Graph products of completely positive maps

Introduction Main result Consequences

Graph products of completely positive maps Scott Atkinson Vanderbilt University

ECOAS 2017 S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Fix Γ = (V , E ) a simplicial (undirected, no single-vertex loops, at most one edge between vertices) graph. Assign an algebra Av to each vertex v ∈ V . If (v , w ) ∈ E then Av and Aw commute. If (v , w ) ∈ / E then Av and Aw have no relations. Edgeless graphs ; free products Complete graphs ; tensor products S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Graph products of groups Definition For each v ∈ V let Gv be a group. The graph product FΓ Gv is given by the free product ∗v ∈V Gv modulo the relations [g , h] = 1 whenever g ∈ Gv , h ∈ Gw , and (v , w ) ∈ E .

Example Right-angled Artin groups (FΓ Z) [Baudisch ’81] Right-angled Coxeter groups (FΓ (Z/2Z)) [Chiswell ’86]

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

In operator algebras: the product of many names

[Mlotkowski ’04]: Λ-free probability

[Caspers-Fima (preprint ’14) ’17]: Graph products of operator algebras

[Speicher-Wysocza´ nski ’16]: Mixtures of classical and free independence

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Universal graph product of C ∗ -algebras Definition For each v ∈ V let Av be a unital C ∗ -algebra. The universal graph product of {Av }v ∈V is the unique unital C ∗ -algebra FΓ Av satisfying the following universal property. 1

2

There exist unital ∗-homomorphisms ιv : Av → FΓ Av such that ιv (a)ιw (b) = ιw (b)ιv (a) whenever a ∈ Av , b ∈ Aw , (v , w ) ∈ E . For any unital C ∗ -algebra B with unital ∗-homomorphisms fv : Av → B such that fv (a)fw (b) = fw (b)fv (a) whenever a, b, v , w are as above, there exists a unique unital ∗-homomorphism FΓ fv : FΓ Av → B satisfying FΓ fv ◦ ιv0 = fv0 for every v0 ∈ V . S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Reduced words (of vertices) Bookkeeping is done by considering words with letters from V . We encode the commuting relations given by Γ with the equivalence relation on words generated by the following relations. (v1 , . . . , vi , vi+1 , . . . , vn ) ∼ (v1 , . . . , vi , vi+2 , . . . , vn )

if

vi = vi+1

(v1 , . . . , vi , vi+1 , . . . , vn ) ∼ (v1 , . . . , vi+1 , vi , . . . , vn )

if

(vi , vi+1 ) ∈ E .

Definition A word v = (v1 , . . . , vn ) is reduced if whenever vk = vl , k < l, there exists a p with k < p < l such that (vk , vp ) ∈ / E.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Reduced words (of elements) ˚v = ker(ϕv ). For each v ∈ V fix ϕv ∈ S(Av ) and let A Definition A reduced word in FΓ Av is an element a ∈ FΓ Av of the form ˚v and va = (v1 , . . . , vn ) is reduced. a = a1 · · · an where ak ∈ A k Scalar multiples of the unit are reduced by convention. Let Wred denote the set of reduced words of either vertices or elements–context will tell. Fact The linear span of Wred is dense in FΓ Av .

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Completely positive maps

Definition A map θ : A → B between C ∗ -algebras is completely positive if θ(n) : Mn (A) → Mn (B) (aij )ij 7→ (θ(aij ))ij is positive for every n ∈ N.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Graph product of ucp maps For each v ∈ V , let θv : Av → B be a unital completely positive (ucp) map. Densely define FΓ θv : FΓ Av → B as follows. ˚v , then put If a = a1 · · · an ∈ Wred with ak ∈ A k FΓ θv (a) = θv1 (a1 ) · · · θvn (an ) and extend linearly.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Main result

Theorem FΓ θv is ucp.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Reductions Write Θ for FΓ θv , and assume B ⊂ B(H). Suffices to show that for any n ∈ N, x1 , . . . , xn ∈ FΓ Av , ξ1 , . . . , ξn ∈ H, n X

hΘ(xi∗ xj )ξj |ξi i ≥ 0.

i,j=1

Can take x1 , . . . , xn ∈ Wred .

