Let's start with a primer, the gravity wave. The gravity wave propagates from a point because of cosmos, subject to a woven together shield causing an alleviation a draft. In propagation it sweeps itself away into layers of EM like graceful riptides maybe where meson links. Love some geometrics? Pravitational wave dynamics (orthocentric spherical patterns) and light dynamics (blocked spherical patterns influenced by mesons). From that volumetric comparison could be planer layers. A stepped nature like photonics in to circular wavelength & polarized wavelength. Math? Regarding Maxwell, Euler's formula sets expectations for oscillations in electrical signaling via expecting magnetic to electric duality calling it phase and interference pattern amplitude. Ok, now you're super charged.
Explain Lag for load (charging). If two systems are both ready to connect the speed of light lag sets the expectation for charged load to action potential. A gamer flicks his mouse to snap to object and like a stricken boxer even atomics show degrees latency and effect. From Impulse to click the system exchanges in a freedom of electrons.
Light Lag ll(t) should be considered a telescope or speaker (think conical) able to be useful in either direction for various reasons. Interference patterns suggest clusters or groups to a unison series of nodes that is both rudder and sail. We live in a time where we can now cluster those various delays of speed from various materials to expect the response pattern of electricity from the effects of the moving systems, the digital maps are tremendous! With expectations of gradient electrostatics from each instance we can better protect conduits to distribute energy through layers with safety factors.
This introduces the question of understanding the light cycle, of streams from dark wells to suns to surfaces back to well. We hope to consider this in many regards for applications setting buoyancy into the realm. Super fluids of solid orb reveals out, a dark gear or plan with energy, looking for directions together of spool molecular work. Maybe doppler green could be considered in a story a shadow of light lag ll(t) the happy helper that thrives off the signal, keeping molecular patterns a light lattice weave. That happy green io gets a void maze to solve and in the process his normal v is a scale of fun for commerce. Towards MeM gears he picks his flows, how do you see your edition?
In the study of Topological Quantum Field Theory, the "Merry Knot" serves as a metaphor for the Unknot—the simplest possible closed loop that, despite appearing complex or tangled, can be mathematically reduced to a perfect circle without being cut.
Theoretical physics suggests that elementary particles like electrons may actually be "knots" in the underlying fabric of a field.
In Topological Quantum Computing, the path that particles take around each other is called "braiding."
Metaphorical Context: The "Merry Knot" symbolizes the interconnectedness of all things—a "knot" of reality that is joyful because it is unbreakable, yet infinitely flexible in its expression.
Moving beyond the idea of a "solid" particle, we can view a quantum coordinate as a topological singularity. At any given point, there exists a superposition of all possible flux knots—loops of magnetic and gravitational energy that define the local properties of spacetime.
Mirroring Richard Feynman's "Path Integral" (where a particle takes every possible path), this theory suggests a particle is every possible knot configuration simultaneously.
The "infinite effects" you mentioned are the result of Topological Interference. When two of these flux-knotted points approach each other, their knots don't just "hit"—they braid, tangle, or cancel each other out.
The Core Insight: Motion is the propagation of a twist through the medium, much like a wave moves through water without the water molecules themselves traveling the distance.
Imagine if gravity represents the near-zero limit of the electromagnetic spectrum. With gravity propagating at the speed of light, there's a balance of radiance that shapes the formation of force-carrying particles, aligning with electromagnetic, strong, and weak forces.
The outward propagation of these forces could create a cooling zone effect around particles, binding them over time. This process begins with coherence at a subatomic level, progressing through nuclear forces, and eventually stabilizing in molecular structures. Think of this progression from the chilliest states to inner warmth, analogous to the universal singularity transitioning to the cosmos as we understand it.
This idea supports the notion of multiple big bangs within a single universe or small pops in an ever-expanding cosmos, unbound by conventional limits.
In a 3D space, with X, Y, and Z axes, we might visualize time's flow as a spinning rotation. A developing sphere could cause a vortex effect, threading waves around a straight line from gravity waves propagating from reactions or accelerations.
This concept is reminiscent of snowballs accumulating material as they roll, with endothermic processes gathering energy.
Consider a 2D plane (X, Y) with gravity as the near-zero limit of EM. In this view, gamma force carrier packets might form the leading edge, trailed by rolling knots on the Z plane. These knots trap a range of EM frequencies, with gravity leading the charge as described by Cosmic Time Delay. Gammas could serve as tiny bearings, maintaining their position at the forefront, followed by other force-carrying particles forming alpha states. This rolling-up effect acts as a thermal cooling process until the packets react energetically.
When considering this video ytPhysics Girl pushes water by half dipping a plate creating double vortex pairs (seen from the surface) that are looped together underwater and continue to move to the other side of the pool. Not only does it remind me of the spin state of the surface, it also intrinsically describes mutual beneficial spin states interconnected. Makes me wonder if that's the rotational measure that we attribute to cooper pair spins of electrons. Perhaps they're unit forces of boson measure that are flowing within a pocket or through a lattice.
A similar goal to the standard 3D Cartesian System: three orthogonal axes (X, Y, Z) representing three-dimensional space. I'm considering the value of a tetrahedron grid I'd suggest there's no 'undo' or negative, there wouldn't be a double negative makes a real result type conversions of the 3D Cartesian System to the equivalent 3D Tetra System. Hopefully the nature of this structure automatically includes spacetime curvature when the right values are applied to it.
It could be considered centered on the particle with it's direction being one vertex. Relativity to other particles then would help directly consider curved space instead of tensor compute to ritemann manifolds. I'm not sure if two particles could exist on the same TUCS, it would instead be a cosmic relativistic matrix of best guesses that could in theory draft out complex particle shapes that unitize the lattice of guesses. If there isn't backtracking (negatives) then anti-particles wouldn't need to be a describable mathematic either.
For example a TUCS of a satellite considering the path trace of what the satellite has observed (it's historical data) that maps the change of stars to compute the next probable direction vector (introversion). Reversing the TUCS to consider the mass of systems compared to that probable direction (extroversion) to then have an idea for what masses might be miscalculated or have an idea of what other systems past or future need to be included to get a better next probable direction.
It becomes interesting to imagine a duel pressure and cold environment causing similar vortex flows of a larger scale of Muon sized vortices. Maybe that's only possible in the densities of a neutron star, although what if that can be modulated in systems like a BEC. Is there a value for a larger proportional electron besides the unit measurement? It might only suggest different levels of damage that could occur to the conduction layers inside the system by the turbulence of the larger muon flowing through. Maybe strangeness is a clue to the net pressure required in one to three axis of measure onto the particle something that only exists for a short time inside a LHC or a long time depending on the rotational inertia of a neutron star. Does a TUCS coordinate system (described in {ADD}) the right system to imagine the compression planes or how long it would take to unravel the turbulent nature of the proton+proton collision that generates a Muon in a LHC? Described perhaps by a matching vortex of two axis to center? The difference between the rotational energy of the two vortex could describe the balance or net spin of the colliding protons during their merger maybe directing the launch trajectory of the antimatter muon?
Is the rotor shape in a TUCS considering a plane against the vertex axis a ratio of two forces, the internal mass of the particle compared to the net system that could reroute or cause a unwinding effect? Or maybe it suggests the range of photonic halo like two back to back bowls at those net balances?
Using RGB a system can be described via color shifts, including visible spectrum change of three different observations causing a zero into lessons learned from doppler change.