update

2021-12-28 21:08:38 +08:00 · 2021-12-28 21:08:38 +08:00 · ab80534458
commit ab80534458
parent 5e4375af09
2 changed files with 63 additions and 0 deletions
--- a/academic_codes/2021.07.26_calculation_of_chern_number_with_kubo_formula/calculation_of_chern_number_with_kubo_formula.py
+++ b/academic_codes/2021.07.26_calculation_of_chern_number_with_kubo_formula/calculation_of_chern_number_with_kubo_formula.py
--- a/academic_codes/2021.12.28_calculation_of_Chern_number_by_Wilson_loop/calculation_of_Chern_number_by_Wilson_loop.py
+++ b/academic_codes/2021.12.28_calculation_of_Chern_number_by_Wilson_loop/calculation_of_Chern_number_by_Wilson_loop.py
@ -0,0 +1,63 @@
 """
 This code is supported by the website: https://www.guanjihuan.com
 The newest version of this code is on the web page: https://www.guanjihuan.com/archives/18319
 """
 import numpy as np
 from math import * 
 import time
 import cmath
 def hamiltonian(kx, ky):  # 量子反常霍尔QAH模型（该参数对应的陈数为2）
    t1 = 1.0
    t2 = 1.0
    t3 = 0.5
    m = -1.0
    matrix = np.zeros((2, 2), dtype=complex)
    matrix[0, 1] = 2*t1*cos(kx)-1j*2*t1*cos(ky)
    matrix[1, 0] = 2*t1*cos(kx)+1j*2*t1*cos(ky)
    matrix[0, 0] = m+2*t3*sin(kx)+2*t3*sin(ky)+2*t2*cos(kx+ky)
    matrix[1, 1] = -(m+2*t3*sin(kx)+2*t3*sin(ky)+2*t2*cos(kx+ky))
    return matrix
 def main():
    start_time = time.time()
    n = 200  # 积分密度
    delta = 2*pi/n
    chern_number = 0
    for kx in np.arange(-pi, pi, delta):
        for ky in np.arange(-pi, pi, delta):
            H = hamiltonian(kx, ky)
            eigenvalue, eigenvector = np.linalg.eig(H)
            vector = eigenvector[:, np.argsort(np.real(eigenvalue))[0]]  # 价带波函数
            # vector = eigenvector[:, np.argsort(np.real(eigenvalue))[0]]*cmath.exp(1j*np.random.uniform(0, pi))  # 验证规范不依赖性
            H_delta_kx = hamiltonian(kx+delta, ky) 
            eigenvalue, eigenvector = np.linalg.eig(H_delta_kx)
            vector_delta_kx = eigenvector[:, np.argsort(np.real(eigenvalue))[0]]   # 略偏离kx的波函数
            H_delta_ky = hamiltonian(kx, ky+delta)  
            eigenvalue, eigenvector = np.linalg.eig(H_delta_ky)
            vector_delta_ky = eigenvector[:, np.argsort(np.real(eigenvalue))[0]]  # 略偏离ky的波函数
            H_delta_kx_ky = hamiltonian(kx+delta, ky+delta)  
            eigenvalue, eigenvector = np.linalg.eig(H_delta_kx_ky)
            vector_delta_kx_ky = eigenvector[:, np.argsort(np.real(eigenvalue))[0]]  # 略偏离kx和ky的波函数
            line_1 = np.dot(vector.transpose().conj(), vector_delta_kx)
            line_2 = np.dot(vector_delta_kx.transpose().conj(), vector_delta_kx_ky)
            line_3 = np.dot(vector_delta_kx_ky.transpose().conj(), vector_delta_ky)
            line_4 = np.dot(vector_delta_ky.transpose().conj(), vector)
            angle = np.log(np.dot(np.dot(np.dot(line_1, line_2), line_3), line_4))/1j
            chern_number = chern_number + angle
    chern_number = chern_number/(2*pi)
    print('Chern number = ', chern_number)
    end_time = time.time()
    print('运行时间(min)=', (end_time-start_time)/60)
 if __name__ == '__main__':
    main()