Let's actually prove a stronger result: for any constants r_{0} and r_{1} where 1 ≤ r_{0} < r_{1}, it is true that r_{0}^{n} = O(r_{1}^{n}) and it is false that r_{1}^{n} = r_{0}^{n}. This proves your result as a special case, since 1 < 3/2 < 2.

To prove the first part, we'll show that r_{0}^{n} = O(r_{1}^{n}). To do this, we'll use the definition of big-O and find values of n_{0} and c such that for any n > n_{0}, we have that

r_{0}^{n} ≤ c r_{1}^{n}

We can choose n = n_{0} and can choose c = 1. The above inequality then holds, so by definition we have that r_{0}^{n} = O(r_{1}^{n}).

To prove the second part, we'll show that r_{1}^{n} ≠ O(r_{0}^{n}). To do this, we'll proceed by contradiction. Assume for the sake of contradiction that there exists a choice of c and n_{0} such that for any n > n_{0}, we have that

r_{1}^{n} ≤ c r_{0}^{n}

Take the log of both sides to get

n log r_{1} ≤ log (c r_{0}^{n})

n log r_{1} ≤ log c + n log r_{0}

n (log r_{1} - log r_{0}) ≤ log c

n log(r_{1} / r_{0}) ≤ log c

n ≤ log c / (log(r_{1} / r_{0}))

But now we're in trouble, since this statement should hold for any choice of n. However, if we pick any choice of n greater than log c / (log(r_{1} / r_{0})), the statement becomes false.

We have reached a contradiction, so our assumption must have been wrong. Thus if 1 < r_{0} < r_{1}, we have that r_{1}^{n} ≠ O(r_{0}^{n}).

Hope this helps!