Prove that the quotient group GLn(R)/SLn(R) is isomorphic to the group R∗ (under multiplication).

Show that any dihedral group is isomorphic to a subgroup of GLn(R). (Be as precise as...

Show that any dihedral group is isomorphic to a subgroup of GLn(R). (Be as precise as possible, giving an explicit map between generators r, s of D2n and certain 2 × 2 matrices.)

Prove that the nonzero elements of a field form an abelian group under multiplication

Prove that the nonzero elements of a field form an abelian group under multiplication

Let R = {0, 2, 4, 6, 8} under addition and multiplication modulo 10. Prove that...

Let R = {0, 2, 4, 6, 8} under addition and multiplication modulo 10. Prove that R is a field.

Prove that if p is prime then Zp, where it is nonzero, is a group under...

Prove that if p is prime then Zp, where it is nonzero, is a group under multiplication.

Prove that if p is prime then Zp, where it is nonzero, is a group under...

Prove that if p is prime then Zp, where it is nonzero, is a group under multiplication.

Prove that, for any group G, G/Z(G) is isomorphic to Inn(G)

Prove that, for any group G, G/Z(G) is isomorphic to Inn(G)

5. What is the orbit of 3 in the group Z_7 under multiplication modulo 7? Is...

5. What is the orbit of 3 in the group Z_7 under multiplication modulo 7? Is 3 a generator? 6. What is the orbit of 2 in the group Z_7 under multiplication modulo 7? Is 2 a generator? 7. What is the residue of 101101 modulo 1101 using these as representations of polynomials with binary coefficients?

Show that the group Q^+ of positive rational numbers under multiplication is not definitely generated

Show that the group Q^+ of positive rational numbers under multiplication is not definitely generated

Let H be a normal subgroup of G. Assume the quotient group G/H is abelian. Prove...

Let H be a normal subgroup of G. Assume the quotient group G/H is abelian. Prove that, for any two elements x, y ∈ G, we have x^ (-1) y ^(-1)xy ∈ H

Let R be an integral domain. Prove that if R is a field to begin with,...

Let R be an integral domain. Prove that if R is a field to begin with, then the field of quotients Q is isomorphic to R