Nice physics, but not so sure about the electronic device. The minimum 2 terminal (contact) resistance of the topological FET is h/2e^2 = 12.9 kOhms corresponding to the two propagating modes. The allowed R_external from 2015 ITRS is ~200 Ohms/micron channel width. Low power drive current targets are ~1.5 mA/micron. 1D edge channels are not going to do the job for a FET. But gate controllable topology is very interesting.
"Topological degrees of dynamical freedom as a function of space-time manifold, less that, you land in discontinueties and non smoothness which is topologically doomed
What an incredible talk! Thank you!
Thank you so much for this technical but also very approachable way of explaining!
Nice physics, but not so sure about the electronic device. The minimum 2 terminal (contact) resistance of the topological FET is h/2e^2 = 12.9 kOhms corresponding to the two propagating modes. The allowed R_external from 2015 ITRS is ~200 Ohms/micron channel width. Low power drive current targets are ~1.5 mA/micron. 1D edge channels are not going to do the job for a FET. But gate controllable topology is very interesting.
OK I'll bite and play stupid!!! HEIL . THAT'S AS BAD AS A FAMILY I ONCE KNEW NAME OF EICHMANN, AND IN AMERICA. AND THEY WERE GERMANS!!!😈😈😈????????????
Mind = melted + spun squared
"Topological degrees of dynamical freedom as a function of space-time manifold, less that, you land in discontinueties and non smoothness which is topologically doomed
His wife calls him my Fuhere :p
Thanks for sharing this awesome Colloquium!
7 years huh? I found this video just in time then.
Amazing talk!
Very helpful
Excellent talk!
Wonderful talk!
If you have nothing to say, please save us from your waste shit
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nice
If you have nothing to say, please, shut the fuck up
nice....can you send me this presentation on my gmail account plzzz
yes
Yes, I’ll send it right up your keister