Why are people who work with quantum systems interested in quasiparticles?

  

Why are people who work with quantum systems interested in quasiparticles? 

“Scientists found that adding a once-dismissed particle, the “neglecton,” allows Ising anyons to perform universal quantum computing. What was once seen as mathematical garbage may hold the key to the future of computation. Credit: SciTechDaily.com” (ScitechDaily, Lost Particle Resurfaces As the Key to Universal Quantum Computing)

Neglectons look like photons. Both of them are donut-shaped particles. And that raises a question: could a photon be some kind of skyrmion? More about these topics at the end of this text. 

Quasiparticles are electromagnetic fields and quantum phenomena that act like a “real particle”. There are many types of quasiparticles, and the thing that makes them interesting in quantum computing is that those particles are extremely rare. Quasiparticles don’t exist for a long time. And there are no long-term versions of those things. That means the wave movement that comes from other particles doesn’t disturb quasiparticles as it does other particles. Because quasiparticles are so-called unique particles, they can create quantum entanglement without causing quantum noise. 

Same way. When a quasiparticle sends a wave movement, that wave movement causes resonance in a similar way to a receiving quasiparticle. And because there are no other particles that send wave movement with a similar wavelength as those quasiparticles, that thing makes it easier to transmit information. In other particles. Like quarks or fermions, the wave movement that reflects from other similar particles can disturb the data transmission. 

Anyons and neglectons are the most interesting quasiparticles from the point of view of quantum computing. 

“In physics, an anyon is a type of quasiparticle so far observed only in two-dimensional systems. In three-dimensional systems, only two kinds of elementary particles are seen: fermions and bosons. Anyons have statistical properties intermediate between fermions and bosons. In general, the operation of exchanging two identical particles, although it may cause a global phase shift, cannot affect observables. Anyons are generally classified as abelian or non-abelian. Abelian anyons, detected by two experiments in 2020, play a major role in the fractional quantum Hall effect.” Wikipedia, Anyons)

Sometimes, frozen anyons are introduced as a solution for quantum entanglement problems in quantum computing. 

“Among the leading candidates for building such a computer are Ising anyons, which are already being intensely investigated in condensed matter labs due to their potential realization in exotic systems like the fractional quantum Hall state and topological superconductors,” said Aaron Lauda, professor of mathematics, physics and astronomy at the USC Dornsife College of Letters, Arts and Sciences and the study’s senior author.”(ScitechDaily, Lost Particle Resurfaces As the Key to Universal Quantum Computing)

“On their own, Ising anyons can’t perform all the operations needed for a general-purpose quantum computer. The computations they support rely on ‘braiding,’ physically moving anyons around one another to carry out quantum logic. For Ising anyons, this braiding only enables a limited set of operations known as Clifford gates, which fall short of the full power required for universal quantum computing.” (ScitechDaily, Lost Particle Resurfaces As the Key to Universal Quantum Computing)

Neglectons are the previously overlooked quasiparticles. Those quasiparticles look like a donut, and that makes them essential for data transmission in the quantum computer. The neglecton can spin ahead of the data transmitter. And if the system can spin it, that allows the laser to send information to that particle. Ot the laser beam, or information carrier that travels through those neglectons. And that thing acts as a quantum gate where information can travel between two superpositioned and entangled neglecton particles that are positioned into graphene or some other 2D structures. Which turns bits  into qubits.

So what if a photon is a skyrmion? 

We can say that the neglecton is something that looks like a skyrmion or photon. The thing that makes frozen anyons problematic is that they can form only in the condensed material. The condensed material means that the particle is in its minimum energy level. That makes energy travel to those particles. And that forms a skyrmion around it. The skyrmion is the impact wave that forms when energy travels to those particles. The neglectons shape causes an idea that maybe the photon is also some kind of skyrmion. So could there be some kind of thing in the middle of the photon that makes the wave movement travel into it. That it make a skyrmion that we know as a photon? 

Skyrmions form around an object when energy jumps back from some structure. And the outside energy interacts with those reflecting waves. That forms a ring-shaped structure around the object. So, if a photon is some kind of skyrmion, that makes this model interesting. 

There are two versions of things. That could make that kind of skyrmion. The first one is the dot-shaped object.  Another one is the stick-shaped object. That means the hypothetical graviton, the hypothetical particle that transmits gravitation, could be in the center of that donut-shaped structure. Or another thing is that. The hypothetical superstring can travel through the photon. Those things are a good explanation for the photon's interesting donut-shaped structure. 

https://www.livescience.com/physics-mathematics/meet-the-neglectons-previously-overlooked-particles-that-could-revolutionize-quantum-computing

https://phys.org/news/2025-08-discarded-particles-dubbed-neglectons-universal.html

https://scitechdaily.com/lost-particle-resurfaces-as-the-key-to-universal-quantum-computing/

https://today.usc.edu/mathematicians-use-neglected-particles-that-could-rescue-quantum-computing/

https://en.wikipedia.org/wiki/Anyon

Does an electron have poles?

