Let p > 3 be a prime. Show that there is a positive integer n < p-1 such that np-1 - 1 and (n+1)p-1 - 1 are not divisible by p2.
Solution
By the binomial theorem we have (p - a)p-1 - ap-1 = (p-1) p ap-1 mod p2. For 0 < a < p, (p-1) p a = p mod p2, so (p - a)p-1 and ap-1 are unequal mod p2. Hence at most one of them is 0 mod p2. In particular, since 12 = 1 mod p2, we must have (p-1)p-1 ≠ 1 mod p2. Also, at least (p-3)/2 of 2, 3, ... , p-2 must have p-1th powers ≠ 1 mod p2. So either one of the pairs (2, 3), (4, 5), ... , (p-3, p-2) has both members with p-1th powers ≠ 1 mod p2, in which case we are done, or exactly one member of each pair has p-1th power ≠ 1 mod p2.
Now if p-2 has p-1th power ≠ 1 mod p2 then we are done (because of p-1). If not, then p-3 has p-1th power ≠ 1 mod p2. Now suppose (p-4)p-1 = 1 mod p2. Then (expanding) 1 = 4p-1 - (p-1)p 4p-2 = 4p-1 + p 4p-2 mod p2 (*). But (p-2)p-1 = 1 mod p2, so (expanding) 1 = 2p-1 + p 2p-2 mod p2. Squaring, 1 = 4p-1 + p 4p-1 mod p2. Subtracting from (*), 0 = p(4p-1 - 4p-2) = 3 p 4p-2 mod p2, but that is clearly false. So we must have (p-4)p-1 ≠ 1 mod p2 and we are home (with p-4 and p-3).
Comment. This is a weak result. There are relatively few a for which ap-1 = 1 mod p2.
© John Scholes
jscholes@kalva.demon.co.uk
14 Oct 2002