A six dimensional "cube" (a <math>6</math>-cube) has <math>64</math> vertices at the points <math>(\pm 3,\pm 3,\pm 3,\pm 3,\pm 3,\pm 3)</math>. This <math>6</math>-cube has <math>192\text{ 1-D}</math> edges and <math>240\text{ 2-D}</math> edges. This <math>6</math>-cube gets cut into <math>6^6=46656</math> smaller congruent "unit" <math>6</math>-cubes that are kept together in the tightly packaged form of the original <math>6</math>-cube so that the <math>46656</math> smaller <math>6</math>-cubes share <math>2-D</math> square faces with neighbors (<math>\textit{one}</math> <math>2</math>-D square face shared by <math>\textit{several}</math> unit <math>6</math>-cube neighbors). How many <math>2</math>-D squares are faces of one or more of the unit <math>6</math>-cubes?

A six dimensional "cube" (a <math>6</math>-cube) has <math>64</math> vertices at the points <math>(\pm 3,\pm 3,\pm 3,\pm 3,\pm 3,\pm 3)</math>. This <math>6</math>-cube has <math>192\text{ 1-D}</math> edges and <math>240\text{ 2-D}</math> edges. This <math>6</math>-cube gets cut into <math>6^6=46656</math> smaller congruent "unit" <math>6</math>-cubes that are kept together in the tightly packaged form of the original <math>6</math>-cube so that the <math>46656</math> smaller <math>6</math>-cubes share <math>2-D</math> square faces with neighbors (<math>\textit{one}</math> <math>2</math>-D square face shared by <math>\textit{several}</math> unit <math>6</math>-cube neighbors). How many <math>2</math>-D squares are faces of one or more of the unit <math>6</math>-cubes?