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The connection is so total that a person can literally walk into another place and time. Does any of this seem outlandish or too far-out to be real? While quantum jumping may at first sound like an idea from science fiction, this term actually covers a wide range of experiences from the rather mundane to the truly extraordinary. Visualize another example of a man preparing for an interview by dressing for success…in attire worn by those making the hiring decisions.
Free Enlightened Living Course: We are capable of taking hundreds of quantum leaps in any given day, making decisions that seem inconsequential or small at the time, yet have the collective power to entirely transform our lives. In most cases, people experience walking into parallel worlds that are nearly—but not quite entirely—identical to the one they came from.
In such cases, it is possible to find something has seemingly shifted in some startling way. These types of quantum jumping reality shifts are remarkably commonplace; yet, unless we pay attention to them, they often go unnoticed and unannounced.
Consider the idea that many times—possibly even every time—you make a decision or choice, you are actually moving between alternate realities, between parallel worlds. When feeling so strongly connected to another self in a different reality, it is possible to gain direct access to the knowledge available only in that time and space and to experience an entirely different self. What makes quantum jumping possible is that, like a quantum particle, every person has the ability to exhibit quantum behavior.
While it may seem extremely improbable that you can do the things quantum particles do—such as tunnel through solid barriers, or make quantum jumps to other alternate times and places—our current understanding of physics suggests such things are within the realm of possibility and can be expected to occur. Experimental observations at the quantum level change our assumptions about reality as we see that: In order to explain some of this truly strange quantum behavior, Niels Bohr theorized that quantum particles exist as waves that might be anywhere until the wave function is collapsed.
Hugh Everett III theorized that we exist in a multiverse consisting of many worlds of parallel realities. Physicist John Cramer theorizes it is possible for information to be exchanged between past and future through a kind of handshake between two points in space-time. Scientists David Bohm and Karl Pribram proposed the universe is a giant hologram, containing matter and consciousness in a single field. What all this means to someone experiencing a quantum jump is that they can enter another parallel reality by relaxing and imagining they are accessing some kind of bridge, window, or doorway to another world with another self who has another set of characteristics, qualities, or skills.
With quantum jumping, one makes the leap from simply imagining oneself in an alternate reality to actually being that other self. Our perception of our world in this new Quantum Age is about to undergo something on par with the Copernican Revolution. In the Copernican Revolution of the sixteenth century, most people worldwide changed their mental model of our solar system from envisioning the sun and planets revolving around the Earth to realizing the Earth revolves around the sun.
This changing worldview depends on scientific observations of quantum behavior on the macroscopic scale of physical objects we can readily observe with our ordinary senses. Such aspects of quantum weirdness that affect and are foundational to our ability to make quantum jumps include: You can learn more and signup for the free masterclass he is offering here: Possibilities become actualities with each measurement that is made, and infinite slightly different realities come into existence as each quantum event is observed.
All possibilities are equally real in the multiverse. Parallel universes coexist side-by-side, undetected by one another, which is critical to understand if you are interested in mastering the art of quantum jumping. University of London physicist David Bohm and Stanford University neurophysiologist Karl Pribram proposed that the universe may be like a giant hologram, containing both matter and consciousness as a single field. The Copenhagen Interpretation of quantum physics was first described and presented by Niels Bohr in Italy in Bohr suggested that quantum particles exist as waves, which might be anywhere until the wave function is collapsed.
As long as nobody looks, each quantum particle is equally distributed in a series of overlapping probability waves, in a superposition of states. An observer is required to assist in ensuring quantum choices are made. All the physics of the multiverse is encoded upon the boundary in time of the surrounding superstructure, where time is set to infinity. Observers are aware of their own slices of reality in space and time within their respective universes. I love the idea that quantum theories can be combined to create imaginative new interpretations in much the same way that chefs create exotically delicious concoctions such as Thai-flavored Mexican burritos!
The Holographic Multiverse Interpretation, for example, is a combination of the Holographic Interpretation with the Many Worlds Interpretation that provides a more holistic, integrated version of many possible worlds. Within a holographic multiverse, there is an interconnectedness between each part of any given parallel universe and all other possible parallel worlds within that holographic multiverse. When the Holographic Multiverse Interpretation is combined with the Transactional Interpretation, we gain an extraordinary view of reality that can truly broaden our minds and allows for the experience of quantum jumping.
