Prove that the only ring homomorphism from Q (rational numbers) to Q (rational numbers) is the...

Prove the following: (By contradiction) If p,q are rational numbers, with p<q, then there exists a...

Prove the following: (By contradiction) If p,q are rational numbers, with p<q, then there exists a rational number x with p<x<q.

Recall that Q+ denotes the set of positive rational numbers. Prove that Q+ x Q+ (Q+...

Recall that Q+ denotes the set of positive rational numbers. Prove that Q+ x Q+ (Q+ cross Q+) is countably infinite.

Linear Algebra Prove that Q, the set of rational numbers, with the usually addition and multiplication,...

Linear Algebra Prove that Q, the set of rational numbers, with the usually addition and multiplication, is a field.

Let I be an ideal of the ring R. Prove that the reduction map R[x] →...

Let I be an ideal of the ring R. Prove that the reduction map R[x] → (R/I)[x] is a ring homomorphism.

4. (30) Let C be the ring of complex numbers,and letf:C→C be the map defined by...

4. (30) Let C be the ring of complex numbers,and letf:C→C be the map defined by f(z) = z^3. (i) Prove that f is not a homomorphism of rings, by finding an explicit counterex- ample. (ii) Prove that f is not injective. (iii) Prove that the principal ideal I = 〈x^2 + x + 1〉 is not a prime ideal of C[x]. (iv) Determine whether or not the ring C[x]/I is a field.

describe all the ring homomorphism from the the ring ZxZ to Z?

describe all the ring homomorphism from the the ring ZxZ to Z?

3. Assume √2 ∈R. Let S = { rational numbers q : q < √2 }....

3. Assume √2 ∈R. Let S = { rational numbers q : q < √2 }. (a)(i) Show that S is nonempty. (ii) Prove that S is bounded from above, but is not bounded from below. (b) Prove that supS = √2.

Let f : Z → Z be a ring isomorphism. Prove that f must be the...

Let f : Z → Z be a ring isomorphism. Prove that f must be the identity map. Must this still hold true if we only assume f : Z → Z is a group isomorphism? Prove your answer.

6. Define S={q∈Q:−√3< q <√3}, where Q denotes the rational numbers. Prove that S can not...

6. Define S={q∈Q:−√3< q <√3}, where Q denotes the rational numbers. Prove that S can not be the set of subsequential limits of any sequence (sn) of reals. Please be very verbose. I already have the answer to this question as a contradiction. It is okay if you use a contradiction, however please explain thoroughly.

Suppose φ:Q→Z is a homomorphism (both groups are under addition). Prove that φ is the zero...

Suppose φ:Q→Z is a homomorphism (both groups are under addition). Prove that φ is the zero map, i.e., φ(x) = 0 for all x ∈ Q.