CONCENTRATED QUANTUM MECHANICALLY ENTANGLED PARTICLE COUPLES AND METHOD FOR MAKING THE SAME

Abstract

The present invention relates to a method creating highly concentrated quantum entangled particles which can be embedded into substrates such that the particles, and therefore substrates they are embedded upon are remotely controllable. The invention includes streaming a beam of particles through a beam splitter and then applying a selected correlation system, such as NMR or supercooling, to the particles in order to align the particle spins. The particles are then released from the correlation system resulting in an unnaturally high saturation of concentrated quantum entangled particles on a macro scale. The particles and substrates are then in a salve-x relationship configuration and are therefore remotely controllable. Through stimulation and detection, changes in state may be observable in order to determine the level of concentration and remote control.

Claims

1. A method for creating concentrated quantum mechanically entangled particle couples comprising: providing at least ten beams having particles; shooting the at least ten beams toward a programmable filtration system having a splitter material; filtering the at least ten beams through the splitter material such that the at least two beams of the ten beams are split; depositing the particles into a substrate randomly such that the substrate is saturated with filtered natural quantum entangled particles; exposing the saturated substrate to a correlation system such that each spin of the filtered natural quantum entangled particles are aligned; and snap-releasing the saturated substrate from the correlation system creating concentrated unnatural entangled particles.

2. The method of claim 1 further comprising stimulating the substrate with a stimulation source such that at least one characteristic of the concentrated entangled particles, substrate, or both is changed from its relaxed state.

3. The method of claim 2 further comprising detecting the change in the at least one characteristic by a detection device.

4. The method of claim 1 wherein the concentrated entangled particles are in a slave-x relationship between each other within the saturated substrate and remotely controllable upon release from the correlation system.

5. The method of claim 4 wherein the slave-x relationship between the concentrated entangled particles within the saturated substrate is asynchronous.

6. The method of claim 1 wherein the particles are deposited onto a second substrate.

7. The method of claim 6 wherein the more than one substrates are in a slave-x relationship with each other and remotely controllable upon release from the correlation system.

8. The method of claim 1 wherein the correlation system is selected from a group consisting of entanglement swapping, magnetic field exposure, supercooling and resonance ring exposure.

9. The method of claim 1 wherein the correlation system is magnetic field exposure further coupled with pulsed frequency radio waves.

10. The method of claim 1 wherein the correlation system is magnetic field exposure and at least 90% of the concentrated entangled particles are entangled after release from the correlation system.

11. The method of claim 1 wherein the correlation system is supercooling and at least 90% of the concentrated entangled particles are entangled after release from the correlation system.

12. The method of claim 1 wherein the concentrated entangled particles are organized, physically stable, separated, and positioned throughout the substrate.

13. The method of claim 2 further comprising stimulating inner valence couples of the concentrated entangled particles to produce a release of light not in a frequency of the light spectrum used as a stimulation source.

14. The method of claim 1 where in the substrate is selected from a group consisting of compounds, crystals, atoms, gasses, atomic structures, proteins, enzymes, microchips, liquids, chromogenic complexes, and thermogenic complexes.

15. The method of claim 1 where in the concentrated entangled particles are in pairs, groups of pairs, groups, and clusters.

16. The method of claim 1 further comprising additional exposures to additional correlation systems in sequential order.

17. The method of claim 2 wherein the stimulation source is selected from a group consisting of photonic sources, electromagnetic sources, magnetic course, gravitational sources, and additional quam entangled particle bombardment.

18. The method of claim 2 wherein the at least one characteristic of the concentrated entangled particles is selected from a group consisting of chromatic shifting, particle energy excitation, particle energy relaxation, particle inner valence structure adjustment, particle location shifting, energy transfer between the particles, and band gap in an atomic structure of the substrate, energy release from substrate valence bond relaxation, release of particles from a lattice structure of the substrate, change in the lattice structure of the substrate, and a change in the bond strength of the substrate.

19. The method of claim 1 wherein the concentrated entangled particles survive for a longer duration and have greater resistance to superposition collapse than naturally completely entangled particles.

