Carmichael number

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A Carmichael number is a composite number named after the mathematician Robert Daniel Carmichael. A Carmichael number ${\displaystyle \scriptstyle c\ }$ divides ${\displaystyle \scriptstyle a^{c}-a\ }$ for every integer ${\displaystyle \scriptstyle a\ }$. A Carmichael number c also satisfies the congruence ${\displaystyle \scriptstyle a^{c-1}\equiv 1{\pmod {c}}}$, if ${\displaystyle \scriptstyle \operatorname {gcd} (a,c)=1}$. The first few Carmichael numbers are 561, 1105, 1729, 2465, 2821, 6601 and 8911. In 1994 Pomerance, Alford and Granville proved that there exist infinitely many Carmichael numbers.

Properties

• Every Carmichael number is square-free and has at least three different prime factors
• For every Carmichael number c it holds that ${\displaystyle c-1}$ is divisible by ${\displaystyle p_{n}-1}$ for every one of its prime factors ${\displaystyle p_{n}}$.
• Every absolute Euler pseudoprime is a Carmichael number.

Chernick's Carmichael numbers

J. Chernick found in 1939 a way to construct Carmichael numbers^{[1] [2]}. If, for a natural number n, the three numbers ${\displaystyle \scriptstyle 6n+1\ }$, ${\displaystyle \scriptstyle 12n+1\ }$ and ${\displaystyle \scriptstyle 18n+1\ }$ are prime numbers, the product ${\displaystyle \scriptstyle M_{3}(n)=(6n+1)\cdot (12n+1)\cdot (18n+1)}$ is a Carmichael number. This condition can only be satisfied if the number ${\displaystyle n\ }$ ends with 0, 1, 5 or 6. An equivalent formulation of Chernick's construction is that if ${\displaystyle \scriptstyle m\ }$, ${\displaystyle \scriptstyle 2m-1\ }$ and ${\displaystyle \scriptstyle 3m-2}$ are prime numbers, then the product ${\displaystyle \scriptstyle m\cdot (2m-1)\cdot (3m-2)}$ is a Carmichael number.

This way to construct Carmichael numbers may be extended^[3] to

${\displaystyle M_{k}(n)=(6n+1)(12n+1)\prod _{i=1}^{k-2}(9\cdot 2^{i}n+1)\,}$

with the condition that each of the factors is prime and that ${\displaystyle n\ }$ is divisible by ${\displaystyle 2^{k-4}}$.

Distribution of Carmichael numbers

Let C(X) denote the number of Carmichael numbers less than or equal to X. Then for all sufficiently large X

${\displaystyle X^{0.332}<C(X)<X\exp(-\log X\log \log \log X/\log \log X).\,}$

The upper bound is due to Erdős(1956)^[4] and Pomerance, Selfridge and Wagstaff (1980)^[5] and the lower bound is due to Glyn Harman (2005),^[6] improving the earlier lower bound of ${\displaystyle X^{2/7}}$ obtained by Alford, Granville and Pomerance (1994), which first established that there were infinitely many Carmichael numbers.^[7]. The asymptotic rate of growth of C(X) is not known.^[8]

References and notes