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Complete sets Definition A finite subset X ⊂ Wred is complete if it is closed under truncation. This naturally gives a partial order  with respect to truncation. Given a finite subset Y ⊂ Wred , let Y  denote the completion of Y . Final reduction: Show that for any complete set X ⊂ Wred and any function ξ : X → H, we have X hΘ(x ∗ y )ξ(y )|ξ(x)i ≥ 0. (1) x,y ∈X

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Non-commutative length Definition Fix v0 ∈ V . Let v = (v1 , . . . , vn , v0 ) be reduced. We let ..v..v0 denote the (right-hand) non-commutative length of v with respect to v0 , given by   .. .. v.v0 := Card {i|1 ≤ i ≤ n, (vi , v0 ) ∈ / E} . If v cannot be written with v0 at the right-hand end, put .. .. . . . . v.v0 = −1. If w ∈ FΓ Av is reduced, let .w .v0 = .vw .v0 . Given a finite set X of reduced words (of vertices or algebra elements), we define the (right-hand) non-commutative length of X with respect to v0 , denoted ..X ..v0 to be given by ..X .. := max ..w .. . v0 v0 w ∈X

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Standard form Definition Fix v0 ∈ V . Let x ∈ Wred be such that v0 ∈ x. Suppose y, c, b ∈ Wred , satisfy the following properties. x = yc(v0 )b; b is the word of smallest length so that yc(v0 )  x and .. . . . yc(v0 )..v0 = . {x} .v0 ; y is the word of smallest length so that y(v0 )  x and ..y(v ).. = .. {x} .. . 0 v0 v0 Then we say that x = yc(v0 )b is in standard form with respect to v0 . We extend this definition to reduced words of algebra elements.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Proceed by induction on |X |. Base case: |X | = 1: trivial. |X | ≥ 2: Let (v0 ) ∈ vX . Put n o . . . . X1 := x ∈ X . {x} .v0 = .X .v0 , and let x0 ∈ X1 be an element of maximal length in X1 . Say ˚v0 ). x0 = y0 c0 a0 b0 is in standard form with respect to v0 (a0 ∈ A Define n o ˚v0 ), vy = vy0 . Y1 := x ∈ X1 in standard form x = ycab (a ∈ A

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Consider the following decomposition. X X hΘ(w ∗ z)ξ(z)|ξ(w )i hΘ(x ∗ y )ξ(y )|ξ(x)i = x,y ∈X

w ,z∈X \Y1

+

X

hΘ(x ∗ x 0 )ξ(x 0 )|ξ(x)i

x,x 0 ∈Y1

X

+

2RehΘ(x ∗ z)ξ(z)|ξ(x)i.

x∈Y1 ,z∈X \Y1

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Cross-terms lemma ˚v0 , be in standard form with respect to Let x = ycab ∈ Wred , a ∈ A v0 . Then Θ(x ∗ z) = Θ(b ∗ a∗ c ∗ y ∗ z) = Θ(b ∗ a∗ )Θ(c ∗ y ∗ z) whenever z ∈ Wred satisfies either of the following conditions. . . . . 1 . {z} . v0 < . {x} .v0 . . . . 0 0 0 0 2 . {z} . v0 = . {x} .v0 but vy 6= vy 0 where z = y c a b is in standard form with respect to v0 .

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Stinespring construction for concatenation Consider C|X | with standard basis {ex }x∈X . (1) yields the following positive semi-definite sesquilinear form on H ⊗ C|X | given by hξ ⊗ ey |η ⊗ ex i = hΘ(x ∗ y )ξ|ηi.

Form the resulting Hilbert space H ⊗Θ C|X | .

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Stinespring construction for concatenation For each x ∈ X let Vx : H → H ⊗Θ C|X | be given by Vx (ξ) = ξ ⊗Θ ex .

