Answer to Question #147956 in Abstract Algebra for Sourav Mondal

We can clearly see that

"4 = 2\\cdot 2 = (1+1\\sqrt{-3})\\cdot (1-1\\sqrt{-3})"

First let's prove that they are irreducible.

We can view elements of "R" as complex numbers (obviously) and thus we know that if "2=(a+b\\sqrt{-3})(c+d\\sqrt{-3})" we have "(a^2+3b^2)(c^2+3d^2)=4" and as the last expression is an equation in "\\mathbb{Z}" we can easily conclude that either "a^2+3b^2=1," or "c^2+3d^2=1" and thus we have "2= (\\pm2) \\cdot (\\pm1)" and "2" is irreducible.

Now let's prove that "1\\pm\\sqrt{-3}" are irreducible. By the same argument of absolute values in "\\mathbb{C}" we find that "1+\\sqrt{-3} = (\\pm1)\\cdot (\\pm1 \\cdot (1+\\sqrt{-3}))" and same for "1-\\sqrt{-3}" . Therefore they are also irreducible.

In addition, while proving this we have studied all unit elements : "\\pm1" and so "1+\\sqrt{-3}" and "2" are not associated. Thus we conclude that "R" is not a unique factorization domain.