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- Tachyon - Wikipedia
A tachyon ( ˈ t æ k i ɒ n ) or tachyonic particle is a hypothetical particle that always travels faster than light Physicists posit that faster-than-light particles cannot exist because they are inconsistent with the known laws of physics
- Tachyons: Facts about these faster-than-light particles | Space
What is a tachyon? Tachyons are one of the most interesting elements arising from Einstein’s theory of special relativity
- Tachyon | Faster-Than-Light, Quantum Mechanics, Particles | Britannica
tachyon, hypothetical subatomic particle whose velocity always exceeds that of light The existence of the tachyon, though not experimentally established, appears consistent with the theory of relativity, which was originally thought to apply only to particles traveling at or less than the speed of light
- What is known about tachyons, theoretical particles that travel faster . . .
Tachyons have never been found in experiments as real particles traveling through the vacuum, but we predict theoretically that tachyon-like objects exist as faster-than-light 'quasiparticles
- Physicists suggest tachyons can be reconciled with the special theory . . .
The first: the ground state of the tachyon field was supposed to be unstable, which would mean that such superluminal particles would form "avalanches "
- Do tachyons exist? - Department of Mathematics
Tachyon is the name given to the supposed "fast particle" which would move with v > c Tachyons were first introduced into physics by Gerald Feinberg, in his seminal paper "On the possibility of faster-than-light particles" [Phys Rev 159 , 1089–1105 (1967)]
- This Particle Could Travel Back in Time: What Is a Tachyon?
The tachyon particle has an intriguing time travel component Scientists like Albert Einstein have believed a class of particles could travel faster than light
- If tachyons exist, how might they be detected? | Astronomy. com
To answer your question, we have to ask: What kind of particle might be a tachyon? We also have to guess how tachyons would behave, since all known particle interactions obey the laws of
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