The Transactional Interpretation involves absorption and emission of waves, with perfect symmetry occurring between emitted and absorbed waves. In essence, what is happening is a synchronized behind-the-scenes choreography in which one point in space-time communicates with another in something akin to a handshake. When you realize that some information is moving forward in time and some backwards through time, there is equal significance to receiving information as there is to sending it—both are equally active and involved.
Professional athletes take advantage of this phenomenon by practicing visualization of perfect performance in order to get the best results. The fundamental principles behind quantum jumping are based upon the behavior of these very smallest particles known in physics—quantum particles. There is a superposition of states in the time of dematerialization in which a quantum particle is between states and is behaving like pure energy rather than like a particular piece of matter.
Just as electrons can make energetic leaps from one energetic level to another, people can quantum jump through alternate realities to experience dramatic shifts in physical reality. Quantum jumps can be envisioned as occurring in a multiverse of many alternate realities. Anyone who can relax, clear their mind, and envision being different in some way—such as more successful, funny, healthy, wealthy, or wise—can quantum jump. To initiate a quantum jump requires keeping an open mind that you can experience another reality.
It is important that you are able to sincerely desire and feel a connection to another reality, envisioning some way of making a connection with it through a bridge, a door, a window or a handshake. Your ability to form a strong intention, to concentrate, and to get and stay focused while feeling detached from concerns of daily life—relaxed, open-minded, and emotionally energized—are essential. Just as when you shift gears on your can you must first disengage from one gear before re-engaging in a new gear, you must attain a mindset of detachment in order to release connections to physical realities you have felt locked into with your thoughts and feelings.
In such a state of pure consciousness, you become aware that you are capable of sensing all possible realities, and you realize that you can emerge from this meditation or lucid dream into the best possible reality for you. If you can walk, you can dance—and you can quantum jump. Your body is designed for quantum jumping, so learning how to improve your skills can be every bit as simple as making the transition from walking to dancing.
Well, as you might have suspected, sometimes there can be a little more to it than that. Wells said in the movie The Time Machine ,. Those that take us back are memories… and those that carry us forward are dreams. What if we could get help to stay balanced and take our first steps in a new direction when we need it?
Because it makes the study of quantum jumps so much easier. This very special section of the 87th annual meeting of the Pacific Division of the American Association for the Advancement of Science AAAS was convened for the purpose of examining the nature of time … and causality. Quantum mechanics is like poetry. The poem is right there, for everyone to see, but it has many different interpretations.
While growing numbers of studies in the field of parapsychology, such as those by UC Berkeley physicist Henry Stapp, indicate experimental participants are able to influence radioactive decay of isotopes in the past, few mainstream research laboratories are repeating these experiments, proving that mind does indeed affect matter and therefore is an important part of the process of quantum jumping. Most mainstream labs shy away for fear of sullying their reputations, as if they would be dirtying their hands by even imagining some of this is possible.
Who are our quantum jumping experts? In his theory, Poirier postulates that small particles from many worlds seep through to interact with our own, and their interaction accounts for the strange phenomena of quantum mechanics. Such phenomena include particles that seem to be in more than one place at a time, or to communicate with each other over great distances without explanations.
There is no fuzziness in his theory. Particles do occupy well-defined positions in any given world. However, these positions vary from world to world, explaining why they appear to be in several places at once. Likewise, quantum communication of faraway particles — something Albert Einstein called "spooky action at a distance" — is actually due to interaction of nearby worlds.
Many Interacting Worlds theory doesn't prove that the quantum wave does not exist, or that many worlds do exist, Poirier said. The standard wave theory is perfectly fine in most respects, providing agreement with experiment, for example. It now has only as much right to that claim as do many interacting worlds — no more and no less. This may be as definitive a statement as one can hope to make about a subject that has confounded the best minds of physics for a hundred years and still continues to generate controversy. At this nanoscopic scale, particles don't act like larger objects, whose position over time is well defined, such as an airplane or an apple falling from a tree.
