Download Dual Banach algebras

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
page
29
page
30
page
31
page
32
page
33
page
34
page
35
page
36
page
37
page
38
page
39
page
40
page
41
page
42
Document related concepts

Basis (linear algebra) wikipedia , lookup

Hilbert space wikipedia , lookup

Fundamental theorem of algebra wikipedia , lookup

Bra–ket notation wikipedia , lookup

Representation theory wikipedia , lookup

Boolean algebras canonically defined wikipedia , lookup

Linear algebra wikipedia , lookup

Heyting algebra wikipedia , lookup

Universal enveloping algebra wikipedia , lookup

Homological algebra wikipedia , lookup

Oscillator representation wikipedia , lookup

Geometric algebra wikipedia , lookup

History of algebra wikipedia , lookup

Laws of Form wikipedia , lookup

Exterior algebra wikipedia , lookup

Complexification (Lie group) wikipedia , lookup

Clifford algebra wikipedia , lookup

Dual space wikipedia , lookup

Transcript 
Dual Banach algebras
Matthew Daws, St John’s College, Oxford
11th April 2006
W∗ -algebras
I
Recall that a W∗ -algebra is a C∗ -algebra A such that
A = E 0 for some Banach space E;
I
Then, automatically, the multiplication on A becomes
separately weak∗ -continuous, and the involution becomes
weak∗ -continuous;
I
There always exists a weak∗ -continuous ∗-representation
of A onto a von Neumann algebra inside B(H) for a
suitable Hilbert space H;
I
Furthermore, the E above is isometrically unique: if F is
any other Banach space such that A is isometrically
isomorphic to F 0 , then E and F are isometrically
isomorphic.
W∗ -algebras
I
Recall that a W∗ -algebra is a C∗ -algebra A such that
A = E 0 for some Banach space E;
I
Then, automatically, the multiplication on A becomes
separately weak∗ -continuous, and the involution becomes
weak∗ -continuous;
I
There always exists a weak∗ -continuous ∗-representation
of A onto a von Neumann algebra inside B(H) for a
suitable Hilbert space H;
I
Furthermore, the E above is isometrically unique: if F is
any other Banach space such that A is isometrically
isomorphic to F 0 , then E and F are isometrically
isomorphic.
W∗ -algebras
I
Recall that a W∗ -algebra is a C∗ -algebra A such that
A = E 0 for some Banach space E;
I
Then, automatically, the multiplication on A becomes
separately weak∗ -continuous, and the involution becomes
weak∗ -continuous;
I
There always exists a weak∗ -continuous ∗-representation
of A onto a von Neumann algebra inside B(H) for a
suitable Hilbert space H;
I
Furthermore, the E above is isometrically unique: if F is
any other Banach space such that A is isometrically
isomorphic to F 0 , then E and F are isometrically
isomorphic.
W∗ -algebras
I
Recall that a W∗ -algebra is a C∗ -algebra A such that
A = E 0 for some Banach space E;
I
Then, automatically, the multiplication on A becomes
separately weak∗ -continuous, and the involution becomes
weak∗ -continuous;
I
There always exists a weak∗ -continuous ∗-representation
of A onto a von Neumann algebra inside B(H) for a
suitable Hilbert space H;
I
Furthermore, the E above is isometrically unique: if F is
any other Banach space such that A is isometrically
isomorphic to F 0 , then E and F are isometrically
isomorphic.
Dual Banach algebras
I
A Dual Banach algebra is a Banach algebra which is a
dual space as a Banach space, and such that the
multiplication becomes separately weak∗ -continuous.
I
The weak∗ -topology allows us to, say, take limits, as the
unit ball becomes compact. For example, if a dual Banach
algebra A has a bounded approximate identity, then it has
an identity.
Dual Banach algebras
I
A Dual Banach algebra is a Banach algebra which is a
dual space as a Banach space, and such that the
multiplication becomes separately weak∗ -continuous.
I
The weak∗ -topology allows us to, say, take limits, as the
unit ball becomes compact. For example, if a dual Banach
algebra A has a bounded approximate identity, then it has
an identity.
