Particle accelerators centimeters long will drastically reduce size and cost of working with antimatter

Physical Review Accelerators and Beams – Quasimonoenergetic laser plasma positron accelerator using particle-shower plasma-wave interactions

An all-optical centimeter-scale laser-plasma positron accelerator is modeled to produce quasimonoenergetic beams with tunable ultrarelativistic energies. A new principle elucidated here describes the trapping of divergent positrons that are part of a laser-driven electromagnetic particle-shower with a large energy spread and their acceleration into a quasimonoenergetic positron beam in a laser-driven plasma wave. Proof of this principle using analysis and particle-in-cell simulations demonstrates that, under limits defined here, existing lasers can accelerate hundreds of MeV pC quasi-monoenergetic positron bunches. By providing an affordable alternative to kilometer-scale radio-frequency accelerators, this compact positron accelerator opens up new avenues of research.

12 thoughts on “Particle accelerators centimeters long will drastically reduce size and cost of working with antimatter”

  1. There was no information on the efficiency of the system. How many joules of input power result in a joule’s worth of kinetic energy in the beam. Now for many to most application this is unimportant. If you want a particle beam for research, then whether your desktop system is 1% efficient or 0.01% efficient matters far less than the fact you didn’t need to spend a billion dollars in building it in the first place. But for interstellar propulsion or fusion power, the energy in to energy out equation becomes critical.

  2. There was no information on the efficiency of the system. How many joules of input power result in a joule’s worth of kinetic energy in the beam.Now for many to most application this is unimportant. If you want a particle beam for research then whether your desktop system is 1{22800fc54956079738b58e74e4dcd846757aa319aad70fcf90c97a58f3119a12} efficient or 0.01{22800fc54956079738b58e74e4dcd846757aa319aad70fcf90c97a58f3119a12} efficient matters far less than the fact you didn’t need to spend a billion dollars in building it in the first place.But for interstellar propulsion or fusion power the energy in to energy out equation becomes critical.

  3. There was no information on the efficiency of the system. How many joules of input power result in a joule’s worth of kinetic energy in the beam.
    Now for many to most application this is unimportant. If you want a particle beam for research, then whether your desktop system is 1% efficient or 0.01% efficient matters far less than the fact you didn’t need to spend a billion dollars in building it in the first place.

    But for interstellar propulsion or fusion power, the energy in to energy out equation becomes critical.

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