Prime ring

A ring R is prime if and only if the zero ideal {0} is a prime ideal in the noncommutative sense.

This being the case, the equivalent conditions for prime ideals yield the following equivalent conditions for R to be a prime ring:

• For any two ideals A and B of R, AB = {0} implies A = {0} or B = {0}.
• For any two right ideals A and B of R, AB = {0} implies A = {0} or B = {0}.
• For any two left ideals A and B of R, AB = {0} implies A = {0} or B = {0}.

Using these conditions it can be checked that the following are equivalent to R being a prime ring:

• All nonzero right ideals are faithful as right R-modules.
• All nonzero left ideals are faithful as left R-modules.

• Any domain is a prime ring.
• Any simple ring is a prime ring, and more generally: every left or right primitive ring is a prime ring.
• Any matrix ring over an integral domain is a prime ring. In particular, the ring of 2 × 2 integer matrices is a prime ring.

• A commutative ring is a prime ring if and only if it is an integral domain.
• A nonzero ring is prime if and only if the monoid of its ideals lacks zero divisors.
• The ring of matrices over a prime ring is again a prime ring.

• {{Citation | last1=Lam | first1=Tsit-Yuen | title=A First Course in Noncommutative Rings | publisher=Springer-Verlag | location=Berlin, New York | edition=2nd | isbn=978-0-387-95325-0 |mr=1838439 | year=2001}}

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Category:Ring theory