Algebras of operators
I
Let E, F be Banach spaces, and form the projective tensor
b with norm
product E ⊗F
kτ kπ = inf
r
nX
i=1
I
kxi kkyi k : τ =
r
X
xi ⊗ yi
o
(τ ∈ E ⊗ F ).
i=1
b )0 = B(E, F 0 ), the space of all bounded linear
Then (E ⊗F
operators from E to F 0 , with duality given by
hT , x ⊗ y i = hT (x), y i (T ∈ B(E, F 0 ), x ∈ E, y ∈ F ).
I
b 0 = B(E 0 ), but we can check that the product is
So (E 0 ⊗E)
∗
weak -continuous if and only if E is reflexive.
Algebras of operators
I
Let E, F be Banach spaces, and form the projective tensor
b with norm
product E ⊗F
kτ kπ = inf
r
nX
i=1
I
kxi kkyi k : τ =
r
X
xi ⊗ yi
o
(τ ∈ E ⊗ F ).
i=1
b )0 = B(E, F 0 ), the space of all bounded linear
Then (E ⊗F
operators from E to F 0 , with duality given by
hT , x ⊗ y i = hT (x), y i (T ∈ B(E, F 0 ), x ∈ E, y ∈ F ).
I
b 0 = B(E 0 ), but we can check that the product is
So (E 0 ⊗E)
∗
weak -continuous if and only if E is reflexive.
Algebras of operators
I
Let E, F be Banach spaces, and form the projective tensor
b with norm
product E ⊗F
kτ kπ = inf
r
nX
i=1
I
kxi kkyi k : τ =
r
X
xi ⊗ yi
o
(τ ∈ E ⊗ F ).
i=1
b )0 = B(E, F 0 ), the space of all bounded linear
Then (E ⊗F
operators from E to F 0 , with duality given by
hT , x ⊗ y i = hT (x), y i (T ∈ B(E, F 0 ), x ∈ E, y ∈ F ).
I
b 0 = B(E 0 ), but we can check that the product is
So (E 0 ⊗E)
∗
weak -continuous if and only if E is reflexive.
Representing dual Banach algebras.
Let A be a dual Banach algebra with predual A∗ .
I
For each µ ∈ A∗ , the map A → A∗ given by a 7→ a · µ is
weakly-compact.
I
By interpolation space results, this map factors through a
reflexive left A-module Eµ .
I
We can check that the resulting representation A → B(Eµ )
is actually weak∗ -continuous.
I
Hence, if we let E be the l 2 -direct sum of all such Eµ , we
see that A is weak∗ -continuously isometric to a
weak∗ -closed subalgebra of B(E).
I
This looks very similar to the GNS construction for a
W∗ -algebra.
Representing dual Banach algebras.
Let A be a dual Banach algebra with predual A∗ .
I
For each µ ∈ A∗ , the map A → A∗ given by a 7→ a · µ is
weakly-compact.
I
By interpolation space results, this map factors through a
reflexive left A-module Eµ .
I
We can check that the resulting representation A → B(Eµ )
is actually weak∗ -continuous.
I
Hence, if we let E be the l 2 -direct sum of all such Eµ , we
see that A is weak∗ -continuously isometric to a
weak∗ -closed subalgebra of B(E).
I
This looks very similar to the GNS construction for a
W∗ -algebra.
Representing dual Banach algebras.
Let A be a dual Banach algebra with predual A∗ .
I
For each µ ∈ A∗ , the map A → A∗ given by a 7→ a · µ is
weakly-compact.
I
By interpolation space results, this map factors through a
reflexive left A-module Eµ .
I
We can check that the resulting representation A → B(Eµ )
is actually weak∗ -continuous.
I
Hence, if we let E be the l 2 -direct sum of all such Eµ , we
see that A is weak∗ -continuously isometric to a
weak∗ -closed subalgebra of B(E).
I
This looks very similar to the GNS construction for a
W∗ -algebra.
Representing dual Banach algebras.
Let A be a dual Banach algebra with predual A∗ .
I
For each µ ∈ A∗ , the map A → A∗ given by a 7→ a · µ is
weakly-compact.
I
By interpolation space results, this map factors through a
reflexive left A-module Eµ .
I
We can check that the resulting representation A → B(Eµ )
is actually weak∗ -continuous.
I
Hence, if we let E be the l 2 -direct sum of all such Eµ , we
see that A is weak∗ -continuously isometric to a
weak∗ -closed subalgebra of B(E).
I
This looks very similar to the GNS construction for a
W∗ -algebra.
Representing dual Banach algebras.
Let A be a dual Banach algebra with predual A∗ .
I
For each µ ∈ A∗ , the map A → A∗ given by a 7→ a · µ is
weakly-compact.
I
By interpolation space results, this map factors through a
reflexive left A-module Eµ .
I
We can check that the resulting representation A → B(Eµ )
is actually weak∗ -continuous.
I
