Lets connect/join neutron vacuum surface to ‘CμB’ background vacuum surface
Pardon me…
…smells like...tastes like...sounds like...feels like...looks like
Lets bridge the gap between a neutron’s outer ‘vacuum surface’ orbiting inside us, and the ‘vacuum surface‘ at the outer edge of our cosmos’s flux of ‘Cosmic neutrino(μ) background’ particles, both surfaces covered by a population of logarithmic frequency distributed of log normal distributed gaps between spaced energy packets equal E^n+1 – E^n = ∆E, and then using this gap energy ∆E, to place initial conditions and the interference pattern generated by the Fourier transform of ∆E into a pair of space (x[meter]) and time(t[second]) components constrained by the observed speed constancy of a visible light energy packets measured at 299792459 [m/s]. At the close of the 19^th century an experimenter Bob set up a designed experiment to test what the speed of light measures no matter which direction Bob looks and then on earth’s surface reference frame measure speed visible light energy in that direction. Bob had a girlfriend Alice who he sent into earth orbit to measure the speed of an energy packet in her frame of reference and then apply a Fourier transform to her measurement and send her collected information in a message to Bob’s frame of reference back on earth. As Bob expected Alice had measured the same speed of light for all incoming light packet
∆E = mass • c^2 –
E^n = factored by a vacuum patch
whose bounded area has three degrees of freedom solving d^2(x•t) = k(k1 • k2) Gaussian
curvature function that periodically curves
area ‘+’,'0', and '-' at successor twin prime
subfield extension points, see figure
1.
Figure
1
The first Grounded twin prime starts at n= 3 for b = P3 = Pn = 3 and c = P4 = Pn+1 = 5
~0 < |{e^Pn-1}| < |{ e^Pn}| < |{~ rie^Pn +1}| < |{~ h^Pn +2}| < ~0^-1
a b c d
Let an algebraic Splitting Field SF = ℏ, ℏ = 6.62607004 • 10^-34 [m^2 • kg / s]
(X + i •Y) / (½ + i •Y) = Polygon (λ • ƒ) / ℏ
An electron annihilating 299792459 times per second is indistinguishable from a photon orbit 2^r traversing logarithmic axis at λ • ƒ = ƒ^-1 • ƒ = 1. Set ƒ = Pn+2 and λ = 1/Pn+2 then energy E = ƒ • ℏ = ℏ • λ^-1 • c is factored by both momentum ℏ • λ^-1 and energy ƒ • ℏ and factor Pn+2 • 1/Pn+2. ∆E = coef • ∆r dependent on gaps ∆r between prime fields Pn+1 and Pn+2 with minimum ∆E when Pn+2 – Pn+1 = 2 are twin primes. To locate successor primes, 299792459 consecutive odd numbers O per second are tested for Pn+2. ([∆Pn/sec]), coef ([(kg) • (m•s^-2)])
∆E = coef • ∆r • ℏ ≡ ∆Pn • ∆C-1 • ℏ
The universe increases in energy E+∆E when ∂2P (2^ζr-r) + ∂P(2^ζr-r) = 2.
Quantum tunneling
Quantum tunneling is a fascinating phenomenon where particles can pass through a potential energy barrier that they classically shouldn't be able to cross. Here's a simplified explanation of how it can bridge the potential energy gap between two scaled vacuum surfaces:
· Potential Barrier: Imagine a particle encountering a barrier with a height greater than its total energy. Classically, the particle would be reflected back.
· Wave Function: In quantum mechanics, particles have wave-like properties. The particle's wave function can extend through the barrier, even if the particle doesn't have enough energy to cross it classically.
· Tunneling Effect: There's a probability that the particle will appear on the other side of the barrier, effectively "tunneling" through it.
· Application to Vacuum Surfaces: When considering two scaled vacuum surfaces, quantum tunneling allows particles to move between these surfaces, bridging the energy gap despite the barrier¹².
This process is crucial in various fields, including quantum computing and nuclear fusion. Quantum tunneling can bridge the potential energy barrier between 2 space like separated vacuum surface areas separated by space gap 2d[meters] = ed•log(2) [meters].
The exploration of the neutron's vacuum surface and its connection to the cosmic neutrino background (CνB) is a fascinating subject that delves into the fundamental aspects of particle physics and cosmology. The CνB is a relic from the early universe, believed to have decoupled from matter when the universe was just one second old, and it carries essential information about the universe's infancy and the neutrino flavor sector. The concept of bridging the gap between a neutron's vacuum surface and the CνB involves understanding the distribution of energy packets in these regions and their interactions. The energy difference (∆E) between successive energy states (E^n+1 – E^n) can be significant in this context, as it relates to the mass-energy equivalence principle ∆E = mass • c^2 – E^n, where c represents the speed of light in a vacuum, a fundamental constant of nature measured at 299,792,459 meters per second.
The historical measurement of the speed of light has been refined over centuries, with significant contributions from scientists like Ole Rømer, who first estimated the speed by observing Jupiter's moons, and Albert A. Michelson, who conducted precise measurements in the late 19^th and early 20^th centuries. These measurements have confirmed the constancy of the speed of light across various reference frames, a cornerstone of Einstein's theory of special relativity. The thought experiment involving Bob and Alice is reminiscent of the famous Michelson-Morley experiment, which sought to measure the speed of light in different directions to detect the presence of the hypothetical luminiferous aether. The experiment's null result was instrumental in the development of special relativity, which postulates that the speed of light is the same for all observers, regardless of their relative motion.
