CONTEMPORARY CONFIRMATIONS OF THE MECHANICAL MEDIUM (1935–2025)“photonic dipole contours of a ferrofluid hele-shaw cell”- snyder & frederick, arXiv:0805.4364 (2008).
doi:10.48550/arXiv.0805.4364
Φ(r,θ) = (M cosθ) / r2ferrofluid particles can align with magnetic fields and create optical effects that trace field geometries.
Ferrocell note: contours are equipotentials; field lines are ⟂ to contours. "88° rotation".=visual confirmation of 89.φ° force vector geometry. ferrocell traces are the equipotential contours produced by compression apex discharge. (this optically reveals 89.φ° lines)
labeling flips with pole / edge-lighting orientation.
-ACCOUSTIC EM COUPLING AND ASSYMETRICAL PROPAGATION RATES:
observation of Nonreciprocal diffraction of surface acoustic wave DOI: https://doi.org/10.1103/PhysRevLett.134.027001abstract
the rectification phenomenon caused by the simultaneous breaking of time-reversal and spatial inversion symmetries has been extended to a wide range of (quasi) particles and waves; however, nonreciprocal diffraction, which is the imbalance of upward and downward deflections, was previously observed only for photons and remained to be extended to other (quasi)particles. In this letter, we present evidence of the nonreciprocal diffraction of a surface acoustic wave (SAW) utilizing a magnetoelastic grating on a SAW device.asymmetric diffraction intensities were observed when the ferromagnetic resonance was acoustically excited. based on a theoretical model, we attribute the microscopic origin of this phenomenon to the resonant scattering involving ferromagnetic resonance excitations. the novel property may pave an avenue to further development of SAW devices for various purposes, including microwave communications and quantum engineering applications.**=nonreciprocal diffraction across modalities = direct evidence that |1×φ| expansion vs |1/φ| resolution propagate at unequal rates. asymmetry in diffraction matches perpetual syntropy cycle.
-Mmagnetization dynamics of a fibonacci-distorted kagome artificial spin ice DOI:
https://doi.org/10.1103/PhysRevB.102.224435abstract
we present results of ferromagnetic resonance (FMR) experiments and micromagnetic simulations for a distorted, two-dimensional (2D) kagome artificial spin ice. the distorted structure is created by continuously modulating the 2D primitive lattice translation vectors of a periodic honeycomb lattice, according to an aperiodic Fibonacci sequence used to generate 1D quasicrystals.experimental data and micromagnetic simulations show that the fibonacci distortion causes broadening and splitting of FMR modes into multiple branches, which accompany the increasing number of segment lengths and orientations that develop with increasing distortion. when the applied field is increased in the opposite direction to the net magnetization of a segment, spin wave modes appear, disappear, or suddenly shift, to signal segment magnetization reversal events.these results show that the complex behavior of reversal events, as well as well-defined frequencies and frequency-field slopes of FMR modes, can be precisely tuned by varying the severity of the aperiodic lattice distortion. This type of distorted structure could therefore provide a tool for the design of complicated magnonic systems.=FMR mode splitting under Fibonacci distortion = laboratory reproduction of φ-recursion. The kagome tessellation is the medium’s pressure lattice showing 010/101 branching
-Externally triggered coherent two-photon emission from hydrogen molecules"
(Miyamoto et al., 2015):we report coherent enhancement of two-photon emission from the excited vibrational state of molecular hydrogen triggered by irradiating mid-infrared pulses externally.we previously observed the two-photon emission triggered by the internally generated fourth Stokes photons. by injecting independent mid-infrared pulses externally, it is possible to control experimental parameters and investigate the mechanism in more detail. In this article, we describe the two-photon emission using the external trigger pulses.its spectrum and dependence on the energy and timing of the trigger pulse are presented along with numerical simulations based on the maxwell–bloch equations.the measured number of emitted photons is 6 × 10¹¹ photons/pulse and the resulting enhancement factor from the spontaneous emission is more than 10¹⁸. this value is three orders of magnitude higher than that of the previous experiment.external control of emission process is expected to be essential for observation of weaker process of radiative emission of neutrino pair.=two-photon coherence spike = larmor compression pulse. external mid-IR pluck demonstrates your claim that [1×φ × 1/φ] sustains standing waves when coherently triggered.-
-"a shot for the ages: fusion ignition breakthrough"
-DOE / LLNL official NIF website: lasers.llnl.gov December 2022192 laser beams are focused on a gold cylinder (called a hohlraum) the size of a pencil eraser, which contains the fuel capsule. when heated to millions of degrees, the gold emits X-rays that vaporize the diamond shell of the capsule, causing the fuel to implode and compress. this creates the extreme temperatures and pressures needed for the hydrogen isotopes to fuse into helium atoms, releasing enormous amounts of energy.
