Researchers observed quasiparticles in classical systems.

 Researchers observed quasiparticles in classical systems. 

"Quasiparticles are a concept in physics that describe the collective behavior of a group of particles in a material. They can be thought of as “effective particles” that capture the essential properties of the underlying particles and their interactions. Quasiparticles play a crucial role in understanding the behavior of materials and are commonly used to explain phenomena such as superconductivity, magnetism, and thermodynamics." (ScitechDaily.com/Scientists Observe “Quasiparticles” in Classical Systems for the First Time)

"In physics, quasiparticles and collective excitations are closely related emergent phenomena arising when a microscopically complicated system such as a solid behaves as if it contained different weakly interacting particles in a vacuum". (Wikipedia/quasiparticles). This is the quasiparticle's description in Wikipedia. 

The thing that makes quasiparticles interesting is that material cannot be solid. When we are looking at the wall it seems solid. But if we take enough close look, we can see that there are atoms and electrons. Electrons are orbiting the atom's nucleus in the ball, where is a lot of space. That ball is the quantum field. A similar quantum field surrounds all particles and particle groups. 

And if we take an even closer look we can see that things like protons and neutrons are also full of space. All quarks and gluons are also hovering in their bubbles. Those bubbles are making quarks and gluons hover in their private quantum space. So we can say that material is a series of internal quantum fields where smaller and smaller quantum fields surround smaller and smaller objects. 

That means all particles are actually in a vacuum. Those vacuum balls that are called quantum fields are energy fields that are forming when material sends radiation. So there is the possibility that even quasiparticles can be forming even inside electrons and quarks. In most modern theories, all elementary particles are hollow. They are whisk-looking skyrmion or string-type structures. 

The quasiparticles are the thing that limits the life of the qubit. 

When we are thinking that the particles are whisk-looking structures we can see why the qubit is so hard to control. The data is stored in those strings that are in different energy levels. When the system starts to upload information. 

It just decreases those strings' energy levels one by one. And when two superstrings reach the same energy level and the same frequency they form a superposition. That superposition forms a channel between those superstrings. And that channel is a quasiparticle that destroys information and the qubit's internal structure. 

The problem is that the qubit also delivers energy because its energy level is higher than its space. The energy flow from the strings in the highest energy level is fast and it happens to the qubit's environment but also part of that energy travels to lower-level superstrings. That thing destroys qubit. 

The thing that supports this model is the superposition's ability to store information. The idea is that all superstrings in that structure can load to different energy levels. And then, each of those superstrings can store wave movement or oscillation series. When a quantum computer loads information to the qubit or subatomic particle it just stores data in the superstrings of the whisk-looking structure. The superstrings at the top energy level are locking information of the lower energy superstrings in their quantum field. The fact is that Pauli exclusion principle also affects those superstrings. 

If their energy level along with oscillation frequency in those superstrings is the same the energy flow away from those superstrings pushes them away. That destroys the structure. The superstrings in that structure take superposition or internal superposition with each other in electron or photon (or quark). And then those superstrings just push them away. This superposition forms an electric ark-type phenomenon. That flash is the quasiparticle. 

When that structure called qubit starts to deliver its information at the first the string in the top level will start to deliver the oscillation that is stored in it. In that case, the energy level of the superstring decreases. 

When the energy level decreases the size of the superstring changes. Then it starts to oscillate with the same frequency as the superstring in the lower energy level oscillates. Then the same process will continue until all data is removed. Pauli exclusion principle affects also qubits. And when all those superstrings reach the same energy level and frequency that destroys the qubit. 

https://scitechdaily.com/scientists-observe-quasiparticles-in-classical-systems-for-the-first-time/

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

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