English

Polynomial Lower Bounds for Arithmetic Circuits over Non-Commutative Rings

Computational Complexity 2026-04-27 v1

Abstract

We prove a lower bound of Ω(n1.5)\Omega\left(n^{1.5}\right) for the number of product gates in non-commutative arithmetic circuits for an explicit nn-variate degree-nn polynomial fnf_{n} (over every field). We observe that this implies that over certain non-commutative rings RR, any arithmetic circuit that computes the induced polynomial function fn:RnRf_{n}: R^n \rightarrow R, using the ring operations of addition and multiplication in RR, requires at least Ω(n1.5)\Omega\left(n^{1.5}\right) multiplications. More generally, for any d2d\geq 2 and sufficiently large nn, we obtain a lower bound of Ω(dn)\Omega\left(d\sqrt{n}\right) for nn-variate degree-dd polynomials, for both these models. Prior to our work, the only known lower bounds for the size of non-commutative circuits, or for the size of arithmetic circuits over any ring, were slightly super-linear in max{n,d}\max\{n,d\}: Ω(nlogd)\Omega\left(n\log d\right) by Baur and Strassen, and Ω(dlogn)\Omega\left(d\log n\right) by Nisan. (Nisan's bound was proved for non-commutative arithmetic circuits and implies a bound for arithmetic circuits over non-commutative rings by our observation).

Cite

@article{arxiv.2604.22006,
  title  = {Polynomial Lower Bounds for Arithmetic Circuits over Non-Commutative Rings},
  author = {Ran Raz},
  journal= {arXiv preprint arXiv:2604.22006},
  year   = {2026}
}
R2 v1 2026-07-01T12:33:00.407Z