Quantum and Thermal Properties of the Klein-Gordon Inverted Harmonic Oscillator with Physical Applications

Abstract

We develop a systematic framework for the quantum and thermal properties of a Klein-Gordon scalar field subject to an inverted harmonic potential -12 m2ω2 x2. Starting from a non-Hermitian momentum substitution P P - mωx, we employ a symplectic phase-space rotation V = \![-π8(xp+px)] to map the system onto an analytically tractable effective harmonic oscillator evaluated at xeiπ/4. This allows us to define a well-regulated partition function Z(β,ω,m) and derive closed-form expressions for the free energy, entropy, and thermal correlation functions. We then apply this framework to three physical settings: (i) scalar field fluctuations during cosmological inflation, (ii) quantum fields near black-hole horizons, and (iii) order-parameter dynamics near second-order phase transitions in condensed matter. Our results unify previously scattered results in the literature and provide new predictions for the finite-temperature spectral density and entanglement entropy of unstable quantum systems.