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--- kazhdan_property [2019/09/06 12:27]
d.gromada
+++ kazhdan_property [2021/11/23 11:56] (current)
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 ====== Kazhdan property (T) ======
+This property was originally formulated by David Kazhdan for locally compact groups (see [[wp>Kazhdan's_property_(T)|Kazhdan's property (T)]]). This article is about its generalization to the quantum group setting.
 ===== Definition =====
@@ Line 5: / Line 7: @@
 The definition of Kazhdan property (T) for discrete quantum groups was formulated in [(ref:Fim10)].
-Let $G$ be a compact quantum group, $X\subset\Irr(G)$, and $\pi\colon C(G)\to B(H)$ a $*$-representation on a Hilbert space $H$. For $x\in\Irr(G)$, denote $u^x$ its representative acting on $H_x$ and put $U^x:= (\id\otimes\pi)u^x\in B(H_x)\otimes B(H)$.
+Let $G$ be a compact quantum group, $X\subset\Irr(G)$, and $\pi\colon C(G)\to B(H)$ a $*$-representation on a Hilbert space $H$. For $x\in\Irr(G)$, denote $u^x$ its representative acting on $H_x$ and put $U^x:=(\id\otimes\pi)u^x\in B(H_x)\otimes B(H)$.
 For $\epsilon>0$ we say that the unit vector $v\in H$ is $(X,\epsilon)$**-invariant** if for all $x\in X$ and all non-zero $\eta\in H_x$ we have
@@ Line 16: / Line 18: @@
 $$U^x(\eta\otimes v) = \eta\otimes v$$
 for all $x\in\Irr(G)$ and all $\eta\in H_x$.
+===== Results =====
+==== Stability results ====
+    * Suppose $H\subset G$. If $\hat G$ has (T), then also $\hat H$ has (T). [(ref:Fim10)]
+==== Examples ====
+The following quantum groups have the property (T).
+The following quantum groups do not have the property (T).
+    * $\hat O_N^+$ for $N\ge 2$ (since $\Z_2^{*N}$ does not have (T)) [(ref:Fim10)]
+    * $\hat U_N^+$ for $N\ge 2$ (since the free group $\mathbb{F}_N$ does not have (T)) [(ref:Fim10)]
+    * $\hat S_N^+$ for $N\ge 2$ [(ref:Fim10)]
+    * Any free group
+    * Any infinite Abelian discrete quantum group (since it is [[amenability|amenable]])
+===== Relation with other properties =====
+If $\Gamma=\hat G$ has (T), then
+    * $\Gamma$ is finitely generated [(ref:Fim10)]
+    * $\Gamma$ is [[Unimodularity|unimodular]] [(ref:Fim10)]
+Discrete quantum group $\Gamma=\hat G$ has (T) if...
+Discrete quantum group $\Gamma$ has the [[haagerup_property|Haagerup property]] and property (T) if and only if $\Gamma$ is [[compact_quantum_group#Finite quantum groups|finite]]  [(ref:DFSW13)].
 ===== References =====
@@ Line 27: / Line 61: @@
 )]
-[(ref:BCF18>>
-title     : Topological generation and matrix models for quantum reflection groups
-year      : 2018
-author    : Michael Brannan, Alexandru Chirvasitu, Amaury Freslon
-url       : https://arxiv.org/abs/1808.08611
-)]
-[(ref:Chi15>>
+[(ref:DFSW13>>
-title     : Residually finite quantum group algebras
+author    : Matthew Daws, Pierre Fima, Adam Skalski, Stuart White
-journal   : Journal of Functional Analysis
+title     : The Haagerup property for locally compact quantum groups
-volume    : 268
+journal   : Journal für die reine und angewandte Mathematik
-number    : 11
+volume    : 2016
-pages     : 3508–3533
+number    : 711
-year      : 2015
+pages     : 189–229
-doi       : https://doi.org/10.1016/j.jfa.2015.01.013
+year      : 2013
-url       : http://www.sciencedirect.com/science/article/pii/S0022123615000373
+doi       : 10.1515/crelle-2013-0113
-author    : Alexandru Chirvasitu
+url       : https://doi.org/10.1515/crelle-2013-0113
 )]
@@ Line 58: / Line 86: @@
 )]
-[(ref:Sol05>>
-author    : Piotr M. Sołtan
-doi       : 10.1215/ijm/1258138137
-journal   : Illinois Journal of Mathematics
-number    : 4
-pages     : 1245–1270
-publisher : Duke University Press
-title     : Quantum Bohr compactification
-url       : https://doi.org/10.1215/ijm/1258138137
-volume    : 49
-year      : 2005
-)]
 ~~REFNOTES ref ~~

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