Newman's conjecture explained

In mathematics, specifically in number theory, Newman's conjecture is a conjecture about the behavior of the partition function modulo any integer. Specifically, it states that for any integers and such that

, the value of the partition function satisfies the congruence for infinitely many non-negative integers . It was formulated by mathematician Morris Newman in 1960.^[1] It is unsolved as of 2020.

History

Oddmund Kolberg was probably the first to prove a related result, namely that the partition function takes both even and odd values infinitely often. The proof employed was of elementary nature and easily accessible, and was proposed as an exercise by Newman in the American Mathematical Monthly.^{[2] [3] [4]}

1 year later, in 1960, Newman proposed the conjecture and proved the cases m=5 and 13 in his original paper, and m=65 two years later.^[5]

Ken Ono, an American mathematician, made further advances by exhibiting sufficient conditions for the conjecture to hold for prime . He first showed that Newman's conjecture holds for prime if for each between 0 and, there exists a nonnegative integer such that the following holds:

He used the result, together with a computer program, to prove the conjecture for all primes less than 1000 (except 3).^[6] Ahlgren expanded on his result to show that Ono's condition is, in fact, true for all composite numbers coprime to 6.^[7]

Three years later, Ono showed that for every prime greater than 3, one of the following must hold:

• Newman's conjecture holds for, or

for all nonnegative integers, and .

Using computer technology, he proved the theorem for all primes less than 200,000 (except 3).^[8]

Afterwards, Ahlgren and Boylan used Ono's criterion to extend Newman's conjecture to all primes except possibly 3.^[9] 2 years afterwards, they extended their result to all prime powers except powers of 2 or 3.^[10]

Partial progress and solved cases

The weaker statement that

has at least 1 solution has been proved for all . It was formerly known as the Erdős–Ivić conjecture, named after mathematicians Paul Erdős and Aleksandar Ivić. It was settled by Ken Ono.

Notes and References

1. Newman. Morris. 1960. Periodicity Modulo m and Divisibility Properties of the Partition Function. Transactions of the American Mathematical Society. 97. 2. 225–236. 10.2307/1993300. 0002-9947. 1993300.
2. Subbarao. M. V.. 1966. Some Remarks on the Partition Function. The American Mathematical Monthly. 73. 8. 851–854. 10.2307/2314179. 0002-9890. 2314179.
3. Kolberg. O.. 1959-12-01. Note on the Parity of the Partition Functions.. Mathematica Scandinavica. en. 7. 377–378. 10.7146/math.scand.a-10584. 1903-1807. free.
4. Newman. Morris. van Lint. J. H.. 1962. 4944. The American Mathematical Monthly. 69. 2. 175. 10.2307/2312568. 0002-9890. 2312568.
5. Newman. Morris. March 1962. Congruences for the partition function to composite moduli. Illinois Journal of Mathematics. EN. 6. 1. 59–63. 10.1215/ijm/1255631806. 0019-2082. free.
6. Ono. Ken. 2000. Distribution of the Partition Function Modulo m. Annals of Mathematics. 151. 1. 293–307. 10.2307/121118. 0003-486X. 121118. 2000math......8140O. math/0008140.
7. Ahlgren. Scott. 2000-12-01. Distribution of the partition function modulo composite integers M. Mathematische Annalen. en. 318. 4. 795–803. 10.1007/s002080000142. 1432-1807.
8. Bruinier. Jan H.. Ono. Ken. 2003-03-01. Coefficients of half-integral weight modular forms. Journal of Number Theory. 99. 1. 164–179. 10.1016/S0022-314X(02)00061-6. 0022-314X. free.
9. Ahlgren. Scott. Boylan. Matthew. 2003-09-01. Arithmetic properties of the partition function. Inventiones Mathematicae. en. 153. 3. 487–502. 10.1007/s00222-003-0295-6. 1432-1297. 2003InMat.153..487A.
10. Ahlgren. Scott. Boylan. Matthew. 2005-01-01. Coefficients of half-integral weight modular forms modulo ℓj. Mathematische Annalen. en. 331. 1. 219–239. 10.1007/s00208-004-0555-9. 1432-1807.