Unifying quantum tunneling: Mathematical framework offers new insights
by Staff Writers
Berlin, Germany (SPX) Apr 29, 2024

In quantum physics, phenomena are broadly categorized into 'perturbative', which are simpler to detect and calculate, and 'nonperturbative' which include complex processes like radioactive decay. Perturbative phenomena, such as the light from atoms and energy from solar cells, straightforwardly relate to Planck's constant. This tiny but crucial number enables the computation of these effects.

On the other hand, nonperturbative phenomena, exemplified by radioactive decay, arise from quantum effects allowing particles to escape atomic nuclei. This process, known as tunneling, involves overcoming formidable energy barriers, akin to digging a tunnel through them, potentially taking billions of years.

Researchers have strived to mathematically describe these challenging nonperturbative effects for over a century. Alexander van Spaendonck, involved in the recent study, highlighted the need for a unified approach to describe all tunneling phenomena within a single mathematical framework. This was achieved using the resurgence theory developed by French mathematician Jean Ecalle in the 1980s. This framework, designed to organize nonperturbative phenomena, was only fully utilized in quantum mechanics decades later due to the initial complexity and language barrier of Ecalle's work.

The culmination of this effort is the application of a 'transseries', a tool from Ecalle's resurgence toolbox, to describe tunneling phenomena across various quantum mechanics problems consistently. This method not only unified the description of tunneling phenomena but also clarified the 'Stokes' phenomenon', which describes sudden changes in the role of these phenomena.

According to van Spaendonck, the beauty of this structure was revealed through their research, showing a clear separation or 'factorization' into a minimal transseries for basic tunneling and a median transseries for more specific quantum settings.

This new mathematical structure could next be applied to understand 'wall-crossing', a variation in particle stability across different physical setups. This challenging issue could be addressed using the same unifying mathematical techniques, potentially leading to further significant advances in the field.

Research Report:Exact instanton transseries for quantum mechanics

Related Links
by Robert Schreiber
Understanding Time and Space