Answer:
You can proceed as follows:
Step-by-step explanation:
Suppose that the matrix [tex]ABC[/tex] is invertible, and suppose that at least one of the matrices [tex]A,B,C[/tex] is not invertible. Without loss of generality suppose that the matrix [tex]A[/tex] is not invertible. Remember the important result that a matrix is invertible if and only if its determinant is nonzero. Then,
[tex]\det (ABC)\neq 0.[/tex]
On the other hand, the determinant of a products of matrices is the product of the determinants of the matrices, that is to say,
[tex]\det (ABC)=\det(A)\cdot \det(B)\cdot \det (C).[/tex]
But we supposed that [tex]A[/tex] is not invertible. Then [tex]\det (A)=0[/tex]. Then [tex]\det(A)\cdot \det(B)\cdot \det (C)=0[/tex]. This contradicts the fact that
[tex]\det (ABC)=\det(A)\cdot \det(B)\cdot \det (C)[/tex]
and then the three matrices [tex]A,B,\, \text{and}\, C[/tex] must be invertible matrices.
