Plasma acceleration

Plasma Wakefield acceleration is a technique for accelerating charged particles, such as electrons, positrons and ions, using an electric field associated with an electron plasma wave. The wave is created either using electron pulses or through the passage of a very brief laser pulses, a technique known as laser plasma acceleration. These techniques appear to offer a way to build high performance particle accelerators of much smaller size than conventional devices at the expense of coherency. Current experimental devices show accelerating gradients several orders of magnitude better than current particle accelerators. For example, an experimental laser plasma accelerator at Lawrence Berkeley National Laboratory accelerates electrons to 1 GeV over about 3.3 cm (5.4x10²⁰ g_n),^[1] whereas the SLAC conventional accelerator requires 64 m to reach the same energy. A recent experiment performed by a team at SLAC achieved an energy gain to 42 GeV over 85 cm using a plasma wakefield accelerator (8.9x10²⁰ g_n).^[2] Once fully developed, the technology could replace many of the traditional RF accelerators currently found in hospitals and research facilities.

1 Basic concept
2 Comparison with RF Acceleration
3 Formula
4 Experimental laboratories
5 See also
6 References
7 External links

Basic concept

A plasma consists of fluid of positive and negative charged particles, generally created by heating or photo-ionizing (direct or tunneling) a dilute gas. Under normal conditions the plasma will be macroscopically neutral (or quasi-neutral), an equal mix of electrons and ions in equilibrium. However, if a strong enough external electric or electromagnetic field is applied, the plasma electrons, which are very light in comparison to the background ions (at least by a factor of 1836), will separate spatially from the massive ions creating a charge imbalance in the perturbed region. A particle injected into such a plasma would be accelerated by the charge separation field, but since the magnitude of this separation is generally similar to that of the external field, apparently nothing is gained in comparison to a conventional system that simply applies the field directly to the particle. But, the plasma medium acts as the most efficient transformer (currently known) of the transverse field of an electromagnetic wave into longitudinal fields of a plasma wave. In existing accelerator technology various appropriately designed materials are used to convert from transverse propagating extremely intense fields in to longitudinal fields that the particles can get a kick from. This process is achieved using two approaches standing-wave structures (such as resonant cavities) or traveling-wave structures} such as disc-loaded waveguides etc. But, the limitation of materials interacting with higher and higher fields is that they eventually get destroyed through ionization and breakdown (which funnily enough forms a plasma). Here the plasma accelerator science originally conceived by late Prof. John M. Dawson of UCLA provides the breakthrough thought on how to generate, sustain and exploit highest fields ever produced by human-science in labs. It should be noted by the readers that most of the non-dark-matter universe is plasma and such plasma-processes are common in astrophysical plasma.

Overview

What makes the system useful is the possibility of introducing waves of very high charge separation that propagate through the plasma similar to the traveling-wave concept in the conventional accelerator. The accelerator thereby phase-locks a particle bunch on a wave and this loaded space-charge wave accelerates them to higher velocities while retaining the bunch properties. Currently, plasma wakes are excited by appropriately shaped laser pulses or electron bunches. Plasma electrons are driven out and away from the center of wake by the ponder-motive force or the electrostatic fields from the exciting fields (electron or laser). Plasma ions are too massive to move significantly and are assumed to be stationary at the time-scales of plasma electron response to the exciting fields. As the exciting fields pass through the plasma, the plasma electrons experience a massive attractive force back to the center of the wake by the positive plasma ions chamber, bubble or column that have remained positioned there, as they were originally in the unexcited plasma. This forms a full wake of an extremely high longitudinal (accelerating) and transverse (focusing) electric field. The positive charge from ions in the charge-separation region then creates a huge gradient between the back of the wake, where there are many electrons, and the middle of the wake, where there are mostly ions. Any electrons in between these two areas will be accelerated (in self-injection mechanism). In the external bunch injection schemes the electrons are strategically injected to arrive at the evacuated region during maximum excursion or expulsion of the plasma electrons.

Exciting the Plasma Wake

A beam-driven wake can be created by sending a relativistic proton or electron bunch into an appropriate plasma or gas. In some cases, the gas can be ionized by the electron bunch, so that the electron bunch both creates the plasma and the wake. This requires an electron bunch with relatively high charge and thus strong fields. The high fields of the electron bunch then push the plasma electrons out from the center, creating the wake.

Similar to a beam-driven wake, a laser pulse can be used to excite the plasma wake. As the pulse travels through the plasma, the electric field of the light separates the electrons and nucleons in the same way that an external field would.

Blowout vs. Linear Regime

If the fields are strong enough, all of the ionized plasma electrons can be removed from the center of the wake: this is known as the "blowout regime". Although the particles are not moving very quickly during this period, macroscopically it appears that a "bubble" of charge is moving through the plasma at close to the speed of light. The bubble is the region cleared of electrons that is thus positively charged, followed by the region where the electrons fall back into the center and is thus negatively charged. This leads to a small area of very strong potential gradient following the laser pulse.

