Rayleigh-Ritz Variational Method in The Complex Plane

Abstract

We present a systematic study of the Rayleigh--Ritz variational method for quantum oscillators in the Segal--Bargmann space. We rigorously derive the normalizability condition |α| < 12 for generalized Gaussian trial functions (z) = eα z2 + β z through convergence analysis of Gaussian integrals in the complex plane. Applications to the harmonic oscillator demonstrate exact recovery of the ground state in Segal--Bargmann space when the trial family contains the true solution. For the quartic anharmonic oscillator (H = -12∂x2 + 12x2 + λ x4), adaptive Gaussian ans\"atze in position space yield a cubic stationarity equation and perturbative energy expansions beyond first order, capturing anharmonic wavefunction narrowing. In contrast, monomial trial functions (n(z) = zn) in the Segal--Bargmann space -- while providing rigorous upper bounds En = n + 12 + 3λ4(2n2 + 2n + 1) for excited states -- lack width adaptability and are limited to first-order accuracy for ground-state calculations. We further analyze displaced Gaussians and displaced monomials for asymmetric potentials (e.g., x3 + x4), showing that displacement parameters are essential to capture parity breaking and stabilization effects (E0 ≈ 12 + 3μ4 - 9λ24 + ·s).