Instead, particles sometimes behave as fixed particles, and other times behave more like waves. Even weirder than this: When they're not looking, it suddenly starts acting like a wave. Even Albert Einstein is said to have disagreed with the quantum idea that particles could exist in an approximate possible location or possibly more than one location at a time rather than just one place. Scientists dissect and disagree to this day as to exactly what's happening on this tiny scale. Although they may not know for sure what's happening, they do at least know how to predict the wave-like behavior of the quantum particle when it's not being observed.
At least, they did until Poirier took another look at the wave and upended established quantum theory. Some physicists can make much about the philosophy of quantum mechanics, Poirier said. To answer these kinds of questions accurately requires quantum mechanics, but solving quantum mechanics problems for large systems more than three bodies is extraordinarily difficult. Chemists use traditional grid-based methods for solving the quantum wave equation. However, the more complex the molecule, the more complex the computations become.
With each atom added to the molecule, about 10, times more additional computational effort is needed, he said. To ease the computational burden, chemists borrowed an idea from engineers to allow the grid points to move like a liquid and "flow" with the quantum wave. Once moving, the grid points trace out trajectories, much like a baseball.
While engineers use the technique to model fluid flow, chemists use it to help calculate the motion of the quantum wave —hence the term 'quantum hydrodynamics. At a certain point, Poirier wondered what would happen if you left the wave computations out and just worked with the quantum trajectories and if the simpler numerical simulation still would be valid. The trajectories tell themselves how to move. Moreover, you don't need the wave for anything else either. Any scientific question that might be answered by knowing the motion of the wave can also be answered just as easily by knowing the motion of the trajectories alone.
So the wave becomes completely extraneous and can be discarded altogether. The concept of many quantum worlds isn't quite new. In the '50s, a graduate student at Princeton University named Hugh Everett III had a similar explanation to account for the strangeness of quantum mechanics. Poirier said Everett Many Worlds theory is based on the standard quantum wave mathematics, so it is not clear where the worlds actually come from or how they're defined.
Critics disagree with the theory for this reason and because the universes fork into countless more each time scientists, say, take a measurement. In Poirier's Many Interacting Worlds approach, these worlds are built into the mathematics right from the start, so scientists don't have to do anything special to define them. It works, he said, because wave-based mathematics aren't used. Worlds never fork or merge the way Everett's worlds do, and Poirier's worlds interact with each other. Poirier compared figuring out quantum mechanics without the wave function to putting up scaffolding, building a structure inside and then realizing you just needed the scaffolding.
From a practical point of view, fewer mathematical moving parts mean greater simplicity. It also posed interesting questions about the physics philosophy on the wave and what it means if you don't need it, he said. Quantum trajectories may be more than just a computational tool. They actually may explain what is going on at the quantum level. The more fundamental question should be, 'Does the wave function even exist, and if not, what takes its place? Only that its existence is not necessary, because we've found another mathematical method that provides all the same information.
So, what does this new mathematics have to say about what takes the place of the wave function? What emerges from the math are parallel universes.
Poirier explained that in the classical physical world where humans operate, everything is in a definite state with respect to velocity and position. Think airplanes and apples falling out of trees. We can calculate where those things are and where they're going.
In quantum mechanics, scientists have to give that up. They can know where particles are or where they're going. The classical trajectory, with its well-defined particle attributes, has been replaced with the quantum probability wave that spreads out across many simultaneous possibilities.
However, by describing quantum realities using quantum trajectories alone, at least some of the old classical notions can be restored, Poirier said. According to this picture, quantum particles really do have well-defined attributes and follow definite quantum trajectories. The catch is that one has to have many interacting worlds. In fact, quantum behavior itself may be regarded as evidence of definite particles from alternate universes poking through into our own, causing this blurry picture at the quantum scale.
The only sensible interpretation is to think of each trajectory as representing a different world. In each world, nothing is wave-like or indefinite. Everything is sharp and well-defined. But there are now multiple worlds. The variation across these worlds is where quantum uncertainty or 'fuzziness,' together with all other quantum behavior, actually comes from. The apparent fuzziness of particle positions may be regarded as a manifestation of an inter-world interaction. Poirier says that while the wave equation still works, scientists can no longer say that it more naturally explains what's going on at the quantum scale than the idea of many alternate universes interacting together at the quantum scale.