20. The method of claim 1 wherein the concentrated entangled particles survive for longer duration and have greater resistance to superposition collapse than natural partially entangled quantum particles.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0045] FIG. 1 is a prior art illustration of a split beam filtration system;

[0046] FIG. 2 is a prior art illustration of NMR/MR spin alignment;

[0047] FIG. 3 is a prior art illustration of entanglement swapping;

[0048] FIG. 4 is a prior art illustration of a slave chip system;

[0049] FIG. 5 is a schematic view of a method for concentrated quantum mechanically entangled particle couples;

[0050] FIG. 6 is a schematic view of a method for concentrated quantum mechanically entangled particle couples;

[0051] FIG. 7 is a schematic view of a method for concentrated quantum mechanically entangled particle couples;

[0052] FIG. 8 is a schematic view of a method for concentrated quantum mechanically entangled particle couples;

[0053] FIG. 9 is a schematic view of a method for concentrated quantum mechanically entangled particle couples; and

[0054] FIG. 10 is a schematic view of a system for a method for concentrated quantum mechanically entangled particle couples.

DETAILED DESCRIPTION

[0055] For the purpose of the specification and the claims:

[0056] The term “quantum entanglement” refers to the physical phenomenon which occurs when pairs or groups of particles are generated or interact in ways such that the quantum state of each particle cannot be described independently of the state of the other(s), even when the particles are separated by a large distance, and thus a quantum state must be described for the system as a whole. It is understood that naturally occurring concentrations of quantum entangled particles exist at concentrations that are not commercially viable, separated, or organized into durable, sustainable pairs, beams, groups, or clusters. The present invention is not directed at naturally occurring concentration of quantum entangled particles.

[0057] The term “commercially viable quantum entangled particles” refers to synthetically concentrated quantum entangled particles at a concentration, separation, and organization as a result of the application of the present invention's correlation systems as defined below such that the particles can be stimulated and manipulated on a macro-scale in various industry practices including but not limited to circuitry and biological protein developments.

[0058] The term “entanglement clusters” refers to groups of quantum entangled particles.

[0059] The term “entanglement swapping” refers to the transference of pairs or groups of quantum entangled particles that originate from difference sources and formerly completely independent. The swapping is the transfer of entanglement by collision from one entangled particle to a non-entangled particle, therefore leaving the previously entangled particle no longer entangled as the entanglement has been transferred to the now entangled particle.

[0060] The term “substrate” refers to a medium with which the unnaturally concentrated quantum entangled particles interact with; including but not limited to microchips, compounds, atoms, gasses, liquids, proteins, chromogenic complexes, thermogenic complexes, nuclei, or atomic structure therein.

[0061] The term “correlation” refers to the spin of the particles such that when a correlation system is applied to the particles, any previous concentration of entanglement is overwritten and also such that when the spins of the particles become correlated and then released, remote control capabilities of the pairs or groups of entangled particles is created.

[0062] The term “correlation system” refers to systems methods applied to the particles such that natural entanglement of the particles is overwritten, separated, and organized entangled particles are created and subsequent interaction between the entangled particles and a substrate is created.

[0063] The term “remote control” refers to the ability to manipulate quantum entangled particles or groups of quantum entangled particles while creating the effects in other corresponding quantum entangled particles or groups of quantum entangled particles at any distance.

[0064] The term “super molecule” refers to entanglement of two or more molecules, for example, oxygen in combination with hydrogen.

[0065] The term “slave chip relationship” refers to the depositing of entangled particles in two or more microchips wherein the entangled nature of the embedded particles causes interaction between the microchips such that, even at great spatial distance, when particle embedded in one microchip is stimulated to manipulated, one or more particles are similarly stimulated or manipulated. It is understood that the term could include other substrates that are not microchips and are therefore a “slave-x relationship” wherein x could be any number of substrates or particles.

[0066] With reference to the Figures, the system for concentrated quantum mechanically entangled particle couples and method for making the same 10 includes providing a particle stream within at least one particle beam 12 at step 100. In one embodiment, a pair or groups of particle beams 12 are selectively combined such that particles 16 within the beam or beams 12 correspond to each other from each pair or group of particle beams 12. The entanglement of the particles 16 within the beams 12 is of a natural concentration, separation, and organization and is therefore not commercially viable. At step 102, the beams 12 are shot toward a programmable filtration system 14. At step 104, the beams 12 are filtered through the programmable filtration system 14. At step 106, the beams 12 are split such that entangled particles are separated by splitter 15 material such as a crystal.

[0067] The particles 16 are exposed to a correlation system 18 and released therefrom after exposure at step 108, thus creating commercially viable, concentrated, separated, and organized entangled particles 20 at step 110. Correlation systems 18 may include NMR/MR, supercooling, resonance ring manipulation, ionic material bonding, and entanglement swapping. Correlation systems 18 may be used alone or in tandem with other correlation systems in sequential exposures. In one embodiment, the correlation system 18 is coupled with pulsed frequency radio wave exposure at step 111.

