Plasma Wakefield Accelerators (PWFA) represent a disruptive candidate for next-generation high-energy accelerators. By providing accelerating gradients orders of magnitude higher than conventional radiofrequency (RF) technologies, PWFAs offer the potential to significantly reduce the scale of future light sources and high-energy colliders. In the realm of electron acceleration, PWFA has achieved major breakthroughs, particularly through the blowout regime, which has successfully demonstrated high-efficiency and high-quality electron acceleration.¹

However, the realization of a future electron-positron collider necessitates the high-quality acceleration of positrons. Historically, the blowout regime was deemed unsuitable for positrons because the exposed plasma ions within the cavity exert a strong transverse repulsive force on them. This "positron barrier" has remained a critical bottleneck for the advancement of PWFA technology toward a complete collider infrastructure.

II. Research Progress: Self-Consistent Electron Filamentation and Uniform Acceleration Theory

This study introduces an innovative and straightforward solution, achieving high-quality positron acceleration within the blowout regime for the first time. The key to this advance lies in the strategic loading of high-density positron bunches at the rear of the blowout cavity, which triggers a self-consistent nonlinear interaction between the positron bunch and the plasma wakefield. The space-charge force of the positron beam effectively confines plasma sheath electrons, inducing the formation of an extended, high-density on-axis electron filament.
This electron filament plays a dual role in achieving high-quality acceleration. First, its net negative charge counteracts the repulsive ion force, providing the essential transverse focusing required for stable, long-distance positron beam transport. Second, the unique coupling between the electron filament and the blowout boundary significantly modifies the longitudinal accelerating field. This research establishes the first theoretical model of nonlinear positron beam loading, proving that the field term induced by the filament effect can cancel out the field decay caused by the cavity boundary, thereby achieving a uniform accelerating field.

High-fidelity 3D particle-in-cell simulations have validated this theory, confirming that stable, high-gradient, and high-quality positron acceleration is achievable over long distances. Key performance metrics include: energy transfer efficiency >20%, normalized emittance ~1mm⋅mrad and induced energy spread ~1%.

III. Future Outlook: A Critical Step for the Collider Blueprint
By demonstrating high-quality positron acceleration in the optimal blowout regime, this work fills a long-standing gap in the field of plasma wakefield acceleration. The underlying principles of nonlinear beam loading and electron filamentation are highly versatile and can be generalized to several advanced scenarios, including high transformer ratio positron acceleration, laser driven positron acceleration and simultaneous acceleration of both electron and positron beams within a single wakefield.

Notably, a seminal 2025 review article published in Nature Physics prominently featured the results of this work when describing positron acceleration solutions for future PWFA-based colliders³. These strategic advances lay a solid foundation for deploying plasma acceleration as a compact, high-energy injector in future high-energy particle physics facilities.

The complete study is accessible via DOI:10.34133/research.0878