# Radial Anharmonic Oscillator: Perturbation Theory, New Semiclassical   Expansion, Approximating Eigenfunctions. I. Generalities, Cubic Anharmonicity   Case

**Authors:** J C del Valle, A V Turbiner

arXiv: 1908.03799 · 2019-11-12

## TL;DR

This paper develops a comprehensive perturbation and semiclassical expansion framework for the radial anharmonic oscillator, introducing an approximant that accurately models eigenfunctions across all coupling regimes and dimensions.

## Contribution

It introduces a novel interpolating approximant combining multiple expansions, achieving high-precision eigenfunction and energy calculations for the cubic anharmonic oscillator.

## Key findings

- Approximant deviates less than 10^{-4} from exact eigenfunctions.
- Achieves 7-8 significant digit accuracy in variational energies.
- Provides a unified approach valid for all coupling constants and dimensions.

## Abstract

For the general $D$-dimensional radial anharmonic oscillator with potential $V(r)= \frac{1}{g^2}\,\hat{V}(gr)$ the Perturbation Theory (PT) in powers of coupling constant $g$ (weak coupling regime) and in inverse, fractional powers of $g$ (strong coupling regime) is developed constructively in $r$-space and in $(gr)$ space, respectively. The Riccati-Bloch (RB) equation and Generalized Bloch (GB) equation are introduced as ones which govern dynamics in coordinate $r$-space and in $(gr)$-space, respectively, exploring the logarithmic derivative of wavefunction $y$. It is shown that PT in powers of $g$ developed in RB equation leads to Taylor expansion of $y$ at small $r$ while being developed in GB equation leads to a new form of semiclassical expansion at large $(g r)$: it coincides with loop expansion in path integral formalism. In complementary way PT for large $g$ developed in RB equation leads to an expansion of $y$ at large $r$ and developed in GB equation leads to an expansion at small $(g r)$. Interpolating all four expansions for $y$ leads to a compact function (called the {\it Approximant}), which should uniformly approximate the exact eigenfunction at $r \in [0, \infty)$ for any coupling constant $g \geq 0$ and dimension $D > 0$. Free parameters of the Approximant are fixed by taking it as a trial function in variational calculus. As a concrete application the low-lying states of the cubic anharmonic oscillator $V=r^2+gr^3$ are considered. It is shown that the relative deviation of the Approximant from the exact ground state eigenfunction is $\lesssim 10^{-4}$ for $r \in [0, \infty)$ for coupling constant $g \geq 0$ and dimension $D=1,2,\ldots$. In turn, the variational energies of the low-lying states are obtained with unprecedented accuracy 7-8 s.d. for $g \geq 0$ and $D=1,2,\ldots$.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1908.03799/full.md

## References

44 references — full list in the complete paper: https://tomesphere.com/paper/1908.03799/full.md

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Source: https://tomesphere.com/paper/1908.03799