Date
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What we discussed/How we spent our time
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Jan 18
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This will be a course on noncommutative ring theory.
Grades will be based on HW.
We introduced rings as algebraic models of
End(A), where A is an abelian group.
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Jan 20
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We defined representations of rings,
k-algebras,
and representations of k-algebras.
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Jan 23
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Categories and their representations.
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Jan 25
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Semisimple modules and rings. We proved
that a complemented modular lattice is
relatively complemented. [This is part of a proof that
a module is a (direct) sum of simple modules iff its
submodule lattice is complemented.]
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Jan 27
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A module is a sum of simple submodules iff it is a direct sum of simple
submodules.
Any module with a complemented submodule lattice
is a sum of simple submodules.
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Jan 30
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A module that is a sum of simple submodules has a complemented
submodule lattice. A ring R is semisimple iff Sub(RR)
is complemented. A semisimple ring is left artinian,
left noetherian, and has only finitely
many isomorphism types of simple modules.
If D is a division ring, then Mn(D)
is semisimple. In fact, a finite product of rings of this type,
Mn1(D1)×Mn2(D2)×…×Mnk(Dk),
is semisimple.
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Feb 1
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Lm. R≅End(RR)
Schur's Lm. If S is a simple R-module, then End(S) is a division ring.
Schur's Lm for algebras.
Let k be a field, A a k-algebra, S a simple A-module.
(i) D:=End(S) is a k-division algebra.
(ii) If A is finite dimensional over k, then so are S and D.
(iii) If k is algebraically closed and A is f.d. over k, then D=k.
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Feb 3
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Snow day.
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Feb 6
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Matrix representation of homomorphisms between direct sums.
Wedderburn-Artin Theorem.
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Feb 8
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We proved a theorem characterizing simple artinian
rings in several ways. We discussed equivalence of categories
and started a proof that
RMod is equivalent to Mn(R)Mod.
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Feb 10
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We finished the proof that
RMod is equivalent to Mn(R)Mod.
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Feb 13
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Jacobson radical: basic properties.
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Feb 15
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The radical acts nilpotently on modules of finite length.
The radical of a left artinian ring is nilpotent.
A left artinian ring is J-ss iff it is ss.
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Feb 17
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Thm. (Hop.-Lev.) Any left artinian ring is left noetherian.
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Feb 20
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Thm. (Hop.-Lev.) TFAE:
(i) RR has finite length.
(ii) R is left artinian.
(iii)
(a) R/J is ss,
(b) J is nilpotent,
(c) Each power Jk is f.g. as a left ideal.
Thm. (Hop.-Lev., module version)
If R is semiprimary and M is an R-module, then TFAE:
(i) M is artinian.
(ii) M is noetherian.
(iii) M has a composition series.
Thm. U(R) is a union of J-cosets, and
U(R)/J = U(R/J).
Thm. (Amitsur)
If k is a field and A is a k-algebra of small dimension
(dimk(A)<|k|), then rad(A) is nil.
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Feb 22
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Behavior of the radical with respect to quotients.
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Feb 24
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The radical of a polynomial ring, part 1.
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Feb 27
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The radical of a polynomial ring, part 2.
A discussion of Koethe's conjecture.
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Feb 29
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Groups rings and algebras.
We started the proof of the strong form of Maschke's Theorem.
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Mar 7
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We finished the proof of Maschke's Theorem.
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Mar 9
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We discussed two open questions: Which groups algebras over fields
are J-s.s.? How do you compute the radical of a group algebra
over a field? We began discussing representation theory.
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Mar 12
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Terminology: representation of a k-algebra, irreducible representation,
reducible representation, completely reducible representation,
module affording a representation, character of a representation,
representation affording a character.
Thm. If A is a f.d. k-algebra,
A/rad(A) ≅
Mn1(D1)×…×
Mnr(Dr),
and M1, …,
Mr are the types of simple A-modules, then
(i) dimk(Mi) =
nidimk(Di)
(ii) dimk(A) = dimk(rad(A)) +
∑ ni2dimk(Di)
(iii) the natural map A→Mni(Di)
is surjective
For A = M2(ℝ), we computed the characters of
ℝ2 and A as A-modules. Then we did the
same thing with A replaced by the ring of upper triangular
2×2 matrices over ℝ.
Thm. If 0 → L→ M→ N→ 0 is exact, then
χM = χL + χN.
Cor. χM is the sum of the characters of the composition
factors of M (counting multiplicity).
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Mar 14
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Thm. If k is a field of characteristic zero, A is a f.d. k-algebra,
and M is a f.g. A-module, then χM determines
the composition factors of M.
(In fact, the proof shows that the same result holds in positive
characteristic provided char(k) > dimk(M).)
We gave examples to show that a restriction on characteristic
is essential in
the above theorem, namely
the case where k is a finite field, or when A is an
inseparable field extension of k. We discussed χK
in the situation where A=K is a field extension of k.
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Mar 16
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We began discussing representations of finite groups.
We described the f.d. representations
of G=ℤ5
over k=ℚ, ℝ, and ℂ,
along with the associated characters.
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Mar 19
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We began discussing representations of finite groups over
ℂ. We calculated the character table of S3.
We started on these notes,
and explained items (1)-(8).
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Mar 21
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We explained how representations and characters of G/N
can be lifted to G. We used this to calculate the character
table of D4. We discussed permutation representations
and their characters. We explained items (14)-(16) of the
character theory notes.
