In recent years, some physicists have conducted experiments in which faster-than-light (FTL) speeds were measured. On the other hand, Einstein's theory of special relativity gives light speed as the absolute speed limit for matter and information! If information is transmitted faster, then a host of strange effects can be produced, e.g. for some observers it looks like the information was received even before it was sent (how this comes about should be described in elementary literature on special relativity). This violation of causality is very worrysome, and thus special relativity's demand that neither matter nor information should move faster than light is a pretty fundamental one, not at all comparable to the objections some physicists had about faster-than-sound travel in the first half of this century.
So, has special relativity been disproved, now that FTL speeds have been measured?
Quantum tunnelling outside the light cone is a hypothetical phenomenon in quantum mechanics where a particle can travel through a barrier faster than the speed of light. This would violate the principles of special relativity, which states that nothing can travel faster than the speed of light.
In regular quantum tunnelling, a particle can pass through a barrier by "tunneling" through it, even though it does not have enough energy to overcome the barrier. In quantum tunnelling outside the light cone, the particle would be able to travel through a barrier faster than the speed of light, which is not possible in regular quantum tunnelling.
Currently, there is no experimental evidence for quantum tunnelling outside the light cone. It is a theoretical concept that has not been observed or proven in any experiments.
Quantum tunnelling outside the light cone is important because it challenges our understanding of the fundamental principles of physics, such as special relativity. It also has potential implications for faster-than-light communication and time travel.
As of now, there is no way to directly observe or test quantum tunnelling outside the light cone. However, some researchers are exploring ways to indirectly test the concept through experiments and simulations. It remains a topic of ongoing research and debate in the scientific community.