number theory Number theory (or arithmetic or higher arithmetic in older usage) is a branch of pure mathematics devoted primarily to the study of the integers and integer-valued functions. German mathematician Carl Friedrich Gauss (1777–1855) said, "Math ...

, a branch of mathematics, a Mirimanoff's congruence is one of a collection of expressions in

modular arithmetic In mathematics, modular arithmetic is a system of arithmetic for integers, where numbers "wrap around" when reaching a certain value, called the modulus. The modern approach to modular arithmetic was developed by Carl Friedrich Gauss in his bo ...

which, if they hold, entail the truth of

Fermat's Last Theorem In number theory, Fermat's Last Theorem (sometimes called Fermat's conjecture, especially in older texts) states that no three positive integers , , and satisfy the equation for any integer value of greater than 2. The cases and have bee ...

. Since the theorem has now been proven, these are now of mainly historical significance, though the Mirimanoff polynomials are interesting in their own right. The theorem is due to

Dmitry Mirimanoff Dmitry Semionovitch Mirimanoff (russian: Дми́трий Семёнович Мирима́нов; 13 September 1861, Pereslavl-Zalessky, Russia – 5 January 1945, Geneva, Switzerland) became a doctor of mathematical sciences in 1900, in Ge ...

Definition

The ''n''th Mirimanoff polynomial for the prime ''p'' is :

\phi_n(t) = 1^t + 2^t^2 + ... + (p-1)^ t^.

In terms of these polynomials, if ''t'' is one of the six values where ''X''^''p''+''Y''^''p''+''Z''^''p''=0 is a solution to Fermat's Last Theorem, then * φ_''p''-1(''t'') ≡ 0 (mod ''p'') * φ_''p''-2(''t'')φ₂(''t'') ≡ 0 (mod ''p'') * φ_''p''-3(''t'')φ₃(''t'') ≡ 0 (mod ''p'') :... * φ_(''p''+1)/2(''t'')φ_(''p''-1)/2(''t'') ≡ 0 (mod ''p'')

Other congruences

Mirimanoff also proved the following: *If an odd prime ''p'' does not divide one of the numerators of the

Bernoulli number In mathematics, the Bernoulli numbers are a sequence of rational numbers which occur frequently in analysis. The Bernoulli numbers appear in (and can be defined by) the Taylor series expansions of the tangent and hyperbolic tangent functions ...

s ''B''_''p''-3, ''B''_''p''-5, ''B''_''p''-7 or ''B''_''p''-9, then the first case of Fermat's Last Theorem, where ''p'' does not divide ''X'', ''Y'' or ''Z'' in the equation ''X''^''p''+''Y''^''p''+''Z''^''p''=0, holds. *If the first case of Fermat's Last Theorem fails for the prime ''p'', then 3^''p''-1 ≡ 1 (mod ''p''²). A prime number with this property is sometimes called a ''Mirimanoff prime'', in analogy to a

Wieferich prime In number theory, a Wieferich prime is a prime number ''p'' such that ''p''2 divides , therefore connecting these primes with Fermat's little theorem, which states that every odd prime ''p'' divides . Wieferich primes were first described by Art ...

which is a prime such that 2^''p''-1 ≡ 1 (mod ''p''²). The existence of primes satisfying such congruences was recognized long before their implications for the first case of Fermat's Last Theorem became apparent; but while the discovery of the first Wieferich prime came after these theoretical developments and was prompted by them, the first instance of a Mirimanoff prime is so small that it was already known before Mirimanoff formulated the connection to FLT in 1910, which fact may explain the reluctance of some writers to use the name. So early as his 1895 paper (p. 298), Mirimanoff alludes to a rather complicated test for the primes now known by his name, deriving from a formula published by Sylvester in 1861, which is of little computational value but great theoretical interest. This test was considerably simplified by Lerch (1905), p. 476, who showed that in general, for ''p'' > 3,

3^ \equiv \left(- \frac 23 \cdot \left\\right)p + 1 \pmod

so that a prime possesses the Mirimanoff property if it divides the expression within the curly braces. The condition was further refined in an important paper by Emma Lehmer (1938), in which she considered the intriguing and still unanswered question of whether it is possible for a number to satisfy the congruences of Wieferich and Mirimanoff simultaneously. To date, the only known Mirimanoff primes are 11 and 1006003 . The discovery of the second of these appears to be due to K.E. Kloss (1965).

References

*K.E. Kloss, "Some Number-Theoretic Calculations," Journal of Research of the National Bureau of Standards—B. Mathematics and Mathematical Physics 69 (1965), pp. 335–336. *Emma Lehmer, "On Congruences involving Bernoulli Numbers and the Quotients of Fermat and Wilson," Annals of Mathematics 39 (1938), pp. 350–360. *M. Lerch, "Zur Theorie des Fermatschen Quotienten…," Mathematische Annalen 60 (1905), pp. 471–49

*D. Mirimanoff, "Sur la Congruence (''r''^''p''−1 − 1):''p'' ≡ ''q''_''r''," Journal für die reine und angewandte Mathematik 115 (1895), pp. 295–30

Some corrections are given in the 1937 paper below. *D. Mirimanoff, "Sur le dernier théorème de Fermat et le Critérium de M. A. Wieferich," L'Enseignement Mathématique 11 (1909), pp. 455–45

*D. Mirimanoff, "Sur le dernier théorème de Fermat," Comptes rendus hebdomadaires des séances de l'Académie des Sciences 150 (1910), pp. 204–206; a revised and expanded version of this paper appeared under the same title in Journal für die reine und angewandte Mathematik 139 (1911), pp. 309–32

*D. Mirimanoff, "Sur les nombres de Bernoulli," L'Enseignement Mathématique 36 (1937), pp. 228–23

*

Paulo Ribenboim Paulo Ribenboim (born March 13, 1928) is a Brazilian-Canadian mathematician who specializes in number theory. Biography Ribenboim was born into a Jewish family in Recife, Brazil. He received his BSc in mathematics from the University of São Pa ...

, ''13 Lectures on Fermat's Last Theorem'', Springer, 1979 *Paulo Ribenboim, ''My Numbers, My Friends: Popular Lectures on Number Theory'', Springer, 2006 {{DEFAULTSORT:Mirimanoff's Congruence Number theory