You want Maclaurin's inequality. Given $n$ positive numbers $a_1, a_2,\dots,a_n$,
write
$$
(x+a_1)(x+a_2)\cdots(x+a_n) = x^n + S_1x^{n-1} + \cdots + S_{n-1}x + S_n,
$$
so $S_i$ is the $i$-th elementary symmetric function of $a_1,\dots,a_n$.
For $i = 1,\dots,n$, set $A_i = S_i/\binom{n}{i}$. When
$n = 2$, $A_1 = (a_1+a_2)/2$ and $A_2 = a_1a_2$. Maclaurin's inequality is that
$$
A_1 \geq \sqrt{A_2} \geq \sqrt[3]{A_3} \geq \cdots \geq \sqrt[n]{A_n},
$$
where the inequality signs are all strict unless $a_1,\dots,a_n$ are all equal.
When $n = 2$ this is the arithmetic-geometric mean inequality.
From a list of $n$ positive numbers $a_1,\dots,a_n$ we have produced a list of $n$ new positive numbers $A_1,\sqrt{A_2},\dots,\sqrt[n]{A_n}$. Repeat the construction.
When $n = 2$ this is the arithmetic-geometric mean recursion.
Theorem: All the terms in the list tend to the same limit.
Off the top of my head I can't recall a reference where this is proved.
It was studied by Meissel in 1875 for $n = 3$.
For example, if we start with the three numbers 1, 2, 3 then
after 4 iterations the three numbers we get all look like 1.9099262335 to 10 digits after the decimal point.
[Edit: Here is a proof of the common limit, using Will Sawin's first comment to my answer below. Order the numbers $a_1,\dots,a_n$ so that $a_1 \geq \cdots \geq a_n > 0$. By Maclaurin's inequality,
$A_1 \geq \sqrt[n]{A_n}$ and we want to bound
$A_1 - \sqrt[n]{A_n}$ from above in terms of $a_1 - a_n$. Well,
$$
A_1 = \frac{a_1 + \cdots + a_n}{n} \leq \frac{(n-1)a_1 + a_n}{n} = a_1 - \frac{a_1 - a_n}{n}
$$
and since $A_n = a_1\cdots a_n \geq a_n^n$ we have
$$
\sqrt[n]{A_n} \geq a_n.
$$
Therefore
$$
0 \leq A_1 - \sqrt[n]{A_n} \leq \left(a_1 - \frac{a_1 - a_n}{n}\right) - a_n = \left(1 - \frac{1}{n}\right)(a_1 - a_n).
$$
So if we start with a sequence $(a_1,a_2,\dots,a_n)$ which is ordered so that $a_1 \geq \cdots \geq a_n > 0$ and construct the sequence $(A_1,\sqrt{A_2},\dots,\sqrt[n]{A_n})$ and keep repeating this, after $r$ iterations the difference between the largest and smallest term is bounded above by $(1-1/n)^{r-1}(a_1 - a_n)$. Letting $r \rightarrow \infty$ we see the $n$ sequences (of largest terms, second largest, etc.) all have the same limit.
]