Untouchable number

Number that cannot be written as an aliquot sum

Unsolved problem in mathematics:

Are there any odd untouchable numbers other than 5?

In mathematics, an untouchable number is a positive integer that cannot be expressed as the sum of all the proper divisors of any positive integer. That is, these numbers are not in the image of the aliquot sum function. Their study goes back at least to Abu Mansur al-Baghdadi (circa 1000 AD), who observed that both 2 and 5 are untouchable.^[1]

Examples

The number 4 is not untouchable, as it is equal to the sum of the proper divisors of 9: 1 + 3 = 4.
The number 5 is untouchable, as it is not the sum of the proper divisors of any positive integer: 5 = 1 + 4 is the only way to write 5 as the sum of distinct positive integers including 1, but if 4 divides a number, 2 does also, so 1 + 4 cannot be the sum of all of any number's proper divisors (since the list of factors would have to contain both 4 and 2).
The number 6 is not untouchable, as it is equal to the sum of the proper divisors of 6 itself: 1 + 2 + 3 = 6.

The first few untouchable numbers are

2, 5, 52, 88, 96, 120, 124, 146, 162, 188, 206, 210, 216, 238, 246, 248, 262, 268, 276, 288, 290, 292, 304, 306, 322, 324, 326, 336, 342, 372, 406, 408, 426, 430, 448, 472, 474, 498, ... (sequence A005114 in the OEIS).

Properties

The number 5 is believed to be the only odd untouchable number, but this has not been proven. It would follow from a slightly stronger version of the Goldbach conjecture, since the sum of the proper divisors of pq (with p, q distinct primes) is 1 + p + q. Thus, if a number n can be written as a sum of two distinct primes, then n + 1 is not an untouchable number. It is expected that every even number larger than 6 is a sum of two distinct primes, so probably no odd number larger than 7 is an untouchable number, and $1=\sigma (2)-2$ , $3=\sigma (4)-4$ , $7=\sigma (8)-8$ , so only 5 can be an odd untouchable number.^[2] Thus it appears that besides 2 and 5, all untouchable numbers are composite numbers (since except 2, all even numbers are composite). No perfect number is untouchable, since, at the very least, it can be expressed as the sum of its own proper divisors. Similarly, none of the amicable numbers or sociable numbers are untouchable. Also, none of the Mersenne numbers are untouchable, since M_n = 2ⁿ − 1 is equal to the sum of the proper divisors of 2ⁿ.

No untouchable number is one more than a prime number, since if p is prime, then the sum of the proper divisors of p² is p + 1. Also, no untouchable number is three more than a prime number, except 5, since if p is an odd prime then the sum of the proper divisors of 2p is p + 3.

Infinitude

There are infinitely many untouchable numbers, a fact that was proven by Paul Erdős.^[3] According to Chen & Zhao, their natural density is at least d > 0.06.^[4]

References

^ Sesiano, J. (1991), "Two problems of number theory in Islamic times", Archive for History of Exact Sciences, 41 (3): 235–238, doi:10.1007/BF00348408, JSTOR 41133889, MR 1107382, S2CID 115235810
^ The stronger version is obtained by adding to the Goldbach conjecture the further requirement that the two primes be distinct—see Adams-Watters, Frank & Weisstein, Eric W. "Untouchable Number". MathWorld.
^ P. Erdos, Über die Zahlen der Form $\sigma (n)-n$ und $n-\phi (n)$ . Elemente der Math. 28 (1973), 83-86
^ Yong-Gao Chen and Qing-Qing Zhao, Nonaliquot numbers, Publ. Math. Debrecen 78:2 (2011), pp. 439-442.

Richard K. Guy, Unsolved Problems in Number Theory (3rd ed), Springer Verlag, 2004 ISBN 0-387-20860-7; section B10.

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OEIS sequence A070015 (Least m such that sum of aliquot parts of m equals n or 0 if no such number exists)

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