Just a correction: I am interested in finding the transmission matrix 't' from the following:
t†t = *ГL(E)½ GC†(E) ГR(E) GC(E) ГL(E)½ * Best Regards, Shivang On Thu, Jun 7, 2018 at 2:23 AM, Shivang Agarwal <shivang.agar...@iitgn.ac.in > wrote: > Hello authors, > > I am trying to perform an eigenchannel analysis of a graphene nanoribbon. > For that I will be using the formula : > *T(E) = ГL(E)½ GC†(E) ГR(E) GC(E) ГL(E)½ * > where *ГL(E)* is the coupling matrix between the left lead and the > conductor, *GC(E)* is the greens function matrix of the conductor > (system) and '†' is the dagger operator. The equation is from the > following paper: https://journals.aps.org/prb/pdf/10.1103/PhysRevB. > 73.075429 > > (1) Now as far as I know, Kwant allows us to calculate transmission as a > number T(E). What I need for my code is 't' where Trace(t*†*t) = T(E). > Could somebody let me know how can I get the desired quantity 't'?. But I > don't know how I can get the coupling matrix *ГL(E) between the left (or > right) lead and the conductor* > > (2) Also, we know that t = *ГL(E)½ GC(E) ГR(E)½ .But I don't know how I > can get the coupling matrix ГL(E) between the left (or right) lead and the > conductor. Is it possible to get too?* > > *PS - My aim is to find the wavefunctions inside the nanoribbon (which > Kwant can do very conveniently) and also their phases! I have found the > wavefunctions but am unable to find their phases. If there's any other way > to find it that would also be extremely helpful.* > > *Any help would be greatly appreciated.* > > *Thanks and Regards,* > *Shivang Agarwal* > -- > *Shivang Agarwal* > Junior Undergraduate > Discipline of Electrical Engineering > IIT Gandhinagar > > Contact: +91-9869321451 > -- *Shivang Agarwal* Junior Undergraduate Discipline of Electrical Engineering IIT Gandhinagar Contact: +91-9869321451