update

2022-11-06 22:10:55 +08:00 · 2022-11-06 22:10:55 +08:00 · 92b1824a1d
commit 92b1824a1d
parent 49e3efd12c
3 changed files with 7 additions and 7 deletions
--- a/academic_codes/2020.09.30_bandstructure_of_graphene_on_high_symmetric_axes/bandstructure_of_graphene_on_high_symmetric_axes.py
+++ b/academic_codes/2020.09.30_bandstructure_of_graphene_on_high_symmetric_axes/bandstructure_of_graphene_on_high_symmetric_axes.py
@ -10,9 +10,9 @@ import cmath  # 要处理复数情况，用到cmath.exp()


 def hamiltonian(k1, k2, M=0, t1=1, a=1/sqrt(3)):  # Haldane哈密顿量(a为原子间距，不赋值的话默认为1/sqrt(3)）
-    h0 = np.zeros((2, 2))*(1+0j)
-    h1 = np.zeros((2, 2))*(1+0j)
-    h2 = np.zeros((2, 2))*(1+0j)
+    h0 = np.zeros((2, 2), dtype=complex)
+    h1 = np.zeros((2, 2), dtype=complex)
+    h2 = np.zeros((2, 2), dtype=complex)

    # 质量项(mass term), 用于打开带隙
    h0[0, 0] = M
--- a/academic_codes/2021.01.10_Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery/Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery.py
+++ b/academic_codes/2021.01.10_Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery/Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery.py
@ -11,7 +11,7 @@ import time


 def hamiltonian(k1, k2, t1=2.82, a=1/sqrt(3)):  # 石墨烯哈密顿量（a为原子间距，不赋值的话默认为1/sqrt(3)）
-    h = np.zeros((2, 2))*(1+0j)
+    h = np.zeros((2, 2), dtype=complex)
    h[0, 0] = 0.28/2
    h[1, 1] = -0.28/2
    h[1, 0] = t1*(cmath.exp(1j*k2*a)+cmath.exp(1j*sqrt(3)/2*k1*a-1j/2*k2*a)+cmath.exp(-1j*sqrt(3)/2*k1*a-1j/2*k2*a))
@ -69,9 +69,9 @@ def main():
            j0 += 1

        if band==0:
-            plot_3d_surface(kx_array/pi, ky_array/pi, F_all, xlabel='kx', ylabel='ky', zlabel='Berry curvature', title='Valence Band', rcount=300, ccount=300)
+            plot_3d_surface(kx_array/pi, ky_array/pi, F_all, xlabel='k_x (pi)', ylabel='k_y (pi)', zlabel='Berry curvature', title='Valence Band', rcount=300, ccount=300)
        else:
-            plot_3d_surface(kx_array/pi, ky_array/pi, F_all, xlabel='kx', ylabel='ky', zlabel='Berry curvature', title='Conductance Band', rcount=300, ccount=300)
+            plot_3d_surface(kx_array/pi, ky_array/pi, F_all, xlabel='k_x (pi)', ylabel='k_y (pi)', zlabel='Berry curvature', title='Conductance Band', rcount=300, ccount=300)
        # import guan
        # if band==0:
        #     guan.plot_3d_surface(kx_array/pi, ky_array/pi, F_all, xlabel='kx', ylabel='ky', zlabel='Berry curvature', title='Valence Band', rcount=300, ccount=300)
--- a/academic_codes/2021.01.10_Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery/Berry_curvature_distribution_with_ky=0.py
+++ b/academic_codes/2021.01.10_Berry_curvature_distribution_of_graphene_under_broken_inversion_symmery/Berry_curvature_distribution_with_ky=0.py
@ -11,7 +11,7 @@ import time


 def hamiltonian(k1, k2, t1=2.82, a=1/sqrt(3)):  # 石墨烯哈密顿量（a为原子间距，不赋值的话默认为1/sqrt(3)）
-    h = np.zeros((2, 2))*(1+0j)
+    h = np.zeros((2, 2), dtype=complex)
    h[0, 0] = 0.28/2
    h[1, 1] = -0.28/2
    h[1, 0] = t1*(cmath.exp(1j*k2*a)+cmath.exp(1j*sqrt(3)/2*k1*a-1j/2*k2*a)+cmath.exp(-1j*sqrt(3)/2*k1*a-1j/2*k2*a))