Peter Cameron's homepage

Welcome to my new homepage on GitHub. Under construction This page is under construction (and probably always will be!)

I am a quarter-time Professor in the School of Mathematics and Statistics at the University of St Andrews, and an Emeritus Professor of Mathematics at Queen Mary, University of London. In addition, I am an associate researcher at CEMAT, University of Lisbon, Portugal.

I am a Fellow of the Royal Society of Edinburgh.

About me

My official page

My diary

zbMATH profile, MathSciNet profile, Google Scholar

ORCID record: orcid.org/0000-0003-3130-9505

Mathematical genealogy, Wikipedia page

CV and publications (PDF)

Biographical stuff, travel diaries

On this site

Talks, publications, conjectures, coauthors, students

Books: Introduction to Algebra, Combinatorics, Notes on Counting, Permutation Groups, Sets, Logic and Categories (some dead links to be sorted out)

Problems from my QMUL homepage

Elsewhere

My homepage at QMUL

Papers on arXiv

Algebra and Combinatorics at St Andrews

British Combinatorial Committee, BCC Conference List

St Andrews pure mathematics seminars

CIRCA

ORCiD

Lecture notes

Australasian Journal of Combinatorics

Cameron Counts

Mathematical quotes
The Infinite Quest, a short course from the IAI Academy

Mathematics: the next generation (LMS–Gresham lecture)

Research snapshots

Cauchy numbers

In group theory, Cauchy's Theorem states that, if a prime p divides the order of a finite group G, then G contains a subgroup which is cyclic of order p.

Can we reverse-engineer this? Clearly we cannot ask for a single subgroup, since primes are the only numbers for which such a result would be true. So we say that n is a Cauchy number if there is a finite list F of finite groups such that a finite group G has order divisible by n if and only if G has a subgroup isomorphic to one of the groups in F.

In a paper with David Craven, Hamid Reza Dorbidi, Scott Harper and Benjamin Sambale, I proved that the Cauchy numbers are as follows:

prime powers;
6;
2p^a, where p is a Fermat prime greater than 3 and a is a positive integer.

For example, the list for n = 6 consists of three groups: the cyclic and dihedral groups of order 6 and the alternating group A₄ of order 12.

The paper is here.

Old research snapshots are kept here.

I am Honorary Editor-In-Chief of the Australasian Journal of Combinatorics, an international open-access journal published by the Combinatorial Mathematics Society of Australasia.

School of Mathematics and Statistics
University of St Andrews
North Haugh
St Andrews, Fife KY16 9SS
SCOTLAND

Fax: +44 (0)1334 46 3748
Email: pjc20(at)st-arthurs(dot)ac(dot)uk
[oops – wrong saint!]

Page revised 9 March 2024

A problem

Cayley's Theorem in group theory states that every group of order n can be embedded as a subgroup of the symmetric group S_n. But usually this group is much too large.

Problem: What is the size F(n) of the smallest group which embeds every group of order n?

In a paper with David Craven, Hamid Reza Dorbidi, Scott Harper and Benjamin Sambale, we looked at this problem, without a lot of success. For the case where n is a prime power p^m, we found a lower bound of p^cm² and an upper bound roughly p^{p^m}.

Subproblem 1: is there an upper bound which is p^{m^c} for some c?

We were able to find the exact order of the smallest abelian group containing every abelian group of order p^m; it is p^F(m), where

F(m) = Σ⌊m/k⌋,

where the sum over k runs from 1 to m. Dirichlet found the order of magnitude of this function; it is roughly m log m.

Subproblem 2: Is it true that no smaller non-abelian group can contain all abelian groups of order p^m?

Old problems are kept here.