t² | p-1

bhelmes · 2018-06-10, 19:36

A peaceful and pleasant evening for all,

let p be element of N, t a divisor of p-1
if t² | p-1
is it possible that there exist n^t=1 mod p (n element N)
and it exists no m^(t²) =1 mod p (m element N) at the same time.

Or in other words:
Could there be a cycle subgroup with t elements and at the same time
a non cycle subgroup with t² elements if t² | p-1

If you know an example or a proof for it,
i would be interesting to know it.

Greetings from the primes

Bernhard

R. Gerbicz · 2018-06-10, 20:30

Quote:

Originally Posted by bhelmes

is it possible that there exist n^t=1 mod p (n element N)
and it exists no m^(t²) =1 mod p (m element N) at the same time.

What do you think about n=1 and m=1 ?

science_man_88 · 2018-06-10, 23:32

Quote:

Originally Posted by bhelmes

let p be element of N, t a divisor of p-1
if t² | p-1
is it possible that there exist n^t=1 mod p (n element N)
and it exists no m^(t²) =1 mod p (m element N) at the same time.

So not 1 t root of n. Not sure myself at least for non trivial cases.

Dr Sardonicus · 2018-06-11, 14:10

Quote:

Originally Posted by bhelmes

A peaceful and pleasant evening for all,

let p be element of N, t a divisor of p-1
if t² | p-1
is it possible that there exist n^t=1 mod p (n element N)
and it exists no m^(t²) =1 mod p (m element N) at the same time.

Or in other words:
Could there be a cycle subgroup with t elements and at the same time
a non cycle subgroup with t² elements if t² | p-1

[snip]

If n^t == 1 (mod p) then n^(t^2) = (n^t)^t == 1 (mod p) as well, so the answer to your question as first stated is "no."

If p is prime, the answer to your question is "no." The multiplicative group is cyclic of order p - 1. If d is any divisor of p - 1, there is at least one element of multiplicative order d.

If you mean, as it appears from your restatement, that "t^2 divides p - 1, there is an element of multiplicative order t, but no element of multiplicative order t^2," then the answer can be "yes," but of course p must be composite.

Example: p = 9, t = 2, n = 8. 8^2 == 1 (mod 9), 2^2 divides 9 - 1 = 8, but there is no element of multiplicative order 4 (mod 9). The multiplicative group (mod 9) is cyclic of order 6.

This example may be generalized. If l is a prime, q is a prime divisor of l - 1, but q^2 is not a divisor of l - 1, then q^2 is a divisor of l^q - 1. However, the multiplicative group (mod l^q) is cyclic of order l^(q-1)*(l - 1) which is not divisible by q^2. Thus, taking p = l^q, we have that q^2 divides p - 1, there is at least one element of multiplicative order q (mod p), but no element of multiplicative order q^2.

bhelmes · 2018-06-12, 02:57

Dear Dr Sardonicus,

thanks for the clear answer.

It was a question which appears to me concerning https://en.wikipedia.org/wiki/Pockli...primality_test

2018-06-10, 19:36	#1
bhelmes Mar 2016 101011001₂ Posts	t² \| p-1 A peaceful and pleasant evening for all, let p be element of N, t a divisor of p-1 if t² \| p-1 is it possible that there exist n^t=1 mod p (n element N) and it exists no m^(t²) =1 mod p (m element N) at the same time. Or in other words: Could there be a cycle subgroup with t elements and at the same time a non cycle subgroup with t² elements if t² \| p-1 If you know an example or a proof for it, i would be interesting to know it. Greetings from the primes Bernhard

2018-06-12, 02:57	#5
bhelmes Mar 2016 101011001₂ Posts	Dear Dr Sardonicus, thanks for the clear answer. It was a question which appears to me concerning https://en.wikipedia.org/wiki/Pockli...primality_test Last fiddled with by bhelmes on 2018-06-12 at 03:08