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This summary is machine-generated.

We achieved significant transverse compression of muon beams using a helium gas target and electric/magnetic fields. This method drastically reduced beam size, enhancing muon beam applications.

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Area of Science:

  • Particle Physics
  • Beam Physics
  • Atomic and Molecular Physics

Background:

  • Muon beams are crucial for fundamental physics research and applications.
  • Efficiently controlling muon beam properties, such as phase space density, is essential for advanced experiments.
  • Previous methods for muon beam manipulation have limitations in compression efficiency and phase space density enhancement.

Purpose of the Study:

  • To demonstrate efficient transverse compression of a muon beam.
  • To investigate the use of a helium gas target with specific field configurations for beam compression.
  • To assess the combined effect of transverse and longitudinal compression on muon beam phase space density.

Main Methods:

  • Utilizing a helium gas target with a vertical density gradient.
  • Applying crossed electric and magnetic fields to the muon beam.
  • Simulating low-energy muon-helium elastic and charge exchange collisions.

Main Results:

  • Achieved transverse compression of a 12.5 MeV/c muon beam.
  • Reduced vertical muon stop distribution from 14 mm to 0.25 mm (rms) in 3.5 μs.
  • Simulation accurately described experimental measurements, validating the collision models used.

Conclusions:

  • The demonstrated transverse compression is highly efficient.
  • Combining transverse and longitudinal compression stages can enhance muon beam phase space density by a factor of 10^10.
  • This technique offers a promising pathway for improving muon beam quality for future research.