0.0.155

2022-11-24 17:11:20 +08:00 · 2022-11-24 17:11:20 +08:00 · 2f8fdae7db
commit 2f8fdae7db
parent 61c91480ab
3 changed files with 11 additions and 11 deletions
--- a/PyPI/setup.cfg
+++ b/PyPI/setup.cfg
@ -1,7 +1,7 @@
 [metadata]
 # replace with your username:
 name = guan
-version = 0.0.154
+version = 0.0.155
 author = guanjihuan
 author_email = guanjihuan@163.com
 description = An open source python package
--- a/PyPI/src/guan.egg-info/PKG-INFO
+++ b/PyPI/src/guan.egg-info/PKG-INFO
@ -1,6 +1,6 @@
 Metadata-Version: 2.1
 Name: guan
-Version: 0.0.154
+Version: 0.0.155
 Summary: An open source python package
 Home-page: https://py.guanjihuan.com
 Author: guanjihuan
--- a/PyPI/src/guan/init.py
+++ b/PyPI/src/guan/init.py
@ -2,7 +2,7 @@
 # With this package, you can calculate band structures, density of states, quantum transport and topological invariant of tight-binding models by invoking the functions you need. Other frequently used functions are also integrated in this package, such as file reading/writing, figure plotting, data processing.
-# The current version is guan-0.0.154, updated on November 24, 2022.
+# The current version is guan-0.0.155, updated on November 24, 2022.
 # Installation: pip install --upgrade guan
@ -1187,10 +1187,10 @@ def calculate_conductance_with_disorder(fermi_energy, h00, h01, disorder_intensi
            green_nn_n = guan.green_function(fermi_energy, h00, broadening=0, self_energy=left_self_energy)
            green_0n_n = copy.deepcopy(green_nn_n)
        elif ix != length+1:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
        else:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
    conductance = np.trace(np.dot(np.dot(np.dot(gamma_left, green_0n_n), gamma_right), green_0n_n.transpose().conj()))
    return conductance
@ -1206,10 +1206,10 @@ def calculate_conductance_with_slice_disorder(fermi_energy, h00, h01, disorder_i
            green_nn_n = guan.green_function(fermi_energy, h00, broadening=0, self_energy=left_self_energy)
            green_0n_n = copy.deepcopy(green_nn_n)
        elif ix != length+1:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
        else:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
    conductance = np.trace(np.dot(np.dot(np.dot(gamma_left, green_0n_n), gamma_right), green_0n_n.transpose().conj()))
    return conductance
@ -1226,10 +1226,10 @@ def calculate_conductance_with_disorder_inside_unit_cell_which_keeps_translation
            green_nn_n = guan.green_function(fermi_energy, h00, broadening=0, self_energy=left_self_energy)
            green_0n_n = copy.deepcopy(green_nn_n)
        elif ix != length+1:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
        else:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+disorder, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
    conductance = np.trace(np.dot(np.dot(np.dot(gamma_left, green_0n_n), gamma_right), green_0n_n.transpose().conj()))
    return conductance
@ -1246,10 +1246,10 @@ def calculate_conductance_with_random_vacancy(fermi_energy, h00, h01, vacancy_co
            green_nn_n = guan.green_function(fermi_energy, h00, broadening=0, self_energy=left_self_energy)
            green_0n_n = copy.deepcopy(green_nn_n)
        elif ix != length+1:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+random_vacancy, h01, green_nn_n, broadening=0)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
        else:
-            green_nn_n = guan.green_function_nn_n(fermi_energy, h00+random_vacancy, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
+            green_nn_n = guan.green_function_nn_n(fermi_energy, h00, h01, green_nn_n, broadening=0, self_energy=right_self_energy)
            green_0n_n = guan.green_function_in_n(green_0n_n, h01, green_nn_n)
    conductance = np.trace(np.dot(np.dot(np.dot(gamma_left, green_0n_n), gamma_right), green_0n_n.transpose().conj()))
    return conductance