Zsigmondy's theorem

In number theory, Zsigmondy's theorem, named after Karl Zsigmondy, states that if ${\displaystyle a>b>0}$ are coprime integers, then for any integer ${\displaystyle n\ge 1}$, there is a prime number p (called a primitive prime divisor) that divides ${\displaystyle a^n-b^n}$ and does not divide ${\displaystyle a^k-b^k}$ for any positive integer ${\displaystyle k<n}$, with the following exceptions:

• ${\displaystyle n=1}$, ${\displaystyle a-b=1}$; then ${\displaystyle a^n-b^n=1}$ which has no prime divisors
• ${\displaystyle n=2}$, ${\displaystyle a+b}$ a power of two; then any odd prime factors of ${\displaystyle a^2-b^2=(a+b)(a^1-b^1)}$ must be contained in ${\displaystyle a^1-b^1}$, which is also even
• ${\displaystyle n=6}$, ${\displaystyle a=2}$, ${\displaystyle b=1}$; then ${\displaystyle a^6-b^6=63=3^2\times 7=(a^2-b^2{)}^2(a^3-b^3)}$

This generalizes Bang's theorem,^[1] which states that if ${\displaystyle n>1}$ and ${\displaystyle n}$ is not equal to 6, then ${\displaystyle 2^n-1}$ has a prime divisor not dividing any ${\displaystyle 2^k-1}$ with ${\displaystyle k<n}$.

Similarly, ${\displaystyle a^n+b^n}$ has at least one primitive prime divisor with the exception ${\displaystyle 2^3+1^3=9}$.

Zsigmondy's theorem is often useful, especially in group theory, where it is used to prove that various groups have distinct orders except when they are known to be the same.^[2][3]

The theorem was discovered by Zsigmondy working in Vienna from 1894 until 1925.

Let ${\displaystyle (a_n{)}_{n\ge 1}}$ be a sequence of nonzero integers. The Zsigmondy set associated to the sequence is the set

${\displaystyle {𝒵}(a_n)=\{n\ge 1:a_n\text{ has no primitive prime divisors}\}.}$

i.e., the set of indices ${\displaystyle n}$ such that every prime dividing ${\displaystyle a_n}$ also divides some ${\displaystyle a_m}$ for some ${\displaystyle m<n}$. Thus Zsigmondy's theorem implies that ${\displaystyle {𝒵}(a^n-b^n)\subset \{1,2,6\}}$, and Carmichael's theorem says that the Zsigmondy set of the Fibonacci sequence is ${\displaystyle \{1,2,6,12\}}$, and that of the Pell sequence is ${\displaystyle \{1\}}$. In 2001 Bilu, Hanrot, and Voutier^[4] proved that in general, if ${\displaystyle (a_n{)}_{n\ge 1}}$ is a Lucas sequence or a Lehmer sequence, then ${\displaystyle {𝒵}(a_n)\subseteq \{1\le n\le 30\}}$ (see OEIS: A285314, there are only 13 such ${\displaystyle n}$s, namely 1, 2, 3, 4, 5, 6, 7, 8, 10, 12, 13, 18, 30). Lucas and Lehmer sequences are examples of divisibility sequences.

It is also known that if ${\displaystyle (W_n{)}_{n\ge 1}}$ is an elliptic divisibility sequence, then its Zsigmondy set ${\displaystyle {𝒵}(W_n)}$ is finite.^[5] However, the result is ineffective in the sense that the proof does not give an explicit upper bound for the largest element in ${\displaystyle {𝒵}(W_n)}$, although it is possible to give an effective upper bound for the number of elements in ${\displaystyle {𝒵}(W_n)}$.^[6]

• Carmichael's theorem

• K. Zsigmondy (1892). "Zur Theorie der Potenzreste". Journal Monatshefte für Mathematik 3 (1): 265–284. doi:10.1007/BF01692444. 
• Th. Schmid (1927). "Karl Zsigmondy". Jahresbericht der Deutschen Mathematiker-Vereinigung 36: 167–168. http://www.digizeitschriften.de/dms/img/?PPN=PPN37721857X_0036&DMDID=dmdlog18. 
• Moshe Roitman (1997). "On Zsigmondy Primes". Proceedings of the American Mathematical Society 125 (7): 1913–1919. doi:10.1090/S0002-9939-97-03981-6. 
• Walter Feit (1988). "On Large Zsigmondy Primes". Proceedings of the American Mathematical Society (American Mathematical Society) 102 (1): 29–36. doi:10.2307/2046025. 
• Everest, Graham; van der Poorten, Alf; Shparlinski, Igor; Ward, Thomas (2003). Recurrence sequences. Mathematical Surveys and Monographs. 104. Providence, RI: American Mathematical Society. pp. 103–104. ISBN 0-8218-3387-1. 

• Weisstein, Eric W.. "Zsigmondy Theorem". http://mathworld.wolfram.com/ZsigmondyTheorem.html. 

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