Given x ∈ X with |x| = 1, define Lx : H ⊗Θ C|X | → H ⊗Θ C|X | as follows.  if xy ∈ /X  0 Lx (ξ ⊗Θ ey ) =  ξ ⊗Θ exy if xy ∈ X

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Proposition Lx is bounded. Yields Proposition Let X ⊂ Wred be a complete set and assume that for every ξ : X → H, (1) holds. Additionally assume that for ci , bi , ci bi ∈ X , Θ(bi∗ ci∗ cj ) = Θ(bi∗ )Θ(ci∗ cj ). Then we have the following inequality. [Θ(bi∗ ci∗ cj bj )]ij ≥ [Θ(bi∗ )Θ(ci∗ cj )Θ(bj )]ij

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

The previous proposition can be bootstrapped to obtain the following lemma. Y1 -square lemma N Let {xi }N i=1 ∈ (Wred ) be a finite sequence such that for every 1 ≤ i ≤ N, we have v0 ∈ vxi . For each 1 ≤ i ≤ N, let xi = yi ci ai bi ˚v0 ). Assume the be in standard form with respect to v0 (ai ∈ A following. 1

2

For every 1 ≤ i, j ≤ N, vyi = vyj ;  For every complete set X ( ({xi }N i=1 ) and any function ξ : X → H, (1) holds.

Then [Θ(xi∗ xj )]ij ≥ [Θ(bi∗ ai∗ )Θ(ci∗ yi∗ yj cj )Θ(aj bj )]ij . S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

The inductive hypothesis gives the following. X

hΘ(w ∗ z)ξ(z)|ξ(w )i =

w ,z∈X \Y1

X

hVw∗ Vz ξ(z)|ξ(w )i

w ,z∈X \Y1

=

X

hVz ξ(z)|Vw ξ(w )i

w ,z∈X \Y1

X 2 = Vw ξ(w ) w ∈X \Y1

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

The cross-terms lemma gives the following. X

2RehΘ(x ∗ z)ξ(z)|ξ(x)i

x∈Y1 ,z∈X \Y1

=

X

2RehΘ(b ∗ a∗ )Θ(c ∗ y ∗ z)ξ(z)|ξ(ycab)i

ycab∈Y1 ,z∈X \Y1

=

X

2RehVz ξ(z)|Vyc Θ(ab)ξ(ycab)i.

ycab∈Y1 ,z∈X \Y1

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

The Y1 -square lemma gives the following. X

hΘ(x ∗ x 0 )ξ(x 0 )|ξ(x)i

x,x 0 ∈Y1

≥

X

hΘ(b ∗ a∗ )Θ(c ∗ y ∗ y 0 c 0 )Θ(a0 b 0 )ξ(y 0 c 0 a0 b 0 )|ξ(ycab)i

x=ycab,x 0 =y 0 c 0 a0 b 0 ∈Y1

=

X

hVy 0 c 0 Θ(a0 b 0 )ξ(y 0 c 0 a0 b 0 )|Vyc Θ(ab)ξ(ycab)i

ycab,y 0 c 0 a0 b 0 ∈Y1

X 2 = Vyc Θ(ab)ξ(ycab) . ycab∈Y1

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Positive-definite functions

Definition Let G be a group and H be a Hilbert space. A function f : G → B(H) is positive-definite if for every finite subset {g1 , . . . , gn } ⊂ G , the n × n matrix   f (gi−1 gj ) ij is positive.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Positive-definite functions ↔ ucp maps

There is a 1-1 correspondence between positive-definite functions f : G → B(H), f (e) = 1 and ucp maps θ : C ∗ (G ) → B(H) in the following sense. If ug ∈ C ∗ (G ) denotes the unitary corresponding to the group element g ∈ G , then f → θf (ug ) := f (g ) fθ (g ) := θ(ug ) ← θ.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Graph product of positive-definite functions Definition Let H be a Hilbert space, and for each v ∈ V , let Gv be a group and fv : Gv → B(H) be positive-definite with fv (e) = 1. If (v , w ) ∈ E ⇒ fv (Gv ) and fw (Gw ) commute, then we define the graph product of the fv ’s, FΓ fv : FΓ Gv → B(H), as follows. 1

FΓ fv (e) = 1;

2

if for 1 ≤ k ≤ n, gk ∈ Gvk \ {1} and (v1 , . . . , vn ) ∈ Wred , then FΓ fv (g1 · · · gn ) := fv1 (g1 ) · · · fvn (gn ).

