Only question 13 ,thx! 13. If M is a finitely generated module over the P.I.D. R,...
ONLY question 25 thx 24. Prove that in a Boolean ring every finitely generated ideal is principal. 25. Assume R is commutative and for each a e R there is an integer n > 1 (depending on a) such that an = a. Prove that every prime ideal of R is a maximal ideal.
(7) Let R be a ring with 1 and let M be a unital left R-module. If I is a right ideal of R then the annihilator of I in M is defined to be AnnM(I) = {m € M: am=0 for all a € 1}. (a) Prove that Annm(I) is a submodule of M. (b) Take R = Z and M = Z/3Z Z/102 x Z/4Z. If I = 2Z describe AnnM(I) as a direct product of cyclic groups.
ar URSCH. In act prove that the identity map is the only ring isomorphism of 2. Let a and b be nonzero elements of the Unique Factorization Domain R. Prove that a and b have a least common multiple (cf. Exercise 11 of Section 1) and describe it in terms of the prime factorizations of a and b in the same fashion that Proposition 13 describes their greatest common divisor. 3. Determine all the representations of the integer 2130797 =...
Let M be a 8:27 AM right R-module, N be an (R,T)-bimodule, and L be a left T-module. Let e: (MN)* L M R (NB, L) be given by e (moon, e) = m (nol). Let m.con, mone MORN, and lEl. Prove e (lm, BR.) + (m₂ Ore), d)= e(m, on, d) + (mon, e). This is the proof I'm working on. I need to show the map I've defined (and which is defined towards the middle of the proof)...
I need to answer #3 could be done in only one way, we see that if we take the table for G and rename the identity e, the next element listed a, and the last element b, the resulting table for G must be the same as the one we had for G. As explained in Section 3, this renaming gives an isomorphism of the group G' with the group G. Definition 3.7 defined the notion of isomorphism and of...