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Question. Let $G$ be a non-compact, finite dimensional Lie group, and let $(X, \mu)$ be a Radon measure space. Let $$\rho\colon G\to U(L^2(X))$$ be a unitary, strongly continuous, representation. Is it true that, if $g_n\to \infty$, then $$ \int_X \overline{h(x)}\rho_{g_n} f(x)\, d\mu\to 0, \qquad \forall f, h\in L^2(X)?$$ Appropriate hypotheses on $X$ may be assumed.

Here, $g_n\to \infty$ means that, for any compact $K\subset G$, $g_n\notin K$ for all sufficiently big $n\in\mathbb N$.

EDIT (for reference). I learned in the comments that a fairly complete answer is given by the "Howe-Moore vanishing theorem". I found a reference in this book (Bekka - Mayer, "Ergodic theory and topological dynamics of group actions on homogeneous spaces"); it is Theorem 1.1 at page 81.


This property is true in the following cases.

  1. $G=(\mathbb R^n, +)$, $X=\mathbb R^n$ with Lebesgue measure and $\rho_g f(x):=f(x-g)$.
  2. $G=(\mathbb R_{>0}, \cdot)$, $X=\mathbb R^n$ with measure $d\mu=\frac{dx}{\lvert x\rvert^n}$, and $\rho_g f(x):=f(x/g)$.
  3. $G=SU(1, 1)$, $X=\mathbb D$, the unit disk, with measure $d\mu=\frac{4dxdy}{(1-(x^2+y^2)^2)^2}$, and $$\rho_g f(z):=f\left(\frac{az+b}{\overline b z + \overline a}\right), \qquad g=\begin{bmatrix} a & b \\ \overline b & \overline a\end{bmatrix}, $$ where $|a|^2-|b|^2=1$.
  4. $G=SL(2, \mathbb R)$, $X=\mathbb H=\{z\in \mathbb C\ :\ \Im z>0\}$, with measure $d\mu=\frac{1}{y^2}dxdy$, and $$\rho_g f(z):=f\left(\frac{az+b}{c z + d}\right), \qquad g=\begin{bmatrix} a & b \\ c & d\end{bmatrix}, $$ where $ad-bc=1$. This case is actually isomorphic to the previous one, via the Cayley transform $z\mapsto \frac{z-i}{z+i}$ that maps $\mathbb H$ onto $\mathbb D$.

I learned the proof for the example 2 in this Math.SE post. The same idea works for the other examples, and it is even slightly simpler; indeed, in all three cases, for all $f\in L^2(X)$, and for all compact $A\subset X$, $$\lVert \rho_{g_n} f\rVert_{L^2(A)}\to 0, $$ provided that $g_n\to \infty$.$^{[1]}$ Thus, $$ \left\lvert \int_X \overline{h(x)}\rho_{g_n}f(x)\, d\mu\right\rvert \le \lVert h\rVert_{L^2(A)}\lVert \rho_{g_n}f\rVert_{L^2(A)}+ \lVert h\rVert_{L^2(X\setminus A)}\lVert \rho_{g_n}f\rVert_{L^2(X\setminus A)}. $$ The first summand tends to zero, while the second can be made arbitrarily small by choosing a sufficiently big $A$, because $h\in L^2(X)$. Here we use that $\rho$ is unitary.


$^{[1]}$ As mentioned, this case is slightly simpler than the dilation one, because for the dilation group we must also consider the possibility that the $L^2$ norm concentrates at the origin.

