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dft_tools/doc/tour/dmft.py
tayral edd1ff4529 Restructuring documentation.
A first general restructuration of the doc according to the pattern [tour|tutorial|reference].
In the reference part, objects are documented per topic.
In each topic, [definition|c++|python|hdf5] (not yet implemented)
2014-10-18 12:21:08 +01:00

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Python

from pytriqs.gf.local import *
from pytriqs.operators import *
from pytriqs.archive import *
import pytriqs.utility.mpi as mpi
# Set up a few parameters
U = 2.5
half_bandwidth = 1.0
chemical_potential = U/2.0
beta = 100
n_loops = 5
# Construct the CTQMC solver
from pytriqs.applications.impurity_solvers.cthyb_matrix import Solver
S = Solver(beta = beta, gf_struct = [ ('up',[1]), ('down',[1]) ])
# Initalize the Green's function to a semi circular
S.G <<= SemiCircular(half_bandwidth)
# Now do the DMFT loop
for IterationNumber in range(n_loops):
# Compute S.G0 with the self-consistency condition while imposing paramagnetism
g = 0.5 * ( S.G['up'] + S.G['down'] )
for name, g0block in S.G0:
g0block <<= inverse( iOmega_n + chemical_potential - (half_bandwidth/2.0)**2 * g )
# Run the solver
S.solve(H_local = U * N('up',1) * N('down',1), # Local Hamiltonian
quantum_numbers = { 'Nup' : N('up',1), 'Ndown' : N('down',1) }, # Quantum Numbers (operators commuting with H_Local)
n_cycles = 5000, # Number of QMC cycles
length_cycle = 200, # Length of a cycle
n_warmup_cycles = 1000, # How many warmup cycles
n_legendre = 30, # Use 30 Legendre coefficients to represent G(tau)
random_name = "mt19937", # Use the Mersenne Twister 19937 random generator
use_segment_picture = True) # Here we can use the segment picture
# Some intermediate saves
if mpi.is_master_node():
R = HDFArchive("single_site_bethe.h5")
R["G-%s"%IterationNumber] = S.G
del R
# Here we would usually write some convergence test
# if Converged : break