[0068] Commercially viable applications of the particles 20 may include geothermal heating techniques, slave chip relationships, crystal matrix manipulation, and the like. The particles 20 may be pairs, groups of pairs, groups, clusters, or any combination thereof. The particles 20 survive for a duration longer than untreated particles 16 and have greater resistant to superposition collapse than untreated particles 16. In one embodiment, the particles 20 are approximately 90%-99% concentrated such that 90%-99% of all particles 20 are entangled when the correlation system includes NMR/MR or supercooling. In another embodiment, at least 60% of the particles 20 are entangled when entanglement swapping is the selected correlation system 18. It is envisioned that post-correlation system exposure filtration and particle selection may improve these percentages.

[0069] At step 112, the split stream containing the particles 20 is applied to a substrate 22 thus creating a slave-x relationship between the particles 18 and between the substrates 22 at step 114. In one embodiment, the split stream 21 of particles 20 is applied to multiple substrates 22. Applications may include absorption, diffraction, bonding, or reacting thereto. The substrate 22 may include compounds, crystals, atoms, gasses, atomic structures, proteins, enzymes, microchips, liquids, chromogenic complexes, and thermogenic complexes. The particles 20 have entangled states that are long lived, durable and are positioned throughout the substrate 22. In one embodiment, step 104 may be repeated at various times throughout the method 10.

[0070] In one embodiment, at step 116, the substrate 22 is stimulated by a stimulation source 24. The stimulation source 24 may include photonic, physical, electromagnetic, additional quantum entangled particles bombardment, magnetic, gravitational, and other stimulation forces of the like. In one embodiment, the stimulation source 24 is a light spectrum that stimulates inner valence structure couples of the substrate 22 or particles 20 to produce a release of light not in a frequency of the light spectrum used as the stimulation source 24.

[0071] At step 118, at least one characteristic 26 of particles 20 is detectably changed. Alternatively, at step 120, at least one characteristic 26 of the substrate 22 is detectably changed. The at least one characteristic 26 includes at least one change in location of the particles 20, at least one change in excitation of the particles 20. In one embodiment, a combination of detectable changes in the at least one characteristic 26 is generated. Alternatively, a chromatic shift is generated by the stimulation step at 116 and subsequent relaxation of the particles 20 is measurable on a macroscopic level and recorded.

[0072] At step 122, for quality assurance purposes, the detectable change in the at least one characteristic 26 is detected by a detection device 28. The detection device 28 detects the effects of the stimulation process from step 116. These effects include a change in the band gap of the atomic structure of the substrate 22, the release of energy from the valence bonds of the substrate 22 or the particles 20, release of particles 20 from a lattice structure of the substrate 22, a change to a lattice structure of the substrate 22, or a change in the bond strength of the substrate 22.

[0073] At the conclusion of step 112, the particles are remotely controllable. Remotely controllable for commercial purposes includes repeatable instances of control, physical control, synchronous control, asynchronous control, and the like of the particles 20, the substrate 22, or both creating a slave-x relationship. For example, remote control occurs when one particle 20 is manipulated in any desired way, the effect occurs and is observable on the macroscopic level on a corresponding particle 20, which may be within the same substrate 22 or a different substrate 22 placed at a distance from any other substrate 22. Alternatively, when a cluster of particles 20 is manipulated in any desired way, the effect occurs and is observable on the macroscopic level on the corresponding cluster of particles 20, which may be within the same substrate 22 or a different substrate 22 placed at a distance from any other substrate 22.

[0074] Alternatively, the method 10 includes providing a particle stream 12 within at least one particle beam at step 200. In one embodiment, a pair or groups of particle beams 12 are selectively combined such that particles 16 within the beam or beams correspond to each other from each pair or group of particle beams 12. The entanglement of particles 16 within the beams 12 is of a natural concentration, separation and organization and is therefore not commercially viable. At step 202, the beams 12 are exposed to a resonance ring thereby splitting the beams 12. At step 204, entanglements of the particles 16 are swapped via an entanglement swapping correlation system 18. The resultant spin-aligned particles 20 are then released from the ring and correlation system creating commercially viable, concentrated, separated, and organized entangled particles 18 occurs at step 206. At step 208, the split beams 12 containing the particles 20 is applied to a substrate 22. In one embodiment, at the conclusion of step 204, the particles 20 are swapped directly into a nucleus or atomic structure of the substrate 22 thereby creating a slave-x relationship between the particles 10, substrates 22, or both. In one embodiment, the stream of particles 20 is applied to multiple substrates 22. In one embodiment, step 202 may be repeated at various times throughout the method 10. Thereafter, steps 116-122 may be performed.