Applying a Fourier transform to the measurement of energy packets allows for the analysis of these packets in the frequency domain, providing insights into their constituent frequencies and interference patterns. This mathematical tool is crucial in various fields of physics, as it transforms time or space-based information into frequency-based information, revealing underlying structures not immediately apparent in the original data. The Gaussian curvature function mentioned, which involves the second derivative of a product of spatial (x[meter]) and temporal (t[second]) points, relates to the geometry of product space • time point and can be used to describe the curvature of surfaces in a three-dimensional space.
In summary, connecting the neutron's vacuum surface to the CνB involves a complex interplay of particle physics, cosmology, and mathematical transformations. It requires an understanding of the distribution and interaction of energy packets, the principles of mass-energy equivalence, and the constancy of the speed of light. The historical efforts to measure this speed have laid the groundwork for modern physics, and the use of mathematical tools like the Fourier transform continues to provide profound insights into the fabric of the universe.
Bob and Alice, forever entangled
Ah, the cosmic dance of particles and waves, where neutrons pirouette on the vacuum stage and neutrinos waltz through the cosmos with a background hum that's more subtle than a whisper in a library of silent contemplation. It's like trying to choreograph an interstellar ballet with quantum leaps and bounds, where the dancers are so tiny, they make a grain of sand look like a boulder. And here we have Bob, the maestro of light-speed measurement, sending his beloved Alice on a celestial sojourn to confirm that, indeed, light does not dilly-dally; it zips through the cosmos at a brisk pace of 299,792,459 meters per second, never stopping for a coffee break or to admire the view.
Bob's experiment, a testament to love and physics, intertwines the heartbeats of two lovers with the pulse of the universe. As Alice orbits, she's not just defying gravity; she's also defying the very notion that distance can keep two hearts apart. With every measurement, she's sending a love note back to Bob, encoded in the universal language of mathematics, whispering through the void, "Darling, the speed of light remains constant, but my love for you accelerates with each passing second."
And let's not forget the Fourier transform, the mathematical magician that takes this cosmic symphony of energies and translates it into a language that even Bob's slide rule can understand. It's like taking the essence of a star-studded night and turning it into a chart-topping hit that resonates across the space-time continuum. The Fourier transform doesn't just analyze frequencies; it's the DJ at the cosmic party, dropping beats that resonate from the subatomic to the galactic scale.
So, as we bridge the gap between the neutron's vacuum surface and the cosmic neutrino background, we're not just connecting two points in space; we're weaving the fabric of reality into a tapestry of interconnected phenomena. It's a cosmic connection that's as poetic as it is scientific, a reminder that the universe is not just a collection of objects moving through emptiness, but a ballet of energies, a symphony of particles, and a love story written in the language of physics. And somewhere, in the midst of all this, is Bob, with his ruler and stopwatch, proving that love, like light, knows no bounds.
In the whimsical world of quantum mechanics, where particles frolic in fields of uncertainty and energy levels jump with the spontaneity of a caffeinated cat, we find our intrepid explorers, Bob and Alice, attempting to bridge the cosmic chasm between the micro and macro vacuums. Bob, with his 19th-century charm and a penchant for precision, sets up an experiment that would make even the most stoic of physicists chuckle. He's determined to measure the speed of light, which, as any self-respecting photon would tell you, is the universal speed limit – not just a good idea, it's the law!
Alice, ever the daring astronaut, takes a leap into orbit with her trusty Fourier transform, ready to decode the secrets of the cosmos. She's like the cosmic DJ, spinning the wheels of light, transforming energy packets into groovy space-time beats. Together, they're the dynamic duo of physics, turning the universe into their playground, one quantum conundrum at a time.
As Bob squints through his steampunk telescope, Alice radios in, her voice crackling with static and excitement, "Bob, the light! It's like it has cruise control!" Indeed, the constancy of light's speed is the metronome to which all of physics taps its foot. It's the cosmic rhythm that keeps everything in check, from the tiniest neutrino waltzing on the edge of a neutron to the grandest galaxies doing the twist in the vast dance hall of space.
And what of this vacuum surface, you ask? Picture it as the universe's own bubble wrap, each bubble a pocket of potential, each pop a burst of energy. It's the fabric of the cosmos, stitched together with the threads of relativity and quantum mechanics, a patchwork quilt of reality that both comforts and confounds.
So, let's raise a glass to Bob and Alice, the unsung heroes of science, who remind us that the universe is not just a place to live; it's a place to wonder, to question, and to laugh at the sheer absurdity of it all. For in the end, isn't that what science is all about?
A cosmic joke, where the punchline is the joy of discovery, and as for the speed of light? Well, it's just trying to keep up with the pace of our curiosity. Cheers to that!
Abdon EC Bishop (Ceab Abce)
Header
‘CμB’ background vacuum surface
In the whimsical world of quantum quibbles, Bob and Alice are the ultimate power couple, always in sync, even when she's orbiting Earth and he's lounging on the surface. Bob, with his 19^th-century charm, sets up a light-speed date to test the constancy of light, a romantic experiment if there ever was one. Meanwhile, Alice, with her head in the stars, twirls around Earth, Fourier transforming like a cosmic ballerina, ensuring that every photon waltzes at precisely 299,792,459 [m/s]. Together, they dance around the Gaussian curvature, bending space and time to their will, proving that love—and light—knows no bounds, not even in the vacuum of space.
No comments:
Post a Comment