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Mar 23
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♦ ℂ[G] ≅ Mn1(D1)×
…×Mnr(Dr),
D1=…=Dr=ℂ
♦ |G|=∑ ni2
♦ χreg = ∑ ni χi
♦ r =
dimℂ(Z(ℂ[G]))
= class number of G
We found the character tables of ℤ3 and the
alternating group A4.
(We found the 3-dimensional irreducible
character of A4
both arithmetically and geometrically.)
We explained items (17) and (18) of the notes.
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Apr 2
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If U and V are G-modules, then we explained how to make
U*
and Homℂ(U,V) into
G-modules. We proved that
♦ χU*(g) =
χU(g-1) (=
χU(g)).
♦ χHomℂ(U,V)=
χU
χV.
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Apr 4
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We proved that
dimℂ(VG)=(1/|G|)*∑
χV(g)
We defined the inner product of class functions and showed that
⟨χU,χV⟩ =
dimℂ(Homℂ[G](U,V))
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Apr 6
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We proved row and column orthogonality. We observed that
χ is irreducible iff ⟨χ,χ⟩ = 1.
We computed the character table of S4.
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Apr 9
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We proved not-Burnside's Lemma.
We discussed
internal vs. external tensor product. The main points of the
discussion were:
♦ Representations/characters of internal tensor products
are derived from those of external tensor products via the
diagonal map Δ:G→G×G.
♦
The permutation representation of G×H on X×Y is the
external tensor product of the permutation representation of G on X
with the permutation representation of H on Y.
♦
χU#V(g,h) =
χU(g)χV(h).
♦
⟨χU#V,χM#N⟩=
⟨
χU,
χM
⟩
⟨
χV,
χN
⟩.
♦
The irreducible representations/characters of
G×H are exactly the #'s of the irreducible characters
of G with those of H.
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Apr 11
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We proved items (9)-(13), (27) of the notes.
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Apr 13
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We proved that a complex
number α satisfies a monic integer polynomial iff
it lies in (equivalently, generates) a subring of ℂ
that is finitely generated as an abelian group. We took these
equivalent conditions for the definition of
algebraic integer. We showed that the algebraic integers,
𝔸, form a ring, and that
𝔸∩ℚ = ℤ.
We showed that character values are algebraic integers.
We also showed that if Kj is the jth conjugacy
class of G, kj = |Kj|,
gj∈Kj
is an element representing
this class, κj is the sum of the elements
of the class, χi is an irreducible character
afforded by a representation
ρi:ℂ[G]→End(V),
then ρi(κj) =
(kjχi(gj)/χi(1))I.
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Apr 16
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We finished the character theory handout. (Finally!)
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Apr 18
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We constructed the character table of A5.
We proved Burnside's theorem
that no simple group has a (nonidentity) conjugacy class
of prime-power order. We
proved Burnside's theorem that any group whose order is divisible
by at most two distinct primes is solvable.
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Apr 20
|
We discussed the group determinant.
We identified groups that act on the character
table of G. (The group of linear characters,
which is isomorphic to G/[G,G],
acts on all irreducible characters. Consequence
for the symmetric group: odd degree characters
come in pairs.)
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Apr 23
|
If |G|=n and ω is a primitive nth root of unity, then
Gal(ℚ[ω]/ℚ)≅ℤn*
acts on the character values. This has the effect of permuting the
column headings and the row headings of the character table, X.
This yields uniquely determined
permutation matrices Pk and Qk
such that, if σk∈Gal(ℚ[ω]/ℚ),
then PkX=σk(X)=XQk.
The maps k↦Pk and
k↦Qk are isomorphic permutation representations
of Gal(ℚ[ω]/ℚ). This leads to the definitions
of rational and real elements/characters/groups. Sn
is rational (hence has rational integral character values)
and Dn is real.
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Apr 25
|
Jacobson Density Theorem.
The usual setup is that R is a ring, M is a left R-module, E=
End(RM), S = End(ME),
and φ:R→S:r↦λr
is the homomorphism of R into its double centralizer S.
Goals: (i) to show that when M is semisimple, then
φ maps R onto an M-dense subring of S, and (ii) to show
that if M is a direct sum of the simple left R-modules
(one copy of each type), then S is isomorphic to a product
of endomorphism rings of vectors spaces over division rings.
Together these show that for any ring R there is a dense
embedding of R/rad(R) into a product of endomorphism
rings of vector spaces.
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Apr 27
|
We achieved the goals identified in the previous
lecture. We defined primitive and semiprimitive rings.
We explained a proof strategy for statements about rings:
prove them for primitive rings, then semiprimitive rings,
then lift modulo the radical.
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Apr 30
|
Every algebraic structure is a subdirect product of subdirectly
irreducible (SI) quotients. An identity holds in an
algebraic structure iff it holds in every SI quotient.
Jacobson's Commutativity Theorem: If a ring R satisfies
xn=x for some n, then it satisfies xy=yx.
If there is a counterexample to the therem,
then it can be taken to be SI.
Any SI counterexample is a division ring whose
maximal subfields have size at most n.
It remains to show (i) if D is a division ring
with a finite maximal subfield, then D is finite,
and (ii) finite division rings are commutative.
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May 2
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We proved part of the double centralizer theorem.
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May 4
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We finished the proof of the double centralizer theorem.
We proved Wedderburn's Little Theorem.
We finished the proof of Jacobson's Commutativity Theorem.
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