Both are equally valid ways of interpreting reality that are consistent with current experiments. As for describing what might be happening right now in other parallel universes, Poirier said that would be pure speculation. According to the theory, the only worlds we can directly interact with are so close to our own world that we hardly can tell them apart, except at the quantum scale.
So that might be a little bit boring for people who like to think in terms of science fiction. On the other hand, that doesn't rule out the possibility that there are indeed more distant worlds macroscopically different from our own where you and I are living out any number of counterfactual existences.
We don't have any direct evidence for that. But then again, nor should we, according to the theory, even if such worlds do exist. Many Interacting Worlds theory: Scientists propose existence and interaction of parallel worlds. Griffith University academics are challenging the foundations of quantum science with a radical new theory based on the existence of, and interactions between, parallel universes.
An experiment devised in Griffith University's Centre for Quantum Dynamics has for the first time demonstrated Albert Einstein's original conception of "spooky action at a distance" using a single particle. Parallel universes — worlds where the dinosaur-killing asteroid never hit, or where Australia was colonised by the Portuguese — are a staple of science fiction. But are they real?
The bizarre nature of reality as laid out by quantum theory has survived another test, with scientists performing a famous experiment and proving that reality does not exist until it is measured. A collaboration of physicists and a mathematician has made a significant step toward unifying general relativity and quantum mechanics by explaining how spacetime emerges from quantum entanglement in a more fundamental theory.
Quantum mechanics is often described as "weird" and "strange" because it abandons many of the intuitive traits of classical physics. For example, the ideas that the world is objective, is deterministic, and exists independent Single-photon avalanche diodes SPADs are promising detector technologies that may be used to achieve active 3D imaging systems with fast acquisition, high timing accuracy and high detection sensitivity.
A team of researchers from Austria, Italy and Sweden has successfully demonstrated teleportation using on-demand photons from quantum dots. In their paper published in the journal Science Advances, the group explains how Scientists have long known that synthetic materials—called metamaterials—can manipulate electromagnetic waves such as visible light to make them behave in ways that cannot be found in nature. That has led to breakthroughs Interactions with water dominate how drug molecules bind to targets, but it's tricky to model these interactions, limiting the accuracy of drug design.
Pedestrians are constantly avoiding collisions with oncoming people. Meters in advance they unconsciously change their walkway to pass each other. Physicists at Eindhoven University of Technology in collaboration with American Advances in the technology of material growth allow fabricating sandwiches of materials with atomic precision. The interface between the two materials can sometimes exhibit physical phenomena which do not exist in both parent Please sign in to add a comment.
Registration is free, and takes less than a minute. Scientists propose existence and interaction of parallel worlds October 30, Griffith University academics are challenging the foundations of quantum science with a radical new theory based on the existence of, and interactions between, parallel universes. Sub-picosecond photon-efficient imaging using single-photon sensors December 17, Single-photon avalanche diodes SPADs are promising detector technologies that may be used to achieve active 3D imaging systems with fast acquisition, high timing accuracy and high detection sensitivity.
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The metaphysical fuss over whether particles are "real" or not before being "observed", what mystery mechanism "collapses" "probability waves", and most other sketchy concepts none of these concepts have a concrete mathematical or scientific definition used to interpret quantum mechanics go away if the equations are simply interpreted as they stand, which is that many versions of each particle interact. There is no action at a distance if two electrons with opposite spin are sent in two directions. Instead of the measured spin of one being magically determining the spin of the opposite electron, there were two elections shot in each direction with each in the same universe as the opposite election with the opposite spin.
When you measure one electron you are not suddenly have an effect on the other, you are simply finding out which pair of electrons are in your universe. Chaining the interaction, your measurement actually involves two versions of you, one in the universe with one pair of elections, the other in the universe with the other pair. The mystical wave probabilities go away and become normal probabilities. The mysterious mechanism for "wave collapse" is gone. The only disadvantage in the straightforward interpretation of QM equations is the implication that the universe does not consist of a single chain of events, but of many versions interacting.
