Quantum tunneling is a phenomenon in quantum mechanics where a particle has a finite probability of crossing a potential energy barrier, even though classically it does not have enough energy to do so. However, when considering macroscopic objects, such as a person, the probability of quantum tunneling through a wall is incredibly small due to the large number of particles involved.
Assuming, for the sake of argument, that quantum tunneling does occur and you somehow tunnel through the wall, what happens next is uncertain. Quantum mechanics describes the behavior of particles probabilistically, meaning that the outcome of an individual quantum event is uncertain. Therefore, there is no definitive answer as to whether you would be alive or dead on the other side of the wall.
In quantum tunneling scenarios, it is generally understood that the probabilities associated with various outcomes would be extremely low, making the occurrence of such events highly unlikely. Furthermore, tunneling through a solid wall would likely involve an enormous number of particles simultaneously tunneling in a coordinated manner, which is exponentially less probable than the tunneling of a single particle.
In the realm of everyday experiences and macroscopic objects, the laws of classical physics and the principles of thermodynamics govern our understanding. While quantum mechanics is essential for describing the behavior of particles at the microscopic level, its effects on macroscopic objects are typically negligible and do not lead to observable tunneling phenomena on a large scale.
In summary, while quantum tunneling is a fascinating quantum phenomenon, its relevance and implications for macroscopic objects such as humans are negligible and highly improbable.