In a Hilbert space setting, Pauli's well-known theorem Pauli's theorem asserts that no self-adjoint operator exists that is conjugate to a semibounded or discrete Hamiltonian [58]. Pauli's argument goes as follows. Assume that there exists a self-adjoint operator T conjugate to a given Hamiltonian H, that is, [T,H]=iLatin small letter h with stroke I such an operator conjugate to the Hamiltonian is known as a time operator. Since T is self-adjoint, the operator U ε=exp(-iεT) is unitary for all real number ε. Now if φE is an eigenvector of H with the eigenvalue E, then, according to Pauli, the conjugacy relation [T,H]=iLatin small letter h with stroke I implies that T is a generator of energy shifts so that (E+ε)φE+e; this means that H has a continuous spectrum spanning the entire real line because ε is an arbitrary real number. Hence, the 'inevitable' conclusion that if the Hamiltonian is semibounded or discrete no self-adjoint time operator T will exist © 2010 Springer-Verlag Berlin Heidelberg.
CITATION STYLE
Galapon, E. A. (2009). Post Pauli’s theorem emerging perspective on time in quantum mechanics. Lecture Notes in Physics, 789, 25–63. https://doi.org/10.1007/978-3-642-03174-8_3
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