In the linear regime, plasma electrons aren't completely removed from the center of the wake. In this case, the linear plasma wave equation can be applied. However, the wake appears very similar to the blowout regime, and the physics of acceleration is the same.

Acceleration

It is this "wakefield" that is used for particle acceleration. A particle injected into the plasma near the high-density area will experience an acceleration toward (or away) from it, an acceleration that continues as the wakefield travels through the column, until the particle eventually reaches the speed of the wakefield. Even higher energies can be reached by injecting the particle to travel across the face of the wakefield, much like a surfer can travel at speeds much higher than the wave they surf on by traveling across it. Accelerators designed to take advantage of this technique have been referred to colloquially as "surfatron"s.

Comparison with RF Acceleration

The advantage of plasma acceleration is that its acceleration field can be much stronger than that of conventional radio-frequency (RF) accelerators. In RF accelerators, the field has an upper limit determined by the threshold for dielectric breakdown of the acceleration tube. This limits the amount of acceleration over any given area, requiring very long accelerators to reach high energies. In contrast, the maximum field in a plasma is defined by mechanical qualities and turbulence, but is generally several orders of magnitude stronger than with RF accelerators. It is hoped that a compact particle accelerator can be created based on plasma acceleration techniques or accelerators for much higher energy can be built, if long accelerators are realizable with an accelerating field of 10 GV/m.

Plasma acceleration is categorized into several types according to how the electron plasma wave is formed:

plasma wakefield acceleration (PWFA): The electron plasma wave is formed by an electron bunch
laser wakefield acceleration (LWFA): A laser pulse is introduced to form an electron plasma wave.
laser beat-wave acceleration (LBWA): The electron plasma wave arises based on different frequency generation of two laser pulses.
self-modulated laser wakefield acceleration (SMLWFA): The formation of an electron plasma wave is achieved by a laser pulse modulated by stimulated Raman forward scattering instability.

The concept of plasma acceleration was first proposed by Toshiki Tajima and John Dawson in a theoretical article published in 1979.^[3] The first experimental demonstration of wakefield acceleration, which was performed with PWFA, was reported by a research group at Argonne National Laboratory in 1988.^[4]

Formula

The acceleration gradient for a linear plasma wave is:^[5]

$E = c \cdot \sqrt{\frac{m_e \cdot \rho}{\epsilon_0}}.$

In this equation, $E$ is the electric field, $c$ is the speed of light in vacuum, $m_e$ is the mass of the electron, $\rho$ is the plasma density (in particles per cube metre), and $\epsilon_0$ is the permittivity of free space.

Experimental laboratories

Surfatron is the colloquial name for experimental particle accelerators using plasma acceleration. Currently such devices are in the proof of concept phase at the following institutions:

References

^ Leemans et al. 2006. GeV electron beams from a centimetre-scale accelerator. Nature Physics 418: 696-699. doi:10.1038/nphys418
^ Blumenfeld et al. 2007. Energy doubling of 42 GeV electrons in a metre-scale plasma wakefield accelerator. Nature 445: 741-744 doi:10.1038/nature05538
^ T. Tajima and J. M. Dawson. 1979. Laser Electron Accelerator. Phys. Rev. Lett. 43: 267–270 doi:10.1103/PhysRevLett.43.267
^ Rosenzweig et al. 1988. Experimental Observation of Plasma Wake-Field Acceleration. Phys. Rev. Lett. 61: 98–101 doi:10.1103/PhysRevLett.61.98
^ http://icfa-usa.jlab.org/archive/newsletter/icfa_bd_nl_12/node26.html

C. Joshi, "Plasma Accelerators," Scientific American (February 2006), 294, 40-47
Thomas Katsouleas, "Accelerator physics: Electrons hang ten on laser wake" Nature (September 2004), 431, 515-516, doi:10.1038/431515a
Joshi, C. & Katsouleas, T., "Plasma accelerators at the energy frontier and on tabletops", Physics Today 56, No. 6, 47−51 (2003), doi:10.1063/1.1595054.
D. Carrigan, Advanced Accelerators (2005)
UCLA Particle Beam Physics Laboratory, Plasma Acceleration at PBPL (2003)
A. Ogata, "Status and Problems of Plasma Accelerators", ICFA Beam Dynamics Newsletter, No. 11, August 1996.
Chan Joshi and Victor Malka "Focus on Laser- and Beam-Driven Plasma Accelerators". New Journal of Physics. 2010. http://iopscience.iop.org/1367-2630/12/4/045003.

External links

Riding the Plasma Wave of the Future