Thursday, March 21, 2019

elementary number theory - Prove without induction that $3^{4n}-2^{4n}$ is divisible by $65$





My brother asked me this (for some reason).



My solution is:



$(3^{4n}-2^{4n})\bmod{65}=$



$(81^{n}-16^{n})\bmod{65}=$



$((81\bmod{65})^{n}-16^{n})\bmod{65}=$




$(16^{n}-16^{n})\bmod{65}=$



$0\bmod{65}$






I think that this solution is mathematically flawless (please let me know if you think otherwise).



But I'm wondering if there's another way, perhaps with the binomial expansion of $(81-16)^{n}$.




In other words, something like:



$3^{4n}-2^{4n}=$



$81^{n}-16^{n}=$



$(81-16)^{n}+65k=$



$65^{n}+65k=$




$65(65^{n-1}+k)$



How would I go from "$81^{n}-16^{n}$" to "$(81-16)^{n}+65k$"?


Answer



You can use the formula $$a^n-b^n = (a-b)\left(a^{n-1}+a^{n-2}b+a^{n-3}b^2+\ldots+ab^{n-2}+b^{n-1}\right)$$


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