I may have been explaining this rather loosely previously, I'll try and clear everything up as best I can, the ideas behind QM are not easily grasped unless you have a rather abstract mind, or think A LOT, like me!
How goes job hunting /phd funding with that? I wish you luck, some of my friends are struggling.
I'm all sorted to do a PhD in Acoustics and Audio Signal Processing (my main love in life is music, it fits), although I've also applied to work on the TARANIS laser in QUB. Funding included, of course!
... ions exchanging places when energy is sufficient ...
Not quite, if they exchanged places, there would be no overall movement. Rather the ions are pushed out of the way by the electrons, and sort of 'squish up' to make room. Gaps then appear in the track, breaking the circuit.
This is strongly temperature dependent, so keeping the system appreciably below ambient will allow higher electron energies without death from this effect...
It's the other way around really, the high temps are CAUSED by the collisions! When an electron transfers energy to an ion, it can be given as vibrational energy, causing a temperature increase. Keeping the temps VERY low will decrease the temperature rise, as the cross section of the ions blocking the electrons will be reduced, as they will be moving a lot less. It will still happen though, just more slowly
...I think below a certain temperature even the most energetic electron just isn't going to make any difference...
Nope, It has to do with the electron current DENSITY, which is already high in microelectronics. By increasing volts, you increase the current (as the resistance doesn't change....much). It has a lot more to do with the sheer number of electrons rather than their energy. I think. Need to read up a bit on that to be sure.
Electron tunnelling is a separate effect. Keeping the system cold wont help with this, increasing voltage will steadily increase this.
ABSOLUTELY CORRECT! Well, it wont be a steady increase, rather an exponential one, but you get the drift
Memories of the maxwell-boltzmann distribution suggests that this is always going to occur, and can be safely ignored up to an approximate voltage beyond which all hell breaks lose as a significant fraction of the electrons have sufficient energy to move to where they aren't expected...
The MB dist. has relatively little to do with this, in any conductor there's only a small number of electrons that have the mobility required to conduct (i.e. in the conduction band of a metal, or at the top of an unfilled valance band in an insulator, like doped silicon). It doesn't
always happen, but you're right that it can be ignored up to a certain point. What you will see as you approach the voltage limit (if this is causing the instability) is only occasional errors initially, but as you increase the volts, the frequency of these errors will increase greatly
When looking at this classically, all hell will break loose at a certain point as the electron energy can overcome a potential barrier only when it has sufficient energy. Quantum mechannically however, electrons can 'borrow' energy from the surrounding vacuum (the amount is dependant on the time it is borrowed for, and is derrived from Heisenberg's uncertainty principle). With this 'borrowed' energy, it can tunnel through a barrier WHEN ITS ENERGY IS LOWER THAN THE BARRIER. Classically this could not happen.
Is it a fair statement that I won't damage anything with this, but stability suddenly starting to drop off with increased voltage is a sign that it's becoming an issue?
It's a sign that there is
an issue. It may be this, it may be something else entirely!
This suggests an ultimate limit, beyond which no further voltage nor cooling will help.
Bingo.
You're very welcome! Sorry that was a bit long, I feel I would be doing an injustice if I didn't do my best to explain as correctly as I can! If you have any uncertianties (haha! physics joke right there!), I'll to my best to make them as observable (oh I'm cracking myself up as I write this!) as I can!
David
