Conjecture:
Let $m$ be a positive integer. Then $$f(m)=(2m)^{2m+1}+m^{2m+1}\cdot (2m+1)^m+(2m+1)^{2m}$$ is not a prime number.
One can prove it when $m$ is odd number, it is clear that $f(m)$ is an even number in this case.
But for $m$ even, it is not easy to show the conjecture. See some example values: $$f(2) = 4^5 + 2^5 \cdot 5^2 + 5^4 = 2449 = 31\cdot 79$$ $$f(4) = 8^9 + 4^9 \cdot 9^4 + 9^8 = 1897191233 = 7\cdot 53\cdot 73\cdot 70051$$ $$f(6) = 12^{13} + 6^{13} \cdot 13^6 + 13^{12} = 63171766713176497 = 281\cdot 2003681\cdot 112198777$$
Using Maple, one can verify the conjecture for even $m≤1300$.
For $m=1008$, the answer to this question contains a proof, because using Fermat's little theorem it shows $f(1008)\equiv 5 \pmod 5$.
Can we show a factorization, that is, can we look for $g(m),h(m)\in Z[x]$, such that $$f(m)=g(m)\cdot h(m)?$$
