Explanation of Two Slit Experiment using Single Photons ∆E=hf
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- Опубліковано 28 вер 2024
- Water waves can go through two slits at the same time. Could light wave do the same going through both slits as a wave forming the potential for the exchange of photon energy as a statistical probabilistic future unfolds?
One explanation is that light goes through both slits as a wave with probabilistic uncertain ∆×∆pᵪ≥h/4π future coming into existence with the exchange of photon ∆E=hf energy transforming potential energy into the kinetic Eₖ=½mv² energy of electrons.
This video answers these questions:
Could light and electrons be waves over a ‘period of time’ with particle characteristics as an uncertain future unfolds?
Could the wave particle duality of light and matter in the form of electrons be forming an interactive process forming a blank canvas?
Could we have a probabilistic uncertain future unfolding quanta by quanta with each single photon?
Could light go through both slits as a wave forming the potential for a new photon forming an uncertain probabilistic future unfolds?
Could the future be emerging photon by photon relative to the structure of the experiment and the wavelength of the light?
Do we need a deeper understanding of how a ‘period of time’ and statistical entropy is formed?
Could the mathematics of quantum mechanics represent the physics of time relative to the atoms of the ‘Periodic Table’ with classical physics representing processes over a ‘period of time’ as in Newton's differential equations?
Is the Future relative to our actions with the Planck Constant h/2π being a constant of action within the geometrical process that forms the characteristics of 3D space and time?
Reference and Original Video by Veritasium
• Single Photon Interfer...
In the second half of this video there is an explanation explaining light as a wave with particle characteristics when it interacts with matter. Even at low energy with just the potential for one photon at a time, light is a wave that goes thought both slits. It only has particle or photon characteristic when it comes in contact with the rear screen of the experiment. It is logical that over a period of time, the light waves will interact with each other in a process called, constructive and destructive interference. We see the pattern of lines form over a ‘period of time’ photon by photon, but there is only the potential for one photon within the experiment at each moment of time.
Reference and Original Video by Veritasium
ua-cam.com/video/GzbKb59my3U/v-deo.html
Photons are waves and particles at the same time. Its not an uncommon phenomena, its called a soliton and occurs in nature all the time. Photonic solitons are resitant to decay because to they are massless and dont experience time. They are forever as instantaneous as the moment of their creation.
en.wikipedia.org/wiki/Soliton
Thanks so much for the link, fascinating!!! Soliton is a nonlinear process. This theory explains a linear process, that forms time itself. In the link it say solitons are also studied in quantum mechanics and could provide a new foundation of de Broglie's unfinished program. The atomic nuclei may exhibit solitonic behavior based on energy and temperature. In this theory the atoms are standing waves in time. There seems a great similarity between soliton and standing waves!
@@Dyslexic-Artist-Theory-on-Time Yes on the fundamental nature of photons I approach the issue from the low energy end because at 4OGHz for example, the photon is about 75mm across, so it is much easier to study its initial formation, energy distribution, separation and radiation away from the energy source (the phenomena of cut off). When looked at in this realm the photon clearly has all the characteristics of a soliton. There is no reason to believe the nature of photons changes as a consequence of energy levels.
In short if it looks like a duck, quacks like a duck, it almost certainly is a duck. As solitons, there is little or no mystery about photons at all.
Still isn't making sense. How do you get a pattern at all? Shooting one photon at a time should mean one giant spot in the back, unless you're randomly aiming the photon. We know photons travel in a straight line unless influenced by an outside source. If you're aiming at the left slit, the spot should be behind the left slit, not randomly patterned on the background. If you aim it between the slits, it shouldn't go through either one. The experiment needs further explaining for me to get it.
This would be true if light had just particle or photon characteristics. But in this theory, explained in the second half of the video, light is a wave with particle characteristics when it interacts with matter. Even at low energy with just the potential for one photon at a time, light is a wave that goes thought both slits. It only has particle or photon characteristic when it comes in contact with the rear screen of the experiment. It is logical that over a period of time, the light waves will interact with each other in a process called, constructive and destructive interference. We see the pattern of lines form over a period of time photon by photon, but there is only the potential for one photon within the experiment at each moment of time. Thanks for the feedback!!!
@@Dyslexic-Artist-Theory-on-Time Yes, i understand that scientific explanation. I'm just saying it needs more explaining. Like how is it possible for a singular photon to act like a wave? You didn't address the points i've made. Please try again.
@@smokert5555 The nature of solitons goes someway to explaining the enigma. Solitons have simultaneously properties of both objects and waves. An everyday examples is a smoke ring,
The photon could be considered a soliton, an excitation, in the electromagnetic field. They don't decay or fade away because being massless they don't experience time, forever instantaneous, travelling at the speed of light.
Viewed this way there is nothing particularly strange about them including double slit behaviour.
en.m.wikipedia.org/wiki/Soliton
@@smokert5555 A single photon may travel in a predominantly straight line over short distances, but its quantum nature and interactions with the environment can cause deviations from a perfectly linear path. The photon's trajectory is fundamentally probabilistic and uncertain at the quantum scale.
The photon is in a superposition as it travels. If you want to know where it is you have to stop it. That collapses the superposition by forcing it to interact with a non-quantum system.
Any type of measurement or interaction that extracts information about the photon's quantum state will inevitably lead to wave function collapse.
We can only infer that a particle was in a superposition through indirect observations such as the interference pattern.
The Uncertainty Principle says that the more precisely we know the particle's position (which slit it went through), the less precisely we can know its momentum. And vice versa - the more we preserve the particle's wave-like momentum, the less we can know about its precise position.
I can only tell you what happens, but I can't say why. Right now why is a question for a priest or philosopher.
It's fairly simple really.
The photon is simultaneously a wave and an object (particle). Things with such characteristics are known as solitons (see below). Solitons exist throughout nature from macro sized objects to the sub atomic.
In terms of the photon's dimension transverse to its line of propagation, the photon is about one wavelength across. So in this case the soliton (photon) goes through both slits. However, the slits constitute a diffraction grating and will diffract the soliton to its ultimate destination on the screen behind.
That the photons impact on the screen appears point like, is simply a function of the way in which the photon's energy is transfered to the atoms of the phosphor. The photon only has enough energy to excite the electrons of a single atom. It therefore appears point like as the photon's energy is transfered to an atom close to the centre of the photon's energy field.
en.m.wikipedia.org/wiki/Soliton
en.m.wikipedia.org/wiki/Diffraction_grating
Link the original. Go ahead, link it.
Will do!
ua-cam.com/video/GzbKb59my3U/v-deo.html
Audio is bad, hard to watch
🥴
100% plagiarism
The second half of the video is all original!!!
any images of this wave collapse? Like a 2 slit pattern vs the interference pattern? (I can’t find any. )
I will check this out!!!
@@Dyslexic-Artist-Theory-on-Time right on
Nice to see you made a video about it.👍
🤠👍