Answer to Question #302529 in Abstract Algebra for rob k

Let "H" be a subgroup of "\\mathbb{Z}". First of all, we study apart the case of "H=\\{0\\}". In this case "H" has an infinite index, but this is a degenerate case.

Now let "H" be a non-trivial subgroup, then "H" has a non-zero element "x" with a minimal absolute value "|x|>0". Let us prove that "H=x\\mathbb{Z}". First, "x\\mathbb{Z}\\subseteq H". Second, suppose that there is "y\\in H" such that "y\\neq a\\cdot x" with "a\\in \\mathbb{Z}". The euclidian division of "y" by "x" gives us a remainder "r\\in H" (as "r=y-a\\cdot x" and both terms are in "H"), but by the properties of a euclidian division "|r|<|x| \\text{ and } \\; r\\neq 0" as "y\\neq a\\cdot x". This condraticts the fact that "x\\in H" is of minimal absolute value. Therefore, "H=x\\cdot \\mathbb{Z}" and we easily deduce that the index of "H" is "|x|" and so is finite.

We conclude that the index of every non-trivial subgroup of the integers is finite. For the trivial subgroup this is obviously false.