WhiteWolf said:Hmm... I got a question. Doesn't quantum tunneling violate the conservation of energy? When a particle tunnels out of an atom, a phenonema that has been proven, it goes against the strong force and gains electromagnetic potential energy, without expending any energy to acquire that potential energy. So for a small instant, it seems like it violates one of the most fundamental laws of physics.
Tunneling is space time is very possible. you know that quantum tunneling lowers the groundstate energy of a system so for this reason it can happen. If something can happen in QM, then it will happen.εllipse said:Does relativistic quantum mechanics make use of 4 dimensional Minkowskian geometry? Or does it just use special relativity formulated in 3 space dimensions and 1 time dimension? And if quantum mechanics can apply to Minkowskian spacetime, then can something tunnel through time?
ZapperZ said:No, because in an elastic tunneling (ballistic), the tunneling particle stays at the same energy state and tunnels into the vacuum state that is also at the same energy (in the form of its KE). That's the whole point of tunneling, it keeps the same energy that is lower than the barrier.
Thanks. Didnt know that. So the Kinetic Energy of the particle is higher with the distance it tunneled also? Hmmm, so what if it tunnels at a much longer distance? If it tunnels past, say... a moles worth of atoms, then wouldn't it have enough energy to approach light speeds? I would imagine that it would acquire great speeds as it is to break the barrier of the strong force from a single atom. So it would eventually have a limit, wouldn't it?
(Sorry, my physics teacher can't answer anything...)
WhiteWolf said:Thanks. Didnt know that. So the Kinetic Energy of the particle is higher with the distance it tunneled also?
DaTario said:There was a famous work by Nimtz, in which he attempted to send a simphony of Mozart along a channel, from the emiter to the recorder and then concluded that the velocity od transmission was 4,7 c. He used tunneling to do so. I guess his experiment was based on the property that tunneling time does not depend on the extension of the barrier. Do you know if his work was accepted by the physics community ?
DaTario said:Mr. Zapperz,
There was a famous work by Nimtz, in which he attempted to send a simphony of Mozart along a channel, from the emiter to the recorder and then concluded that the velocity od transmission was 4,7 c. He used tunneling to do so. I guess his experiment was based on the property that tunneling time does not depend on the extension of the barrier. Do you know if his work was accepted by the physics community ?
Quantum tunnelling is a phenomenon in which a particle can pass through a potential barrier even though it does not have enough energy to do so according to classical physics. This is possible due to the probabilistic nature of quantum mechanics, which allows for particles to exist in multiple states simultaneously.
Quantum tunnelling occurs when a particle approaches a potential barrier and has a certain probability of "tunneling" through it. This probability is determined by the particle's energy and the height and width of the barrier. The particle exists in a superposition of states, both on one side and the other of the barrier, until it is observed or interacts with another particle.
Quantum tunnelling has many practical applications, such as in scanning tunneling microscopy, where it is used to image surfaces at the atomic level. It is also important in the functioning of tunnel diodes, which are used in electronic devices such as microwave amplifiers and oscillators.
Spacetime is a concept that combines the three dimensions of space (length, width, and height) with the dimension of time. It is a fundamental concept in physics, and according to the theory of general relativity, it is the fabric of the universe in which all matter and energy exist.
Quantum tunnelling and spacetime are related in the sense that quantum tunnelling occurs within the fabric of spacetime. The probabilistic nature of quantum mechanics allows particles to exist in multiple states simultaneously, including different points in spacetime. This is why particles can tunnel through potential barriers, as they exist in a superposition of states on either side of the barrier.