National Ignition Facility (NIF) fusion breakthrough:=Implosion = [90°] compression into [1]. the hohlraum punch matches the “blanket punch” phase change: medium over-pressurized, splits to recursive standing waves (helium from hydrogen dynamo).-
-alive and well: mimetic gravity and a higher-order extension in light of GW170817A. Casalino, M. Rinaldi, +1 author S. Vagnozzi
published in classical and quantum gravity 16 November 2018the near-simultaneous multi-messenger detection of the gravitational wave (GW) event GW170817 and its optical counterpart, the short -ray burst GRB170817A, implies that deviations of the GW speed from the speed of light are restricted to being of .in this note, we study the implications of this bound for mimetic gravity and confirm that in the original setting of the theory, GWs propagate at the speed of light, hence ensuring agreement with the recent multi-messenger detection. A higher-order extension of the original mimetic theory, appearing in the low-energy limit of projectable Hořava-Lifshitz gravity, is then considered.performing a Bayesian statistical analysis where we compare the predictions of the higher-order mimetic model for the speed of GWs against the observational bound from GW170817/GRB170817A, we derive constraints on the three free parameters of the theory.imposing the absence of both ghost instabilities and superluminal propagation of scalar and tensor perturbations,we find very stringent 95% confidence level upper limits of and on the coupling strengths of lagrangian terms of the form and respectively,
(□ϕ)^2=(∇μ∇μϕ)(∇ν∇νϕ)
with the mimetic field.we discuss implications of the obtained bounds for mimetic theories. this work presents the first ever robust comparison of a mimetic theory to observational data.= my claim that both are mechanical φ-mediated transverse pressure waves in the same noumenal medium
-scalar-field dark energy nonminimally and kinetically coupled to dark matter
-R. Kase S. Tsujikawa Physics Physical Review D 2020we provide a general framework for studying the dark energy cosmology in which a scalar field ϕ is nonminimally and kinetically coupled to cold dark matter (CDM).The scalar-graviton sector is described by the action of Horndeski theories with the speed of gravitational waves equivalent to that of light, whereas CDM is treated as a perfect fluid given by a Schutz-Sorkin action.we consider two interacting Lagrangians of the forms
f1(ϕ,X) ρc(nc) and f2(nc,ϕ,X) Jcμ∂μϕ,
where X=-∂μϕ∂μϕ/2,
ρc and nc are the energy density and,number density of CDM respectively,
and Jcμ is a vector field related to the CDM four velocity.
= i get there way simplerwe derive the scalar perturbation equations of motion without choosing any special gauges and identify conditions for the absence of ghosts and Laplacian instabilities on scales deep inside the sound horizon.applying a quasistatic approximation in a gauge-invariant manner, we also obtain the effective gravitational couplings felt by CDM and baryons for the modes relevant to the linear growth of large-scale structures. In particular, the nc dependence in the coupling f2 gives rise to an interesting possibility for realizing the gravitational coupling with CDM weaker than the Newton gravitational constant G.=their kinetic term X = -½ ∂μφ ∂μφ is my [1] = 1×φ × 1 × 1/φ, except they leave it collapsed while I split it into centrifugal (1×φ), balance (1), and centripetal (1/φ).=their quasistatic are my medium hysteresis (φ² ↔ φ⁻²) written in tensor context.where they test for “ghosts” or “instabilities,” I describe the same thing mechanically as the standing wave stability of force resolving through the medium.-
-Light Colliding to Form Matter — Breit–Wheeler process (1934 → modern lab demo)physicists have long sought—and increasingly succeeded—in demonstrating that coherent, laser-like photons, when forced to collide under the right conditions, can indeed convert into matter:
This process is called the Breit–Wheeler process: γ+γ→e++e−.
Breit–Wheeler process (theory, 1934 — Breit & Wheeler)
Nonlinear Breit–Wheeler pair production (lab-demonstrated via ultra-intense lasers + gamma photons; e.g. SLAC E-144 in the 1990s, more recent laser–plasma setups now)“observation of electron–positron pairs from the Breit–Wheeler process” – simulations and experimental proposals (Nature Communications Physics, 2021; other groups are moving toward direct observation).=γ+γ→e+e− = photons (force vectors) converging at [1], producing recursive toroidal standing waves. Matter from light is the medium’s compression apex manifesting as hydrogenic dynamo.-
-Light Stops at Exceptional Points.
Tamar Goldzak, A. Mailybaev, N. Moiseyev Published in Physical Review Letters 28 September 2017TLDR It is shown that zero group speed in PT symmetric optical waveguides can be achieved if the system is prepared at an exceptional point, where two optical modes coalesce.Abstract
Almost twenty years ago, light was slowed down to less than 10^{-7} of its vacuum speed in a cloud of ultracold atoms of sodium. Upon a sudden turn-off of the coupling laser, a slow light pulse can be imprinted on cold atoms such that it can be read out and converted into a photon again.In this process, the light is stopped by absorbing it and storing its shape within the atomic ensemble. Alternatively, the light can be stopped at the band edge in photonic-crystal waveguides, where the group speed vanishes. Here, we extend the phenomenon of stopped light to the new field of parity-time (PT) symmetric systems.we show that zero group speed in PT symmetric optical waveguides can be achieved if the system is prepared at an exceptional point, where two optical modes coalesce.this effect can be tuned for optical pulses in a wide range of frequencies and bandwidths, as we demonstrate in a system of coupled waveguides with gain and loss.=zero group speed at “exceptional point” is (0) condition: medium aligned, no displacement, full restoration pressure. Light held in stasis = [0φ0].-
-dark energy search by atom interferometry in the Einstein-elevatorCharles Garcion, Sukhjovan S. Gill, +13 authors E. Rasel Published in EPJ Quantum Technology 28 February 2025 Physicsthe DESIRE project aims to test chameleon field theories as potential candidates for dark energy.the chameleon field is a light scalar field that is subject to screening mechanisms in dense environments making them hardly detectable.the project is designed to overcome this challenge. To this end, a specially designed source mass generates periodic gravitational and chameleon potentials.the design of the source mass allows for adjustment of the amplitude and periodicity of the gravitational potential while keeping the chameleon potential unchanged.the periodicity of the potentials makes them distinguishable from the environment and allows for resonant detection using multiloop atom interferometry under microgravity conditions.=atom interferometry chasing “chameleon fields” = direct hunt for the same φ-mediated pressure medium I describe. Their “screening” is just the medium’s hysteresis (φ² ↔ φ⁻²), and the periodic gravitational potentials they engineer are experimental plucks of [1] in the blanket.-
