Particles That Refuse To Obey The Laws Of Physics

Are there any particles that refuse to obey the laws of physics? To our knowledge, no particles that have been detected thus far obey all of Newton’s laws, though many come close. None of the known elementary particles has a charge of zero. The only thing in the universe that resists this law is the particle known as the “Boson.” It’s said that Bosons can exist in two places at once.

Using this fact with a little creativity and inspiration, our latest crossword puzzle lets you in on some fun facts about these terrific particles. Particles that refuse to obey the laws of physics are a very interesting topic, though it can be tricky if you don’t know much about the matter.

Which Particles That Refuse To Obey The Laws Of Physics?

Source: Cognito

A particle is a small piece of matter, such as an atom or molecule. Here are some particles that refuse to obey the laws of physics:


This particle has a very small mass and is extremely difficult to detect. The neutrino has been observed only in the context of nuclear reactions, but it can also be produced by cosmic rays hitting the atmosphere. Neutrinos come in three flavors, or types: electron neutrinos, muon neutrinos and tau neutrinos.

Top quarks

The top quark is the heaviest particle ever discovered. It’s also one of the strangest. Unlike other quarks, it has a very short lifespan, lasting only about 10-23 seconds before decaying into other particles. Top quarks are made in collisions between two protons at the Large Hadron Collider (LHC). These collisions produce a huge number of new particles that travel outwards from the collision point in all directions. The LHC’s detector is designed to spot these particles and measure their properties.


A muon is a subatomic particle with a mass similar to an electron. Muons can be created when cosmic rays hit the Earth’s atmosphere. They are heavier than electrons and decay quickly into other subatomic particles. The term “muon” comes from the Greek word “mu,” meaning “mulberry,” which was chosen because when muons were discovered in 1937, they were thought to be related to electrons (or “electron-like”).


A tauon is a subatomic particle with a mass similar to a proton but with no electric charge. It decays into another particle called a pion (which has no charge either). The term “tauon” comes from the Greek letter “tau” because when it was discovered in 1975, it was thought to be related to protons (or “proton-like”).


The electron is a subatomic particle, symbol e or 𝜈, whose electric charge is -1.6×10 coulombs, which is exactly equal to the elementary charge on an electron. The negatively charged electron has an extremely small mass and a large radius. Quantum theory requires electrons to be described as wave-like or particle-like.


This particle is thought to carry the force of gravity, and it’s believed it has no mass. If a graviton were created in a laboratory, it would instantly disappear into an unknown dimension. No one knows what this means yet because we don’t know enough about gravity.


Photons are the building blocks of light. They’re massless, chargeless, and travel at the speed of light. They’re also the most common particles in the universe and can be found anywhere from stars to planets, even in your own body. However, photons are also incredibly difficult to study because they don’t interact with other particles. This means they don’t feel any force or experience any acceleration, making them difficult to detect and measure.

W bosons

Source: Forbes

The W boson is one of the particles that do not obey the laws of physics. This is a particle that acts as a messenger between the two types of quarks: up and down. The W boson can be considered a carrier for the electric charge. They are so weird that even their discovery was a bit mysterious: the first time scientists saw them, they thought they were seeing something else entirely. Until someone realized what was going on during a routine check of equipment settings.

Higgs bosons

Higgs bosons are the elementary particles that give mass to other particles. These particles, theorized by British physicist Peter Higgs and others in 1964, have been detected at CERN, the European Organization for Nuclear Research. But the Higgs boson is more than just a subatomic particle: It may be the key to understanding how the universe works.


Tachyons are theoretical particles that travel faster than the light speed. Which is impossible according to Einstein’s theory of special relativity. They escape from black holes before collapsing and have been observed traveling through space at speeds greater than 186,000 miles per second.

Final Words

In the end, we discovered that many particles Refuse To Obey The Laws Of Physics. Moreover, we can’t even fully explain how they get their mass and energy. The more we understand the universe and how particles behave, the more we realize that the universe is bigger than what our senses register, and what we can physically sense may not even exist at all.

Leave a comment

Your email address will not be published.