But the idea of a universe that is not a unique chain of events is as likely to go away as all the other illusions based on the natural but flawed idea that what our senses directly "see" is all there is: Earth as the center of the solar system, life as having some special force, our galaxy being unique, time as having one perspective, etc. So is there any conceivable experiment that could help decide which interpretation is more likely?
Even if not, from a layman's perspective at least, the many worlds interpretation seems more intuitive. If truly these interpretations are on equal footing then I would suggest the many worlds idea should get more attention than it has so far. I've heard this particular version of the idea does not require the continuous creation of new universes.
But how could this be avoided if, due to chaos, even very close universes diverge eventually? I don't see how the properties of quantum mechanics could stay constant. The language used implies that they are not "Many worlds" at all, but just hidden facets of our own, or hidden dimensions of our own world. This language paradox confuses the issue.
If one tries to force a physical theory to say more than it can, they will enter directly into metaphysics. The most rational literally interpretation of the 'strangeness' of QM, is an epistemological one, The metaphysical fuss [ That the many worlds notion IS metaphysics, If not taken literally but rather as simply a mathematical procedure, then it is redundant, and only gets rid of wave-function collapse at the expense of adding more questions. There is no observable basis for thinking the wavefunction represents a physical wave, therefore the added procedure, over and above the Scrodinger equation, of collapse, is a non-problem as it can be attributed to projecting the underlying reality into the conceptual framework hilbert basis implied by the experimental arrangement.
But metaphysical statements sells books better. It IS what was done in the Copenhagen Interpretation. Everette, drunk on 'a slosh of cherry', added a layer of metaphysics to the equations purely on the basis of not being 'intuitively satisfied' with the 'explanation' given by QM. The Bohm pilot wave, also adds another layer, a unobservable physical wave. The error is in expecting an 'intuitive explanation' of independent reality at the QM scale.
Your statement is absurd because it ignores the obvious elephant in the room,, Your def of the metaphysical nether realm says that NO info can be gleaned from it. Of course you will provide a big bowl of spaghetti to try to prove that this is factually incorrect or similar but otherwise different. That, statements about other universes, requires an extra layer of interpretation of the theory.
Mathematically and experimentally the various interpretations all predict the same results. The above article even admits this fact. Our theory, though based on different mathematics, makes exactly the same experimental predictions". You say That the many worlds notion IS metaphysics -but the article says "The apparent fuzziness of particle positions may be regarded as a manifestation of an inter-world interaction" -Lots of things we can discern from THIS specific theory about these other worlds.
Through experiment we can understand how other-worldly particles affect particles in this world, for one. We can also discern that these other worlds exist, something you cant do with your version of metaphysics. This is info transfer.
Oh, boy, Noum versus "otto". A zealot against a nothing. Or is it "Bring 'em on! Lots of things we can discern from THIS specific theory about these other worlds.
In a parallel universe, this theory would make sense . help us protect independent journalism at a time when factual, trustworthy reporting is. consciously undertaking the process and art of quantum jumping allows us to shift our reality in A quantum jump can be made through a kind of handshake through time and In most cases, people experience walking into parallel worlds that are .. To initiate a quantum jump requires keeping an open mind that you can.
We can also discern that these other worlds exist, By it's very nature "other worlds" are unobservable and thus are metaphysical. There has never been an QM experiment or otherwise that has demonstrated that 'other worlds' exist, If there was a quantifiable physical effect in reach of experiment, then de facto, it would be of THIS universe. I don't propose metaphysics, quite the opposite. By it's very nature "other worlds" are unobservable and thus are metaphysical As usual you didnt read the article and you didnt read my post.
The theory in the article describes ways in which these other worlds interact with this one. We can study these interactions and begin to understand what these other universes are about. We dont have direct evidence YET because the theory is in its infancy and hasnt been explored experimentally. But it predicts interactions and thus we can know things about these other worlds. You are still stuck on older theories which reinforce your lyrical views of reality.
Time to update your paradigm, if thats possible. Strange behavior of quantum particles may indicate the existence of other parallel universes It only suggests the standard theory's explanation and interpretation are critically wrong. But what else would you expect from pseudoscientific metaphysical mumbo jumbo? If you kidnap your other self's son, like Walter Bishop, and raise him as your own it is still a crime.