Hence, if we let E be the l 2 -direct sum of all such Eµ , we
see that A is weak∗ -continuously isometric to a
weak∗ -closed subalgebra of B(E).
I
This looks very similar to the GNS construction for a
W∗ -algebra.
Derivations
I
I
I
I
A derivation from a Banach algebra A to a Banach
A-bimodule E is a linear map d such that
d(ab) = d(a) · b + a · d(b).
We say that an algebra is contractable if every derivation to
every bimodule is inner, that is, d(a) = a · x − x · a for some
x ∈ E. It is conjectured that contractable algebras are
finite-dimensional; this is true for C∗ -algebras, for example.
An algebra is amenable if every derivation to every dual
bimodule is inner. This is a richer class: for example, L1 (G)
is amenable if and only if the group is amenable. A
C∗ -algebra is amenable if and only if it is nuclear.
However, there are few amenable dual Banach algebras:
M(G) is amenable only when G is discrete (so that
M(G) = l 1 (G)) while an amenable von Neumann algebra
is of the form
n
M
C(X ) ⊗
Mni .
i=1
Derivations
I
I
I
I
A derivation from a Banach algebra A to a Banach
A-bimodule E is a linear map d such that
d(ab) = d(a) · b + a · d(b).
We say that an algebra is contractable if every derivation to
every bimodule is inner, that is, d(a) = a · x − x · a for some
x ∈ E. It is conjectured that contractable algebras are
finite-dimensional; this is true for C∗ -algebras, for example.
An algebra is amenable if every derivation to every dual
bimodule is inner. This is a richer class: for example, L1 (G)
is amenable if and only if the group is amenable. A
C∗ -algebra is amenable if and only if it is nuclear.
However, there are few amenable dual Banach algebras:
M(G) is amenable only when G is discrete (so that
M(G) = l 1 (G)) while an amenable von Neumann algebra
is of the form
n
M
C(X ) ⊗
Mni .
i=1
Derivations
I
I
I
I
A derivation from a Banach algebra A to a Banach
A-bimodule E is a linear map d such that
d(ab) = d(a) · b + a · d(b).
We say that an algebra is contractable if every derivation to
every bimodule is inner, that is, d(a) = a · x − x · a for some
x ∈ E. It is conjectured that contractable algebras are
finite-dimensional; this is true for C∗ -algebras, for example.
An algebra is amenable if every derivation to every dual
bimodule is inner. This is a richer class: for example, L1 (G)
is amenable if and only if the group is amenable. A
C∗ -algebra is amenable if and only if it is nuclear.
However, there are few amenable dual Banach algebras:
M(G) is amenable only when G is discrete (so that
M(G) = l 1 (G)) while an amenable von Neumann algebra
is of the form
n
M
C(X ) ⊗
Mni .
i=1
Derivations
I
I
I
I
A derivation from a Banach algebra A to a Banach
A-bimodule E is a linear map d such that
d(ab) = d(a) · b + a · d(b).
We say that an algebra is contractable if every derivation to
every bimodule is inner, that is, d(a) = a · x − x · a for some
x ∈ E. It is conjectured that contractable algebras are
finite-dimensional; this is true for C∗ -algebras, for example.
An algebra is amenable if every derivation to every dual
bimodule is inner. This is a richer class: for example, L1 (G)
is amenable if and only if the group is amenable. A
C∗ -algebra is amenable if and only if it is nuclear.
However, there are few amenable dual Banach algebras:
M(G) is amenable only when G is discrete (so that
M(G) = l 1 (G)) while an amenable von Neumann algebra
is of the form
n
M
C(X ) ⊗
Mni .
i=1
Connes-amenability
I
Let A be a dual Banach algebra, and let E be an
A-bimodule. Then E 0 is normal if the maps
(
a · µ,
0
A → E , a 7→
µ · a,
are weak∗ -continuous, for each µ ∈ E 0 .
I
Then A is Connes-amenable if every weak∗ -continuous
derivation from A to a normal dual bimodule is inner.
I
Volker Runde has shown that then M(G) is
Connes-amenable if and only if G is amenable.
I
If E is a reflexive Banach space with the approximation
property, then B(E) is Connes-amenable if and only if
