Each number has some *factorization*. If `a`

, `b`

each have a little number of *distinct prime factors* (**DPF**), and distance between them is large, it is certain there will be at least one number between them, whose set of **DPF** s has no elements in common with the two. So this will be our one-number pick `n`

, such that `gcd(a,n) == 1`

and `gcd(n,b) == 1`

. The higher we go, the more prime factors there are, potentially, and the probability for even `gcd(a,b)==1`

is higher and higher, and also for the *one-num-in-between* solution.

When will one-num solution not be possible? When `a`

and `b`

are *highly-composite* - have a lot of **DPF** s each - and are situated not too far from each other, so each intermediate number has some prime factors in common with one or two of them. But `gcd(n,n+1)==1`

for any `n`

, always; so picking one of `a+1`

or `b-1`

- specifically the one with smallest amount of **DPF** s - will decrease the size of combined **DPF** set, and so picking one number between them will be possible. (... this is far from being rigorous though).

This is not a full answer, more like an illustration. Let's try this.

```
-- find a number between the two, that fulfills the condition
gg a b = let fs=union (fc a) (fc b)
in filter (\n-> null $ intersect fs $ fc n) [a..b]
fc = factorize
```

Try it:

```
Main> gg 5 43
[6,7,8,9,11,12,13,14,16,17,18,19,21,22,23,24,26,27,28,29,31,32,33,34,36,37,38,39
,41,42]
Main> gg 2184 2300
[2189,2201,2203,2207,2209,2213,2221,2227,2237,2239,2243,2251,2257,2263,2267,2269
,2273,2279,2281,2287,2291,2293,2297,2299]
```

Plenty of possibilities for just *one* number to pick between 5 and 43, or between 2184 and 2300. But what about the given pair, 2184 and 2200?

```
Main> gg 2184 2200
[]
```

No one number exists to put in between them. But obviously, `gcd (n,n+1) === 1`

:

```
Main> gg 2185 2200
[2187,2191,2193,2197,2199]
Main> gg 2184 2199
[2185,2189,2195]
```

So having picked one adjacent number, we indeed have plenty of possibilities for the 2nd number. Your question is, to prove that it is always the case.

Let's look at their factorizations:

```
Main> mapM_ (print.(id&&&factorize)) [2184..2200]
(2184,[2,2,2,3,7,13])
(2185,[5,19,23])
(2186,[2,1093])
(2187,[3,3,3,3,3,3,3])
(2188,[2,2,547])
(2189,[11,199])
(2190,[2,3,5,73])
(2191,[7,313])
(2192,[2,2,2,2,137])
(2193,[3,17,43])
(2194,[2,1097])
(2195,[5,439])
(2196,[2,2,3,3,61])
(2197,[13,13,13])
(2198,[2,7,157])
(2199,[3,733])
(2200,[2,2,2,5,5,11])
```

It is obvious that the higher the range, the easier it is to satisfy the condition, because the variety of contributing prime factors is greater.

`(a+1)`

won't always work by itself - consider `2185, 2200`

case (similarly, for `2184,2199`

the `(b-1)`

won't work).

So if we happen to get *two* highly composite numbers as our `a`

and `b`

, picking an adjacent number to either one will help, because usually it will have only few factors.