.. _guide_cub: *********** Cubic (CUB) *********** **Pearson symbol**: cP **Constructor**: :py:func:`.CUB` It is defined by one parameter: :math:`a` with primitive and conventional cell: .. math:: \begin{matrix} \boldsymbol{a}_1 &=& \boldsymbol{a}_1^c &=& (a, &0, &0)\\ \boldsymbol{a}_2 &=& \boldsymbol{a}_2^c &=& (0, &a, &0)\\ \boldsymbol{a}_3 &=& \boldsymbol{a}_3^c &=& (0, &0, &a) \end{matrix} with .. math:: \boldsymbol{C} = \boldsymbol{C}^{-1} = \begin{pmatrix} 1 & 0 & 0 \\ 0 & 1 & 0 \\ 0 & 0 & 1 \end{pmatrix} Variations ========== There are no variations for cubic lattice. One example is predefined: ``cub`` with :math:`a = \pi`. K-path ====== :math:`\mathrm{\Gamma-X-M-\Gamma-R-X\vert M-R}`. ======================= ============================== ============================== ============================== Point :math:`\times\boldsymbol{b}_1` :math:`\times\boldsymbol{b}_2` :math:`\times\boldsymbol{b}_3` ======================= ============================== ============================== ============================== :math:`\mathrm{\Gamma}` :math:`0` :math:`0` :math:`0` :math:`\mathrm{M}` :math:`1/2` :math:`1/2` :math:`0` :math:`\mathrm{R}` :math:`1/2` :math:`1/2` :math:`1/2` :math:`\mathrm{X}` :math:`0` :math:`1/2` :math:`0` ======================= ============================== ============================== ============================== Examples ======== Brillouin zone and default kpath ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ .. literalinclude:: cub_brillouin.py :language: py .. raw:: html :file: cub_brillouin.html Primitive and conventional cell ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ .. literalinclude:: cub_real.py :language: py .. raw:: html :file: cub_real.html Wigner-Seitz cell ^^^^^^^^^^^^^^^^^ .. literalinclude:: cub_wigner-seitz.py :language: py .. raw:: html :file: cub_wigner-seitz.html Cell standardization ==================== No standardization required. .. math:: \boldsymbol{S} = \boldsymbol{S}^{-1} = \boldsymbol{S}^T = \begin{pmatrix} 1 & 0 & 0 \\ 0 & 1 & 0 \\ 0 & 0 & 1 \end{pmatrix}