 Does an electron have poles? 

The quantum entangled electrons created a quantum magnet or triplon. That quasiparticle caused an idea about the question: Is there some kind of asymmetry in the electron's poles? Electron is a negative particle, which has multiple negative poles. That thing causes spin 1/2 that is common for one, or monopolar fermions. Because an electron has multiple poles that deny its full rotation. 

Artistic illustration depicts magnetic excitations of cobalt-phthalocyanine molecules, where entangled electrons propagate into triplons. Credit: Jose Lado/Aalto University (ScitechDaily.com/Tricky Triplons: Scientists Create Artificial Quantum Magnet With Quasiparticles Made of Entangled Electrons)

"A single point in space can rotate continuously without becoming tangled. Notice that after a 360-degree rotation, the spiral flips between clockwise and counterclockwise orientations. It returns to its original configuration after spinning a full 720°." (Wikipedia/Spin)

The electron's spin.  When an electron wobbles back from the up position it releases the photon.  An electron is a monopolar particle that denies the full spin. It is still possible that the electron has weak electromagnetic  N/S polarity. 

But if we think that there is some kind of asymmetry in the number of those poles, we might think that the electron may have weak double polarity. So in that model electron has N and S poles, but another of those poles is extremely weak. That thing makes it possible to make those quantum magnets. 

Or it explains why those quantum magnets do not fly away because of electromagnetic repel. The question is the quantum magnet form because there are N/S poles in the quantum field that surrounds the electron pair, or is its source in those electrons? However, the asymmetry of the number of the electron's poles on both sides of its wobbling axle makes it possible to connect electrons. 

The triplon forms when there is a weaker point or pothole in the quantum entangled electron pair's quantum field. That pothole pulls the entirety that is two electrons and their quantum field to the point where researchers want to put it. This quasiparticle has multiple uses and it can revolutionize quantum computing and quantum information technology, as I wrote sometimes before. 

https://scitechdaily.com/tricky-triplons-scientists-create-artificial-quantum-magnet-with-quasiparticles-made-of-entangled-electrons/

https://en.wikipedia.org/wiki/Spin_(physics)

How to adjust energy levels in quantum entanglement without breaking superpositioned quantum entanglement?

Low-energy particles can adjust quantum entanglement's energy level in quantum computers. 

The low-energy particles can use to adjust the energy level of quantum entanglement. When the energy level of the quantum entanglement rises high enough the low-energy particle will be used to pull energy away from quantum entanglement when the energy level in that structure rises too high. 

And that helps to keep the energy level in quantum entanglement longer in the right position than without that system. That helps the quantum computer operate longer time without re-adjusting. 

The problem with quantum entanglement is that they remain only for a short time. When the energy level in that structure turns stable the quantum entanglement is destroyed. For making energy flow another side of the quantum entanglement must have a higher energy level. 

One possibility is to shoot low-energy quasiparticles under the side of the quantum entanglement that is rising too high. The idea is that those particles are pulling too much energy out from the quantum entanglement. 

And those particles that are at low energy levels will use to adjust the energy level in quantum entanglement. So in this model, the low-energy particles are shot near the quantum entanglement the energy level is too high. 

How can researchers exchange information between two molecular (extremely complicated) quantum systems? 

Of course, the energy level of another system must be higher. That thing makes information flow between those molecular systems. 

When we are willing to make two or more complex quantum system exchange information we must find something that is the same in both systems. That thing can be quarks or bonds between quarks. 

If we want to exchange information between two molecular structures by using quantum superposition we must realize that the transmitters and receivers of those complex quantum systems must be so big that they can put each other resonate. 

One of the things that are similar in all quantum systems is the bonds between atoms. There is the possibility that by stressing those chemical bonds with electricity the controller can transmit the information between two molecular quantum systems by using superposition and quantum entanglement. 

In that case, the bonds between atoms are offering a good tool for that purpose. The superpositioned things must be so big that the oscillation is. That they send to quantum fields in the molecular structures can be measured. Normally, superpositioned quantum entanglement is possible only between elementary particles. 

Or actually, the energy fields of atoms can be superpositioned. But there is so much turbulence that some other point of the system must put to resonate or resonating atoms must be some extraordinary elements. If the system uses common elements. 

That causes turbulence in the resonance.  The resonance is the key element in quantum entanglement. The superposition means that the elementary particles are oscillating with the same frequency. And they are connected by an energy bridge. 

In most cases, quantum entanglement made by using photons. But in molecular systems that are much larger than individual photons, the chemical bonds are a good thing that can put to superpositioned quantum entanglement. 

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