Suppose that R is a domain satisfying the ascending chain condition on principal ideals. Show that...
Let R={1 € Q[2] : [0) € Z}. (a) Show that R is an integral domain and R* = {+1}. (b) Show that irreducibles of Rare Ep for primes pe Z, and S() ER with (0 €{+1} which are irreducible in Q[r]. (c) Show that r is not a product of irreducibles, and hence R does not satisfy the ascending chain condition for principal ideals.
Prove/Justify. help plz. Remark 8.46. The following facts are easily verified. (a) (A) is the intersection of all ideals containing A. (b) If R is commutative, then (a)-aR :-|ar l r є R. Example 8.47. In Z, nZ = (n) = (-n). In fact, these are the only ideals in Z (since these are the only subgroups). So, all the ideals in Z are principal. If m and n are positive integers, then nZ C mZ if and only if...
Let a EC Z such that a? EZ and Rea=0. Let N: Z[0] → Z:2H |212. (a) Show that N() NU {0} for all ze Z[a], and that if ry in Za], then N (2) N(y). (b) Show that Z[a] satisfies the ascending chain condition for principal ideals. (e) (Bonus) Show that Z[iV2 is a Euclidean domain. (Hint: there's a proof in the textbook that Z[i] is a Euclidean domain that you can modify.) (d) Show that Ziv5) is not...
Let a EC Z such that a? EZ and Rea=0. Let N: Z[0] → Z:2H |212. (a) Show that N() NU {0} for all ze Z[a], and that if ry in Za], then N (2) N(y). (b) Show that Z[a] satisfies the ascending chain condition for principal ideals. (e) (Bonus) Show that Z[iV2 is a Euclidean domain. (Hint: there's a proof in the textbook that Z[i] is a Euclidean domain that you can modify.) (d) Show that Ziv5) is not...
Let a EC Z such that a? EZ and Rea=0. Let N: Z[0] → Z:2H |212. (a) Show that N() NU {0} for all ze Z[a], and that if ry in Za], then N (2) N(y). (b) Show that Z[a] satisfies the ascending chain condition for principal ideals. (e) (Bonus) Show that Z[iV2 is a Euclidean domain. (Hint: there's a proof in the textbook that Z[i] is a Euclidean domain that you can modify.) (d) Show that Ziv5) is not...
From Goodman's "Algebra: Abstract and Concrete" 6.6.7. Show that R = Z + xQ[x] does not satisfy the ascending chain condition for principal ideals. Show that irreducibles in R are prime.
Suppose R is a principal ideal domain, and let S be a multiplicatively closed subset of R not containing 0. Show that S-R is a principal ideal domain. Let I be an ideal of a principal ideal domain R. Show that R/I is a principal ideal domain if and only if I is prime.
Q5: (10 pts) Let K > 0 and f R R satisfying the condition lf(x)-f(y) | Klx-y | for all x, y E R. Show that f s continuous at every point CER Q5: (10 pts) Let K > 0 and f R R satisfying the condition lf(x)-f(y) | Klx-y | for all x, y E R. Show that f s continuous at every point CER
Let a and b be non-zero elements of a principal ideal domain R, and let 1 = (a) and I = (6). Show that the following are cquivalent: (i) I and I are comaximal. (ii) In J = II. (iii) ab is a least common multiple of a and b. (iv) 1 = ged(a,b).
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 =...