K (E), the algebra of compact operators, is amenable. So
B(`p ) is Connes-amenable for 1 < p < ∞.
Connes-amenability
I
Let A be a dual Banach algebra, and let E be an
A-bimodule. Then E 0 is normal if the maps
(
a · µ,
0
A → E , a 7→
µ · a,
are weak∗ -continuous, for each µ ∈ E 0 .
I
Then A is Connes-amenable if every weak∗ -continuous
derivation from A to a normal dual bimodule is inner.
I
Volker Runde has shown that then M(G) is
Connes-amenable if and only if G is amenable.
I
If E is a reflexive Banach space with the approximation
property, then B(E) is Connes-amenable if and only if
K (E), the algebra of compact operators, is amenable. So
B(`p ) is Connes-amenable for 1 < p < ∞.
Connes-amenability
I
Let A be a dual Banach algebra, and let E be an
A-bimodule. Then E 0 is normal if the maps
(
a · µ,
0
A → E , a 7→
µ · a,
are weak∗ -continuous, for each µ ∈ E 0 .
I
Then A is Connes-amenable if every weak∗ -continuous
derivation from A to a normal dual bimodule is inner.
I
Volker Runde has shown that then M(G) is
Connes-amenable if and only if G is amenable.
I
If E is a reflexive Banach space with the approximation
property, then B(E) is Connes-amenable if and only if
K (E), the algebra of compact operators, is amenable. So
B(`p ) is Connes-amenable for 1 < p < ∞.
Connes-amenability
I
Let A be a dual Banach algebra, and let E be an
A-bimodule. Then E 0 is normal if the maps
(
a · µ,
0
A → E , a 7→
µ · a,
are weak∗ -continuous, for each µ ∈ E 0 .
I
Then A is Connes-amenable if every weak∗ -continuous
derivation from A to a normal dual bimodule is inner.
I
Volker Runde has shown that then M(G) is
Connes-amenable if and only if G is amenable.
I
If E is a reflexive Banach space with the approximation
property, then B(E) is Connes-amenable if and only if
K (E), the algebra of compact operators, is amenable. So
B(`p ) is Connes-amenable for 1 < p < ∞.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity
I
Let A ⊆ B(H) be a von Neumann algebra, and let
Ac = {a ∈ B(H) : ab = ba (b ∈ A)} be the commutant of
A in B(H).
I
An expectation for Ac is a norm-one projection
Q : B(H) → Ac .
I
A von Neumann algebra is injective if there is an
expectation for Ac .
I
We can use the structure theorem for weak∗ -continuous
∗-isomorphisms to show that the definition of injectivity
does not actually depend on the choice of representation
A ⊆ B(H).
I
So this definition makes sense for W∗ -algebras.
I
In fact, A is injective if and only if A is Connes-amenable.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
Injectivity for dual Banach algebras
Let A ⊆ B(E) be a dual Banach algebra.
I
A quasi-expectation for Ac is a bounded projection
Q : B(E) → Ac such that Q(aTb) = aQ(T )b for T ∈ B(E)
and a, b ∈ Ac .
I
An expectation is a quasi-expectation.
I
If A is Connes-amenable, then whenever A is realised as a
weak∗ -closed subalgebra of B(E), there is a
quasi-expectation B(E) → Ac .
I
We say that A is injective if there is always a
quasi-expectation for Ac .
I
So Connes-amenable implies injective.
The converse
I
Building on work of Runde, and again using interpolation
spaces extensively, the converse can be shown to hold.
I
That is, a dual Banach algebra A is Connes-amenable if
and only if whenever A ⊆ B(E), there is a
quasi-expectation for Ac .
I
However, unlike the von Neumann algebra case, we really
do need to check for all E;
I
For example, B(`p ⊕ `q ) is not Connes-amenable when
p, q ∈ (1, ∞) \ {2} are distinct. However, B(`p ⊕ `q )
obviously admits a quasi-expectation over itself.
The converse
I
Building on work of Runde, and again using interpolation
spaces extensively, the converse can be shown to hold.
I
That is, a dual Banach algebra A is Connes-amenable if
and only if whenever A ⊆ B(E), there is a
quasi-expectation for Ac .
I
However, unlike the von Neumann algebra case, we really
do need to check for all E;
I
For example, B(`p ⊕ `q ) is not Connes-amenable when
p, q ∈ (1, ∞) \ {2} are distinct. However, B(`p ⊕ `q )
