Asao Arai
Generalized Weak Weyl Relation and Decay of Quantum Dynamics
(93K, LaTex209)

ABSTRACT.  Let $H$ be a self-adjoint operator on a Hilbert space ${\cal H}$, 
$T$ be a symmetric operator on ${\cal H}$ and $K(t)$ ($t\in \R$) be a 
bounded self-adjoint operator on ${\cal H}$. 
We say that $(T,H,K)$ obeys the {\it generalized weak Weyl relation} (GWWR) 
if $e^{-itH}D(T) \subset D(T)$ for all $t \in \R$ and 
$Te^{-itH}\psi=e^{-itH}(T+K(t))\psi, \forall \psi \in D(T)$ ( 
$D(T)$ denotes the domain of $T$). 
In the context of quantum mechanics where $H$ is the Hamiltonian 
of a quantum system, we call $T$ a {\it generalized time opeartor} of $H$. 
We first investigate, in an abstract framework, mathematical structures and 
properties of triples $(T,H,K)$ obeying the GWWR. 
These include the absolute continuity 
of the spectrum of $H$ restricted to a closed subspace of ${\cal H}$, 
an uncertainty relation between $H$ and $T$ (a 
\lq\lq{time-energy uncertainty relation}"), 
the decay property of transition probabilities $\left|\lang \psi,e^{-itH}\phi\rang 
\right|^2$ as $|t| \to \infty$ 
for all vectors $\psi$ and $\phi$ 
in a subspace of ${\cal H}$. 
We describe methods to construct various examples of triples $(T,H,K)$ 
obeying the GWWR. 
In particular we show that there exist generalized time operators 
of second quantization operators on Fock spaces (full Fock spaces, 
boson Fock spaces, fermion Fock spaces) which may have 
applications to quantum field models with interactions.