Hi Anton,
Thank you for awnsering! I don't think that it is e problem with my code because there because i am using the one that is used on the tutoring of kwant:
import kwant
# For plotting
from matplotlib import pyplot
# For matrix support
import tinyarray
# define Pauli-matrices for convenience
sigma_0 = tinyarray.array([[1, 0], [0, 1]])
sigma_x = tinyarray.array([[0, 1], [1, 0]])
sigma_y = tinyarray.array([[0, -1j], [1j, 0]])
sigma_z = tinyarray.array([[1, 0], [0, -1]])
def make_system(a=1, t=1.0, alpha=0.5, e_z=0.08, W=10, L=30):
# Start with an empty tight-binding system and a single square lattice.
# `a` is the lattice constant (by default set to 1 for simplicity).
lat = kwant.lattice.square(a)
sys = kwant.Builder()
#### Define the scattering region. ####
sys[(lat(x, y) for x in range(L) for y in range(W))] = \
4 * t * sigma_0 + e_z * sigma_z
# hoppings in x-direction
sys[kwant.builder.HoppingKind((1, 0), lat, lat)] = \
-t * sigma_0 - 1j * alpha * sigma_y
# hoppings in y-directions
sys[kwant.builder.HoppingKind((0, 1), lat, lat)] = \
-t * sigma_0 + 1j * alpha * sigma_x
#### Define the left lead. ####
lead = kwant.Builder(kwant.TranslationalSymmetry((-a, 0)))
lead[(lat(0, j) for j in xrange(W))] = 4 * t * sigma_0 + e_z * sigma_z
# hoppings in x-direction
lead[kwant.builder.HoppingKind((1, 0), lat, lat)] = \
-t * sigma_0 - 1j * alpha * sigma_y
# hoppings in y-directions
lead[kwant.builder.HoppingKind((0, 1), lat, lat)] = \
-t * sigma_0 + 1j * alpha * sigma_x
#### Attach the leads and return the finalized system. ####
sys.attach_lead(lead)
sys.attach_lead(lead.reversed())
return sys
def plot_conductance(sys, energies):
# Compute conductance
data = []
for energy in energies:
smatrix = kwant.smatrix(sys, energy)
data.append(smatrix.transmission(1, 0))
pyplot.figure()
pyplot.plot(energies, data)
pyplot.xlabel("energy [t]")
pyplot.ylabel("conductance [e^2/h]")
pyplot.show()
def main():
sys = make_system()
# Check that the system looks as intended.
kwant.plot(sys)
# Finalize the system.
sys = sys.finalized()
# We should see non-monotonic conductance steps.
plot_conductance(sys, energies=[0.01 * i - 0.3 for i in xrange(100)])
# Call the main function if the script gets executed (as opposed to imported).
# See <http://docs.python.org/library/__main__.html>.
if __name__ == '__main__':
main()Best Regards,
Alexis
> From: anton.akhmerov@gmail.com
> Date: Thu, 25 Jun 2015 11:28:58 +0200
> Subject: Re: [Kwant] Spin
> To: alexis-bozio@hotmail.fr
> CC: kwant-discuss@kwant-project.org
>
> Hi Alexis,
>
> Can you share the code that you wrote? Is there any error being raised?
>
> Can you check if your kwant installation is working? To do so execute
>
> import kwant
> kwant.test()
>
> and check the output.
>
> Best,
> Anton
>
> On Thu, Jun 25, 2015 at 11:25 AM, Alexis Bozio <alexis-bozio@hotmail.fr> wrote:
> > Hello,
> >
> > I'm trying to calculate transmission function including spin with Matrix for
> > onsite values but when i am writting the code that is explained on the site
> > (http://kwant-project.org/doc/1.0/tutorial/tutorial2) it makes the
> > calculation but a few seconds later Python stops and all the datas vanishe.
> > Thank you for your help.
> > Best Regards.
> > Alexis Bozio