OPEN
This is open, and cannot be resolved with a finite computation.
Is there some $k$ such that every large integer is the sum of a prime and at most $k$ powers of 2?
The open status of this problem reflects the current belief of the owner of this website. There may be literature on this problem that I am unaware of, which may partially or completely solve the stated problem. Please do your own literature search before expending significant effort on solving this problem. If you find any relevant literature not mentioned here, please add this in a comment.
Erdős described this as 'probably unattackable'. In
[ErGr80] Erdős and Graham suggest that no such $k$ exists, although in
[Er80] Erdős conjectured with 'trepidation' that such a $k$ does exist.
Gallagher
[Ga75] has shown that for any $\epsilon>0$ there exists $k(\epsilon)$ such that the set of integers which are the sum of a prime and at most $k(\epsilon)$ many powers of 2 has lower density at least $1-\epsilon$.
Granville and Soundararajan
[GrSo98] have conjectured that at most $3$ powers of 2 suffice for all odd integers, and hence at most $4$ powers of $2$ suffice for all even integers. (The restriction to odd integers is important here - for example, Bogdan Grechuk has observed that $1117175146$ is not the sum of a prime and at most $3$ powers of $2$, and pointed out that parity considerations, coupled with the fact that there are many integers not the sum of a prime and $2$ powers of $2$ (see
[9]) suggest that there exist infinitely many even integers which are not the sum of a prime and at most $3$ powers of $2$).
See also
[9],
[11], and
[16].
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This page was last edited 11 April 2026. View history
Additional thanks to: Bogdan Grechuk and Desmond Weisenberg
When referring to this problem, please use the original sources of Erdős. If you wish to acknowledge this website, the recommended citation format is:
T. F. Bloom, Erdős Problem #10, https://www.erdosproblems.com/10, accessed 2026-05-21
