AI Article Synopsis
- Laser wakefield acceleration (LWFA) is gaining global interest due to its promising potential to match classical accelerators, but challenges in stability and reliability hinder its widespread use.
- The study investigates how controlling laser wavefronts, particularly through introducing aberrations, affects electron beam characteristics in an LWFA accelerator, revealing that complex wavefronts can outperform the traditionally accepted Gaussian distribution.
- Findings demonstrate a clear relationship between different input wavefronts and the stability, acceleration, and injection of electron beams, suggesting improvements in laser tuning could enhance control over LWFA-generated electrons.
Article Abstract
Laser wakefield acceleration (LWFA) continues to grow and awaken interest worldwide, especially as in various applications it approaches performance comparable to classical accelerators. However, numerous challenges still exist until this can be a reality. The complex non-linear nature of the process of interaction between the laser and the induced plasma remains an obstacle to the widespread LWFA use as stable and reliable particle sources. It is commonly accepted that the best wavefront is a perfect Gaussian distribution. However, experimentally, this is not correct and more complicated ones can potentially give better results. in this work, the effects of tuning the laser wavefront via the controlled introduction of aberrations are explored for an LWFA accelerator using the shock injection configuration. Our experiments show the clear unique correlation between the generated beam transverse characteristics and the different input wavefronts. The electron beams stability, acceleration and injection are also significantly different. We found that in our case, the best beams were generated with a specific complex wavefront. A greater understanding of electron generation as function of the laser input is achieved thanks to this method and hopes towards a higher level of control on the electrons beams by LWFA is foreseen.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10611724 | PMC |
| http://dx.doi.org/10.1038/s41598-023-45737-5 | DOI Listing |
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