physics-278-3662136538/
#Thermodynamics, #YoungS.Kim