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#!/usr/bin/env python
## compute the bands for bilayer graphene (no g4 or delta)
## first regime
from math import *
import cmath
import numpy
g1=0.1
g3=0.33*g1
def Omega(x,y):
return(1+2*cmath.exp(-3j/2*x)*cos(sqrt(3)/2*y))
# Hamiltonian
def H(x,y):
return(numpy.array(\
[[0,g1,0,Omega(x,y).conjugate()],\
[g1,0,Omega(x,y),0],\
[0,Omega(x,y).conjugate(),0,g3*Omega(x,y)*cmath.exp(3j*x)],\
[Omega(x,y),0,g3*(Omega(x,y).conjugate())*cmath.exp(-3j*x),0]]\
))
# eigenvalues
def eigsH(x,y):
return(numpy.linalg.eigvals(H(x,y)))
# resolution
nrpoints=31
# xrange
xmin,xmax=2*pi/3-1.5,2*pi/3+1.5
# yrange
ymin,ymax=2*pi/3/sqrt(3)-1.5,2*pi/3/sqrt(3)+1.5
# sample points
x=numpy.linspace(xmin,xmax,nrpoints)
y=numpy.linspace(ymin,ymax,nrpoints)
x,y=numpy.meshgrid(x,y)
# data points
z=numpy.zeros((4,nrpoints,nrpoints))
for i in range(0,nrpoints):
for j in range(0,nrpoints):
eigs=numpy.sort(numpy.real(eigsH(x[i,j],y[i,j])))
for k in range(0,4):
z[k,i,j]=(eigs[k])
# output
for i in range(0,nrpoints):
for j in range(0,nrpoints):
for k in range(0,4):
print("%10f %10f %10f %d " % (x[i,j],y[i,j],z[k,i,j],k),end='')
print()
print()
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