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    $\begingroup$ One needs to obviously exclude the trivial representation. At any case, for simple Lie groups (and semisimple with appropriate additions) you have the famous Howe-Moore theorem (your example is essentially SL2) For compact groups, the answer is negative, representations are finite dimensional in this case and tend to have almost periodic nature. This can be easily seen in the representations of $SO(2)$ on itself, and taking say a trig. polynomial. $\endgroup$
    – Asaf
    Commented Dec 3, 2019 at 20:54
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    $\begingroup$ What about $G = \mathbb{R}$, $X= \mathbb{C}$, and $\rho_g f(z) = f(e^{2\pi i g}z)$, i.e., $\rho$ rotates by an angle of $g$? Then $\rho_g = {\rm id}$ whenever $g$ is an integer, so it can't go to zero at infinity. $\endgroup$
    – Nik Weaver
    Commented Dec 3, 2019 at 20:57
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    $\begingroup$ @Asaf he said that $G$ is noncompact. $\endgroup$
    – Nik Weaver
    Commented Dec 3, 2019 at 20:58
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    $\begingroup$ @NikWeaver, one may take easy modifications, say semisimple with compact factors etc. $\endgroup$
    – Asaf
    Commented Dec 3, 2019 at 21:05
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    $\begingroup$ @Asaf: Of course, the $SU(1, 1)$ example is exactly the action of $SL_2(\mathbb R)$ on the hyperbolic plane, up to a Cayley transform, like you say. Thank you for pointing me to the Howe-Moore theorem. $\endgroup$ Commented Dec 3, 2019 at 23:00

2 Answers 2

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No, there are simple counterexamples. E.g., take $G = \mathbb{R}$ and $X = \mathbb{C}$ with Lebesgue measure, and define $\rho_t f(z) = f(e^{2\pi i t}z)$ for $t \in \mathbb{R}$ and $f \in L^2(\mathbb{C})$. Then $\rho_t$ is the identity for any integer $t$, so $\rho_n \to {\rm id}$ strongly, not to zero.

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    $\begingroup$ So, requiring $G$ to be noncompact isn't really effective, because one can take a quotient which is compact. $\endgroup$ Commented Dec 3, 2019 at 22:54
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    $\begingroup$ @NateEldredge, for non-abelian non-compact semi-simple groups, there are rarely compact quotients which are groups. That's partly why Nik's counterexample may not quite be decisive, depending what one is really wanting. $\endgroup$ Commented Dec 3, 2019 at 22:57
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    $\begingroup$ This counterexample does answer my question, and I have learned something.Thank you! I also see, thanks to Asaf, that there is literature concerning this; it goes under the name of "Howe-Moore property". $\endgroup$ Commented Dec 3, 2019 at 23:09
  • $\begingroup$ You are welcome! $\endgroup$
    – Nik Weaver
    Commented Dec 4, 2019 at 1:15
  • $\begingroup$ Or $G$ the reals, $X$ a singleton, $\mu$ the unit mass on it, $\rho$ any unirrep on $L^2(X)=\mathbf C$ (= any character of $G$). $\endgroup$ Commented Dec 4, 2019 at 22:40
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In the comments to Nik's answer, Nate Eldredge and Paul Garrett point out that the answer is not "truly noncompact"; indeed, in that answer the noncompact group $(\mathbb R, +)$ factors through $\mathbb R/\mathbb Z$. However, we can easily fix this and construct a "truly noncompact" counterexample, by adding a toroidal component with a dense linear flow.

Precisely, let $X=\mathbb T^2\times \mathbb C$ with Lebesgue measure, where $\mathbb T^2=\mathbb R^2/\mathbb Z^2$. Let $v=(\alpha, \beta)\in\mathbb R^2$ be such that $$\tag{1}\frac\beta\alpha\text{ is irrational, }$$ and define a unitary representation of $(\mathbb R, +)$ by $$ \rho_t f(x, z):=f(x-tv, e^{-it}z), \qquad \forall f\in L^2(\mathbb T^2\times \mathbb C).$$ Since there is $t_n\to \infty$ such that, say, $\lvert t_n v\rvert\le \frac1{100}$, this representation does not vanish at infinity, just like in Nik's answer; but now there is no compact quotient of $\mathbb R$ that $\rho$ factors through.

Remark. I considered $\mathbb T^2\times \mathbb C$, instead of just $\mathbb T^2$, to avoid the objection that $\mathbb T^2$ is compact. So, in this example, we have a non-compact group acting on a non-compact space, with an action that cannot be reduced to the one of a compact quotient. This is what I mean by "truly noncompact".

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  • $\begingroup$ @NateEldredge: this answer contains a little bit of discussion on your comment. $\endgroup$ Commented Dec 10, 2019 at 18:57
  • $\begingroup$ I noticed that somebody downvoted, and somebody retracted the up vote. May I ask why? $\endgroup$ Commented Dec 12, 2019 at 12:32

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