Sustained, High-Fidelity Quantum Teleportation Achieved for the First Time

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The quantum teleportation of a qubit is achieved using quantum entanglement, in which two or more particles are inextricably linked to each other. Sciencedaily.com

Mainstream science still has no coherent model as to why entangled particles ought to be reflexively connected at any distance, or why any force ought to act at a distance for that matter. Cutting to the chase, the term "force" is a useful but antiquated way of describing how the universe "calculates" or else "simulates" its internal (intrinsic) values, a process with intrinsically includes observer participation.

The conspansion diagram from the CTMU theory by Chris Langan coherently describes why quantum teleporation ought to exist at all, without violating any laws of physics...

https://pic8.co/sh/hqNosT.png

Modeling cause over effect, with a reflexive "feedback" holding between the two, yields a sensible interpretation of quantum physics, without altering existing theories (ie, gravity, relativity) , but rather unifying them in the process. Conspansion is the inversion of an "expanding" system, and is already unwittingly observed by science as "quantum collapse". The conspansion diagram is formed via the 90-degree rotation of a Minkowski Space-Time (light cone) diagram.

In conspansive modeling, each quantum state is diagrammed as a "collapse", as per the dot in the center of the circle in the above diagram. In turn, each dot becomes the next circle in an inherently step-wise quantum process. The conspansion process is the inversion of an "expanding" universe, namely a static system with "contracting" or "collapsing" content.

Per the conspansion diagram, where states are "entangled", they amount to overlapping circles which haven't yet "collapsed" into their next state (dot), the eventual collapse happening only upon "observation". Regarding observation, any generic quantum interaction amounts to an "observation", or observation-level event, meaning it's something which could be observed scientifically or otherwise, in principle. Any interaction between particles yields photons or other particles, forming the basis for any observations, scientific or otherwise, and hence any such interaction can be regarded as an "observation" level event. Observation is also synonymous with measurement for purposes of analysis.

Where cause is modeled over effect, when one entangled particle is observed, its new "value" reflexively becomes part of the overlying "cause" (circle) simultaneously assigning value to both entangled particles. The value of the other particle is reflexively assigned because neither had collapsed in the first place, meaning neither were "separate" prior to observation, however it may appear. Note that separation of entangled particles is never directly observed and only implied, as any such observation would disentangle the system.The particles were never separated until the observation/collapse of one, at which the collapse of one simultaneously collapses the other.

Since quantum-level state transitions are the smallest possible scale of state-transition, the conspansive matrix" implied by the conspansion diagram model is the finest possible detail regarding the "history" of the universe, offering a sensible model for causality and origin where conventional "expanding universe" or "field" theories of physics are wanting, while also sensibly re interpreted these theories under a unified model.

Conspansion, along with other principles outlined in the CTMU, unifies QM & GR (Relativity), and these with Biology and Psychology, yielding a truly universal Theory of Everything (ToE).

Because quantum-scale objects are seen to exist only when they are participating in observational events, ... their worldlines are merely assumed to exist between events and are in fact syntactically retrodicted, along with the continuum, from the last events in which they are known to have participated. This makes it possible to omit specific worldlines entirely, replacing them with series of Venn diagrams ... This scenario is general, applying even to macroscopic objects consisting of many particles of matter; the higher definition of the worldlines of macroscopic objects can be imputed to a higher frequency of collapse due to interactive density among their constituent particles. C.M.Langan, CTMU

>*The quantum teleportation of a qubit is achieved using quantum entanglement, in which two or more particles are inextricably linked to each other.* Sciencedaily.com Mainstream science still has no coherent model as to why entangled particles ought to be reflexively connected at any distance, or why any force ought to act at a distance for that matter. Cutting to the chase, the term "force" is a useful but antiquated way of describing how the universe "calculates" or else "simulates" its internal (intrinsic) values, a process with intrinsically includes observer participation. The conspansion diagram from the CTMU theory by Chris Langan coherently describes why quantum teleporation ought to exist at all, without violating any laws of physics... https://pic8.co/sh/hqNosT.png Modeling cause over effect, with a reflexive "feedback" holding between the two, yields a sensible interpretation of quantum physics, without altering existing theories (ie, gravity, relativity) , but rather unifying them in the process. Conspansion is the inversion of an "expanding" system, and is already unwittingly observed by science as "quantum collapse". The conspansion diagram is formed via the 90-degree rotation of a Minkowski Space-Time (light cone) diagram. In conspansive modeling, each quantum state is diagrammed as a "collapse", as per the dot in the center of the circle in the above diagram. In turn, each dot becomes the next circle in an inherently step-wise quantum process. The conspansion process is the inversion of an "expanding" universe, namely a static system with "contracting" or "collapsing" content. Per the conspansion diagram, where states are "entangled", they amount to overlapping circles which haven't yet "collapsed" into their next state (dot), the eventual collapse happening only upon "observation". Regarding observation, any generic quantum interaction amounts to an "observation", or observation-level event, meaning it's something which could be observed scientifically or otherwise, in principle. Any interaction between particles yields photons or other particles, forming the basis for any observations, scientific or otherwise, and hence any such interaction can be regarded as an "observation" level event. Observation is also synonymous with measurement for purposes of analysis. Where cause is modeled over effect, when one entangled particle is observed, its new "value" reflexively becomes part of the overlying "cause" (circle) simultaneously assigning value to both entangled particles. The value of the other particle is reflexively assigned because neither had collapsed in the first place, meaning neither were "separate" prior to observation, however it may appear. Note that separation of entangled particles is never directly observed and only implied, as any such observation would disentangle the system.The particles were never separated until the observation/collapse of one, at which the collapse of one simultaneously collapses the other. Since quantum-level state transitions are the smallest possible scale of state-transition, the conspansive matrix" implied by the conspansion diagram model is the finest possible detail regarding the "history" of the universe, offering a sensible model for causality and origin where conventional "expanding universe" or "field" theories of physics are wanting, while also sensibly re interpreted these theories under a unified model. Conspansion, along with other principles outlined in the CTMU, unifies QM & GR (Relativity), and these with Biology and Psychology, yielding a truly universal Theory of Everything (ToE). > *Because quantum-scale objects are seen to exist only when they are participating in observational events, ... their worldlines are merely assumed to exist between events and are in fact syntactically retrodicted, along with the continuum, from the last events in which they are known to have participated. This makes it possible to omit specific worldlines entirely, replacing them with series of Venn diagrams ... This scenario is general, applying even to macroscopic objects consisting of many particles of matter; the higher definition of the worldlines of macroscopic objects can be imputed to a higher frequency of collapse due to interactive density among their constituent particles.* C.M.Langan, CTMU

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