10. Is S= {(a, b)|a +b= 0} a subring of ZxZ Jastify your answer. I1. Let S be the subset of MR) consisting of all matrices of the form ) (4) Prove that S'is a ring isa right identity in S(meaning that AJ = A for (b) Show that J every A in S). (e) Show that Jis not a left identity in S by finding a matrix Bin S such that JB + B. For more information about S, sec Exercise 41. 12. Let 49 denote the set fa t bla, beZ}. Show that Z[g is a subring of C. 13. Let ZV2]denote the set {a + BV2|4, beZ). Show that Z[V2] is a subring of R. Soe Example 20.] 14. Let Tbe the ring in Example 8. Let S = {S€T\f{2) = 0}. Prove that Sis a subring of T. 15. Write out the addition and multiplication tables for

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po Thomas W. Hungerford - Abstrac X b My Questions | bartleby + O File | C:/Users/angel/Downloads/Thomas%20W.%20Hungerford%20-%20Abstract%20Algebra_%20AN%20lntroduction-Cengage%20Learning%20(2014).pdf ... Flash Player will no longer be supported after December 2020. Turn off Learn more of 621 -- A Read aloud V Draw F Highlight O Erase 77 10. Is S= {(a, b)|a + b = 0} a subring of Z x Z? Justify your answer. 11. Let S be the subset of M(R) consisting of all matrices of the form (a) Prove that S is a ring. (b) Show that J = every A in S). (c) Show that Jis not a left identity in S by finding a matrix Bin S such that is a right identity in S (meaning that AJ = A for JB + B. For more information about S, see Exercise 41. 12. Let Z denote the set {a + bi |a, beZ}. Show that Z[] is a subring of C. 13. Let Z[V2] denote the set {a + bV2|a, beZ}. Show that Z[V2] is a subring of R. See Example 20.] 14. Let Tbe the ring in Example 8. Let S = {feT|f(2) = 0}. Prove that S is a subring of T. 15. Write out the addition and multiplication tables for (a) Zz x Z; (b) Zz × Z, (c) Z, x Z, -G )- 16. Let A = and 0 = in M(R). Let S be the set of all matrices B such that AB = 0. (a) List three matrices in S. [Many correct answers are possible.] (b) Prove that Ss is a subring of M(R). [Hint: If B and Carc in S, show that B + Cand BC are in S by computing A(B + C) and A(BC).] 17. Define a new multiplication in Z by the rule: ab = 0 for all a, b, eZZ Show that with ordinary addition and this new multiplication, Z is a commutative ring. 18. Define a new multiplication in Z by the rule: ab = 1 for all a, b, EZ. With ordinary addition and this new multiplication, is Z is a ring? 19. Let S = {a, b, c} and let P(S) be the set of all subsets of S; denote the elements of P(S) as follows: S = {a, b, c}; D = {a, b}; E= {a, c}; F= {b, c}; A = {a}; B= {b}; C= {c}; 0 = Ø. Define addition and multiplication in P(S) by these rules: M + N = (M – N) U (N – M) and MN = MON. Write out the addition and multiplication tables for P(S). Also, see Exercise 44. R 20 Show that the subset P - ibring Doer P hare