Algebra Prelim, August 2011
Do all problems
- Prove that there is no simple group of order 380.
- Let k be a field with | k| = 7, let n be a positive
integer, and let f, g be coprime polynomials in
k[x1,..., xn].
If
f3 - g3 = h3 for some nonzero polynomial
h∈k[x1,..., xn], prove that there exists
p∈k[x1,..., xn] and
u∈k such that
f - g = up3.
Hint: factor f3 - g3 as a product of three polynomials, and note
that these polynomials are pairwise coprime.
- Let R be a PID, let p be a prime in R, and let
M, N be finitely generated left R-modules such that
pM≌pN. Assume that if
0≠m∈M or N and
pm = 0, then Rm is not a direct summand of M or N
respectively (i.e. there is no submodule X such that
Rm⊕X = M or N). Prove that
M≌N.
- Let
f (x)∈Q[x] be an irreducible polynomial of degree
9, let K be a splitting field for f over
Q, and let
α∈K be a
root of f. Suppose that
[K : Q] = 27. Prove that
Q(α) contains a field of degree 3 over
Q.
- Let p be a prime and let A denote all pn-th roots of unity in
C. Thus A is the abelian subgroup of the nonzero
complex numbers under multiplication defined by
{e2πim/pn | m, n∈N}, in particular A is
a
Z-module. Determine
A⊗ZA.
- Let k be a field, let
A∈M3(k), the 3 by 3 matrices
with entries in k, and suppose the characteristic polynomial of A
is x3. Prove that A has a square root, that is a matrix
B∈M3(k) such that B2 = A, if and only if the minimal polynomial
of A is x or x2.
- Let R be an integral domain, let n be a positive integer, let
S be a subset of the polynomial ring in n variables
R[x1,..., xn], and define
Z(S) = {(r1,..., rn)∈Rn | f (r1,..., rn) = 0 for all
f∈S}, the zero set of S. Prove that there exists a finite
subset T of S such that
Z(S) = Z(T).
Peter Linnell
2011-08-13