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Quantum Algorithms
The inverse problem for Schwinger pair production
arXiv
Authors: Florian Hebenstreit
Year
2015
Paper ID
26986
Status
Preprint
Abstract Read
~2 min
Abstract Words
131
Citations
N/A
Abstract
The production of electron-positron pairs in time-dependent electric fields (Schwinger mechanism) depends non-linearly on the applied field profile. Accordingly, the resulting momentum spectrum is extremely sensitive to small variations of the field parameters. Owing to this non-linear dependence it is so far unpredictable how to choose a field configuration such that a predetermined momentum distribution is generated. We show that quantum kinetic theory along with optimal control theory can be used to approximately solve this inverse problem for Schwinger pair production. We exemplify this by studying the superposition of a small number of harmonic components resulting in predetermined signatures in the asymptotic momentum spectrum. In the long run, our results could facilitate the observation of this yet unobserved pair production mechanism in quantum electrodynamics by providing suggestions for tailored field configurations.
Why This Paper Matters
- It adds a 2015 reference point for readers tracking recent quantum research.
- The production of electron-positron pairs in time-dependent electric fields (Schwinger mechanism) depends non-linearly on the applied field profile.
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