PT-Symmetric Quantum Mechanics
Abstract
This paper proposes to broaden the canonical formulation of quantum mechanics. Ordinarily, one imposes the condition H=H on the Hamiltonian, where represents the mathematical operation of complex conjugation and matrix transposition. This conventional Hermiticity condition is sufficient to ensure that the Hamiltonian H has a real spectrum. However, replacing this mathematical condition by the weaker and more physical requirement H=H, where represents combined parity reflection and time reversal PT, one obtains new classes of complex Hamiltonians whose spectra are still real and positive. This generalization of Hermiticity is investigated using a complex deformation H=p2+x2(ix)ε of the harmonic oscillator Hamiltonian, where ε is a real parameter. The system exhibits two phases: When ε≥0, the energy spectrum of H is real and positive as a consequence of PT symmetry. However, when -1<ε<0, the spectrum contains an infinite number of complex eigenvalues and a finite number of real, positive eigenvalues because PT symmetry is spontaneously broken. The phase transition that occurs at ε=0 manifests itself in both the quantum-mechanical system and the underlying classical system. Similar qualitative features are exhibited by complex deformations of other standard real Hamiltonians H=p2+x2N(ix)ε with N integer and ε>-N; each of these complex Hamiltonians exhibits a phase transition at ε=0. These PT-symmetric theories may be viewed as analytic continuations of conventional theories from real to complex phase space.
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