[0075] In an alternative embodiment, the method 10 includes providing a particle stream within at least one particle beam 12 at step 300. In one embodiment, a pair or groups of particle beams 12 are selectively combined such that particles 16 within the beam or beams 12 correspond to each other from each pair or group of particle beams 12. The entanglement of the particles 16 within the beams 12 is of a natural concentration, separation and organization and is therefore not commercially viable. At step 302, the beams 12 are shot toward a programmable filtration system 14. At step 304, the beams 12 are filtered through the programmable filtration system 14. At step 306, the beams 12 are split such that entangled particles 16 are separated. The creation of commercially viable, concentrated, separated, and organized entangled particles 20 occurs at step 308 via exposing the particles 16 to a correlation system 18. The beams 12 now containing the entangled, commercially viable, separated and organized particles 20 is applied to a material 30 at step 310. The material 30 may be ionic and in need of an electron which would therefore require the stream of the particles 20 in the beam 12 to be electrons. In one embodiment, the stream of particles 20 is applied to multiple materials 30. In one embodiment, step 304 may be repeated at various times throughout the method 10. Thereafter, steps 116-122 may be performed.

[0076] Alternatively, the inventive method 10 includes providing a particle stream within at least one particle beam 12 at step 400. In one embodiment, a pair or groups of particle beams 12 are selectively combined such that particles 16 within the beam or beams 12 correspond to each other from each pair or group of particle beams 12. The entanglement of the particles 16 within the beams is of a natural concentration, separation and organization and is therefore not commercially viable. Step 402 includes providing a substrate 22 containing particles 16. In one embodiment, the substrate 22 is chemically doped microchips. In one embodiment, the chemical doping is achieved with thermoluminescent chemical application. In an alternative embodiment, the chemical doping is achieved with photoluminescent chemical application. At step 404, the substrate 22 is placed within a chamber 32. At step 406, the chamber 32 generates cooling of the substrate 22 to a supercooling degree. Supercooling may be achieved by using standing wave technology. Alternatively, at step 408, the chamber 32 generates a magnetic field. In one embodiment, the magnetic field is a nuclear magnetic resonance (NMR) field. At step 410, a pulsed radio frequency stream is applied to the chamber 32. The alignment of spins of the particles 16 occurs at step 412. At step 414, the substrate is released from either the supercooled stated applied at step 406 or the magnetic field generated at step 406 creating commercially viable, concentrated, separated, and organized entangled particles 20 having a slave-x relationship with each other at step 416. In one embodiment both supercooling and a magnetic field are generated by the chamber 32. Thereafter steps 116-122 may be performed.

[0077] In operation, and by way of example to further illustrate the commercial application, detectable change, and detection portion of the process in a specific setting subject to and without waiving the above embodiments, at step 500, the particles 16 are embedded in a selected substrate 22 a corresponding second substrate 22 which includes two small disks 34 doped with AL.sub.2O.sub.3:C. At step 502, the substrates 22 are subjected to a correlation system 18 having a magnetic field. At step 504, while positioned within the correlation system 18, the spins of the particle atoms 16 are aligned in the same direction thus creating a high concentration of entangled particles 18 within the substrates 22 at step 506. The particles 18 are released from the correlation system 18 thus creating a slave-x relationship between the particles 20 and between the disks 34. At step 508, the disks 34 are separated a distance from each other. In one embodiment, the disks 34 are fitted with an LED 36 which creates a detectable light output having, for example, a green light for “on” or one and a red like for “off” or zero. The disks 34 may then be stimulated at step 510 to exchange thermal gradients, magnetic fields, movement, or an adjustment of internal valance structures and the like. At step 512, light is refracted off of the disks 34, filtered through a programmable filtration device 14, and read through a photomultiplier. A shift in valence structure due to the entanglement state between the particles 18 and the disks 34 causes the LED 36 to be in the spectrum of the LED diode and thus read as a 1 or green. Alternatively, in a relaxed state and not stimulated, the light refracted is in the red spectrum, or zero.

[0078] From the above discussion and accompanying figures and claims it will be appreciated that the concentrated quantum mechanically entangled particle couples and method for making the same offer many advantages over the prior art. It will be appreciated further by those skilled in the art that other various modifications could be made to the device without parting from the spirit and scope of this invention. For example, the additional methods of particle entanglement and particle stimulation as well as substrates extending beyond microchips are anticipated. It should be understood that the method may include different detection devices. All such modifications and changes fall within the scope of the claims and are intended to be covered thereby. It should be understood that the examples and embodiments described herein are for illustrative purposes only and that various modifications or changes in the light thereof will be suggested to persons skilled in the art and are to be included in the spirit and purview of this application.