# A simple argument that small hydrogen may exist

**Authors:** J. Vavra

arXiv: 1906.08243 · 2026-05-12

## TL;DR

This paper explores whether small, compact electron-proton configurations, or 'small hydrogen', are theoretically plausible within relativistic and finite-size constraints, without invoking quantum electrodynamics.

## Contribution

It develops a phenomenological energy-balance framework showing such states are not ruled out by basic relativistic and stationarity constraints.

## Key findings

- Characteristic energy scales around 260 keV and 100 keV are identified.
- Relativistic kinematics and finite-size effects do not exclude small hydrogen states.
- Implications for astrophysics, fusion, and dark matter are discussed.

## Abstract

This paper examines whether a compact electron-proton configuration (small hydrogen) with a characteristic radius of a few femtometers is excluded by basic relativistic kinematics and simple stationarity constraints. Motivated by earlier discussions of formally deep relativistic energy scales in Dirac-based treatments, a phenomenological, virial-inspired energy-balance framework that incorporates relativistic kinetic energy, finite-size regularization of the central field, and order-of-magnitude spin-magnetic and spin-orbit contributions is developed in this paper. Within this framework, self-consistent characteristic scales associated is obtained with a hypothetical compact configuration without invoking Dirac or quantum-electrodynamics (QED) bound-state eigenvalues. The resulting scales-namely, a central energy scale of about 260 keV and a characteristic spin-dependent scale of order of 100 keV-define concrete experimental and observational energy ranges of interest. The present study does not establish the existence, formation probability, lifetime, or dynamical stability of such states. Rather, it shows that relativistic kinematics, finite-size effects, and virial-inspired stationarity constraints do not, by themselves, rule out compact stationary electron-proton configurations within the assumptions of the model. If such states were realized in nature and possessed radiative or interaction channels, those states may have implications for astrophysics, fusion concepts, and dark-matter phenomenology.

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Source: https://tomesphere.com/paper/1906.08243