Ph.D. Preliminary Examination in Algebra
January 25, 1999
1.
Let G be a finite group and Perm(G) the group of permutations of G viewed as a set. (a) Show that the map λ : G −→ Perm(G) that is defined by λ(σ)(τ ) = σ ◦ τ is a group homomorphism. (b) (c) Show that the map ρ1 defined by ρ1 (σ)(τ ) = τ ◦ σ is a homomorphism if and only if G is an abelian group. Show that the map ρ defined by ρ(σ)(τ ) = τ ◦ σ −1 is a homomorphism for every group G.
2.
Let A be an n × n matrix in a field K, let c(t) be the characteristic polynomial of A, and let m(t) be the minimal polynomial of A. Show that m(t) divides c(t) in the polynomial ring K[t].
3.
Show that the alternating group A4 has no subgroup of index 2.
4.
Let f (x) = x5 − 2 in Q[x], and let K be the splitting field of f (x) over Q. (a) Find generators for K as a Q-algebra. (b) Find the Galois group G of K over Q. (c) For each subgroup H of G describe the subfield of K which corresponds to H under the “fundamental correspondence of Galois theory”.
5.
Show that if a finite ring R admits an injective (ring) homomorphism from a field, then the number of elements of R must be a power of a prime number.
6.
Let R be a commutative ring, H a commutative R-algebra, and I an ideal in H. Show that H/I ⊗ R H/I ∼ = H ⊗RH I ⊗RH + H ⊗RI .
7.
Let the field L be a (finite) Galois extension of the field K. Define tr : L → K by tr(α) =
σ∈G
σ(α) .
Show that this trace map is surjective on K.
8.
Let R be a ring and P a left R-module. Show that the following two statements are equivalent: (a) (b) P is a direct summand of a finitely-generated free left R-module. There exist x1 , . . . , xn ∈ P , and f1 , . . . , fn ∈ HomR (P, R) such that the relation x = holds for all x ∈ P . fi (x)xi
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