Theorem Let Gv , fv and H be as above. Then FΓ fv is positive-definite. S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Unitary dilation consequence

Theorem Let H be a Hilbert space, and let {Tv }v ∈V ⊂ B(H) be contractions such that if (v , w ) ∈ E then Tv and Tw doubly commute ([Tv , Tw ] = [Tv∗ , Tw ] = 0). Then there exist a Hilbert space K containing H and unitaries Uv ∈ B(K) for each v ∈ V such that for any polynomial p ∈ ChXv iv ∈V in |V | non-commuting indeterminates we have p({Tv }v ∈V ) = PH p({Uv }v ∈V )|H .

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Proof. Goal: obtain a ucp map Θ : FΓ C ∗ (Z) → B(H) such that Θ(p((xv )) = p((Tv )). Define the ucp map θv on the v th copy of C ∗ (Z) as follows.  m Tv if m ≥ 0 θv (xvm ) = (Tv∗ )−m if m < 0 Then the map Θ = FΓ θv : FΓ C ∗ (Z) = C ∗ (FΓ Z) → B(H) defined with respect to the canonical trace on C ∗ (Z) does the job.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Graph independence Definition Given a non-commutative probability space (A, ϕ), let {Av }v ∈V ⊂ A be a family of unital C ∗ -subalgebras. An element a ∈ C ∗ (∪v ∈V Av ) is reduced with respect to ϕ if a = a1 · · · am ˚v for 1 ≤ j ≤ m and (v1 , . . . , vm ) is reduced. where aj ∈ A j Definition Given a non-commutative probability space (A, ϕ), a family of unital C ∗ -subalgebras {Av }v ∈V ⊂ (A, ϕ) is Γ independent if 1 2

(v , v 0 ) ∈ E ⇒ Av and Av 0 commute; for any a ∈ C ∗ (∪v ∈V Av ) such that a is reduced with respect to ϕ, ϕ(a) = 0. S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Unitary dilation of graph independent contractions Theorem Given Γ independent contractions {Tv }v ∈V in the noncommutative probability space (B(H), ϕ), there exist a Hilbert space K containing H and unitaries {Uv }v ∈V ⊂ B(K) that are Γ independent with respect to ϕ ◦ Ad(PH ) such that for any polynomial p ∈ ChXv iv ∈V in |V | non-commuting indeterminates we have p({Tv }v ∈V ) = PH p({Uv }v ∈V )|H . Furthermore, this dilation is unique up to unitary equivalence if K is minimal.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

von Neumann’s inequality Theorem Let Γ = (V , E ) be a graph. Let H be a Hilbert space and {Tv }v ∈V ⊂ B(H) be contractions such that if (v , v 0 ) ∈ E then Tv and Tv 0 doubly commute ([Tv , Tv 0 ] = [Tv∗ , Tv 0 ] = 0). Let p ∈ ChXv iv ∈V be a polynomial in |V | non-commuting indeterminates. Then ||p({Tv }v ∈V )|| ≤ ||p({xv }v ∈V )||C ∗ (FΓ Z) where for each v ∈ V , xv denotes the unitary corresponding to the canonical generator of the v th copy of Z.

S. Atkinson

Graph products of completely positive maps

Introduction Main result Consequences

Positive-definite functions Unitary dilation von Neumann’s inequality

Thanks!

Preprint: arXiv:1706.07389

S. Atkinson

Graph products of completely positive maps