Can you proof the following?

For each integer #n in N#
#5n^3+7n^5-=0# (mod 12)

2 Answers
Jan 31, 2018

See below.

Explanation:

Given

#5n^3+7n^5 = n(5 n^2+7 n^4)#

we have that a typical polynomial such that

#p(n,a) equiv 0 mod 12# is given by

#p(n,a) = 7(n+a)(n+a+1)^2(n+a+2)#

then making

#5n^2+7n^4 equiv p(n,a) mod 12#

we have

#{(7a^4+28a^3+35a^2+14a equiv 0 mod 12),(28a^3+84a^2+70a+14 equiv 0 mod 12),(42a^2+84a+30 equiv 0 mod 12),( 28a+28 equiv 0 mod 12):}#

so choosing #a = -1# we have

#{(0 equiv 0 mod 12),(0 equiv 0 mod 12),(12 equiv 0 mod 12),(0 equiv 0 mod 12):}#

or

#5n^2+7n^4 equiv p(n,-1) equiv 0 mod 12#

where

#p(n,-1) = 7n^4-7n^2#

then as #7n^4-7n^2 equiv 0 mod 12 rArr 5n^2+7n^4 equiv 0 mod 12 rArr 5n^3+7n^5 equiv 0 mod 12#

Jan 31, 2018

See explanation...

Explanation:

For any integer #n#, note that exactly one of #n#, #n-1#, #n+1# is divisible by #3#. So #n(n-1)(n+1)# is always divisible by #3#.

If #n# is even then #n^2# is divisible by #4#

If #n# is odd then #(n-1)(n+1)# is divisible by #4#

Hence for any integer #n# we have #n^2(n-1)(n+1)# is divisible by #4#.

Hence #n^2(n-1)(n+1)# is divisible by #3*4 = 12#

Then modulo #12# we have #5 -= -7#

So:

#0 -= 7n^3(n-1)(n+1) = 7n^3(n^2-1) = 7n^5-7n^3 -= 5n^3+7n^5#