Measure Space from Outer Measure

Theorem
Suppose $\mu^*$ is an outer measure on a set $X$.

Let $\mathfrak M(\mu^*)$ be the collection of $\mu^*$-measurable sets.

Let $\mu$ be the restriction of $\mu^*$ to $\mathfrak M(\mu^*)$.

Then $(X, \mathfrak M(\mu^*), \mu)$ is a measure space.

Proof
First, note that $\mathfrak M(\mu^*)$ is a $\sigma$-algebra over $X$.

Next, choose $E_1, E_2\in\mathfrak M(\mu^*)$ such that $E_1\cap E_2 = \varnothing$.

Thus:

Therefore $\mu$ is additive. But because it is constructed from an outer measure, it is also countably subadditive.

Since Additive and Countably Subadditive Functions are Countably Additive, it follows that $\mu$ is countably additive.

Finally, also because it is constructed from an outer measure, $\mu$ is nonnegative.

Hence $(X, \mathfrak M(\mu^*), \mu)$ meets all the criteria of a measure space.

Consequences
It immediately follows from the theorem that the Lebesgue measure forms a measure over the collection of Lebesgue measurable sets of reals.