Answer to Question #350753 in Abstract Algebra for Dron

Let us assume that there are finitely many primes and label them "p_1,\\dots,p_n". We will now construct the number "P" to be one more than the product of all finitely many primes: "P=p_1p_2\\dots p_n+1".

The number "P" has remainder "1" when divided by any prime "p_i", "i=1,\\dots,n", making it a prime number as long as "P\\ne1".

Since "2" is a prime number, the list of "p_i"'s is non-empty. It follows that "P" is greater that one and so has two distinct divisors. It is therefore a prime number.

It can also be seen from the definition of "P" that it is strictly greater than any of the "p_i"'s.  This contradicts our assumption that there are finitely many prime numbers. Therefore, there are infinitely many prime numbers.