obviously admits a quasi-expectation over itself.
The converse
I
Building on work of Runde, and again using interpolation
spaces extensively, the converse can be shown to hold.
I
That is, a dual Banach algebra A is Connes-amenable if
and only if whenever A ⊆ B(E), there is a
quasi-expectation for Ac .
I
However, unlike the von Neumann algebra case, we really
do need to check for all E;
I
For example, B(`p ⊕ `q ) is not Connes-amenable when
p, q ∈ (1, ∞) \ {2} are distinct. However, B(`p ⊕ `q )
obviously admits a quasi-expectation over itself.
The converse
I
Building on work of Runde, and again using interpolation
spaces extensively, the converse can be shown to hold.
I
That is, a dual Banach algebra A is Connes-amenable if
and only if whenever A ⊆ B(E), there is a
quasi-expectation for Ac .
I
However, unlike the von Neumann algebra case, we really
do need to check for all E;
I
For example, B(`p ⊕ `q ) is not Connes-amenable when
p, q ∈ (1, ∞) \ {2} are distinct. However, B(`p ⊕ `q )
obviously admits a quasi-expectation over itself.
Conclusion
I
This doesn’t provide an “easy” proof that
Connes-amenability and injectivity agree for W∗ -algebras,
as we do not generate representations on Hilbert spaces;
I
Indeed, which Banach spaces E do appear? What sort of
weak∗ -representation B(`p ⊕ `q ) → B(E) doesn’t allow a
quasi-expectation?
I
As above, K(E) is amenable if and only if B(E) is
Connes-amenable (for “nice” E). This allows an
“abtrast-nonsense” formulation of when K(E) is amenable,
in terms of (necessarily rather pathological) tensor
products of E. Can we use this to improve upon known
results of when K(E) is and is not amenable?
Conclusion
I
This doesn’t provide an “easy” proof that
Connes-amenability and injectivity agree for W∗ -algebras,
as we do not generate representations on Hilbert spaces;
I
Indeed, which Banach spaces E do appear? What sort of
weak∗ -representation B(`p ⊕ `q ) → B(E) doesn’t allow a
quasi-expectation?
I
As above, K(E) is amenable if and only if B(E) is
Connes-amenable (for “nice” E). This allows an
“abtrast-nonsense” formulation of when K(E) is amenable,
in terms of (necessarily rather pathological) tensor
products of E. Can we use this to improve upon known
results of when K(E) is and is not amenable?
Conclusion
I
This doesn’t provide an “easy” proof that
Connes-amenability and injectivity agree for W∗ -algebras,
as we do not generate representations on Hilbert spaces;
I
Indeed, which Banach spaces E do appear? What sort of
weak∗ -representation B(`p ⊕ `q ) → B(E) doesn’t allow a
quasi-expectation?
I
As above, K(E) is amenable if and only if B(E) is
Connes-amenable (for “nice” E). This allows an
“abtrast-nonsense” formulation of when K(E) is amenable,
in terms of (necessarily rather pathological) tensor
products of E. Can we use this to improve upon known
results of when K(E) is and is not amenable?
Related documents
Advanced Analysis Spring 2006
Advanced Analysis Spring 2006
Abstract. We establish versions of the Snake Lemma from homo-
Abstract. We establish versions of the Snake Lemma from homo-
Gabriela Bulancea () De- partment of Mathematics and Physics, University of
Gabriela Bulancea () De- partment of Mathematics and Physics, University of
On the Moreau-Rockafellar-Robinson condition in Banach spaces
On the Moreau-Rockafellar-Robinson condition in Banach spaces
extras_03_1
extras_03_1
SQUARE ROOTS IN BANACH ALGEBRAS
SQUARE ROOTS IN BANACH ALGEBRAS
Definition 1. Cc(Rd) := {f : R d → C, continuous and with compact
Definition 1. Cc(Rd) := {f : R d → C, continuous and with compact
Algebra 2 Homework: ACT Prep Assigned: 4-2-14 Due: 4-7
Algebra 2 Homework: ACT Prep Assigned: 4-2-14 Due: 4-7
Algebra
Algebra
Fox Chapel Area High School Mathematics Courses Mathematics
Fox Chapel Area High School Mathematics Courses Mathematics
2.2 Algebra 1 Section 2.2
2.2 Algebra 1 Section 2.2
GENERALIZED GROUP ALGEBRAS OF LOCALLY COMPACT
GENERALIZED GROUP ALGEBRAS OF LOCALLY COMPACT