Building up a body centered cubic lattice: Difference between revisions

Revision as of 19:36, 19 March 2007

a cubic simulation box whose sides are of length $\left.L\right.$
a number of lattice positions, $\left.M\right.$ given by $\left.M=2m^{3}\right.$ , with $m$ being a positive integer

\left\{{\begin{array}{l}x_{a}=i_{a}\times (\delta l)\\y_{a}=j_{a}\times (\delta l)\\z_{a}=k_{a}\times (\delta l)\end{array}}\right\}

where the indices of a given valid site $(i_{a},j_{a},k_{a})$ must be either all odd or all even. $\left.\delta l=L/(2m)\right.$

@@ Line 1: / Line 1: @@
 * Consider:
-# a Cubic Simulation box of length <math>\left. L  \right. </math>
+# a cubic simulation box whose sides are of length <math>\left. L  \right. </math>
-# a number of lattice positions, <math> \left. M \right. </math> given by:
+# a number of lattice positions, <math> \left. M \right. </math> given by <math> \left. M = 2 m^3    \right. </math>, with <math> m </math> being a positive integer
-: <math> \left. M = 2 m^3    \right. </math>
-: with <math> m </math> being a positive integer
 * The <math> \left. M \right. </math> positions are those given by:
+:<math>
-<math>
 \left\{ \begin{array}{l}
 x_a = i_a \times (\delta l)  \\
@@ Line 17: / Line 12: @@
 \right\}
 </math>
-where the indices of a given valid site <math>(i_a,j_a,k_a)</math> must be all of them either odd or even.
+where the indices of a given valid site <math>(i_a,j_a,k_a)</math> must be either all odd or all even.
-with
 <math>
 \left.