Dielectric wall accelerator
A Dielectric Wall Accelerator (DWA) is a compact linear particle accelerator concept designed and patented[1] in the late 1990s, that works by inducing a travelling electromagnetic wave in a tube which is constructed mostly from dielectric material. The main conceptual difference to a conventional disk-loaded linac system is given by the additional dielectric wall and the coupler construction.
Possible uses of this concept include its application in external beam radiotherapy (EBRT) using protons or ions.
Operation
An external alternating-current power supply provides an electromagnetic wave that is transmitted to the accelerator tube using a waveguide. The power supply is switched on only a very short time (pulsed operation).[2]
Electromagnetic induction creates a traveling electric field, which accelerates charged particles. The traveling wave overlaps with the position of the charged particles, leading to their acceleration inside as they pass through the tube's vacuum channel.[2] The field inside the tube is negative just ahead of the proton and positive just behind the proton. Because protons are positively charged, they accelerate toward the negative and away from the positive. The power supply switches the polarity of the sections, so they stay synchronized with the passing proton.
Construction
The accelerator tube is made from sheets of fused silica, only 250 µm thick. After polishing, the sheets are coated with 0.5 µm of chromium and 2.5 µm of gold. About 80 layers of the sheets are stacked together, and then heated in a brazing furnace, where they fuse together. The stacked assembly is then machined into a hollow cylinder. Fused silica is pure transparent quartz glass, a dielectric, which is why the machine is called a "dielectric wall accelerator."
A sketch of one of the assembled modules of the accelerator is shown in the patent sketch. The module is about 3 cm long, and the beam travels upward. The dielectric wall is seen as item number 81. It is surrounded by a pulse forming device called a Blumlein. In figure 8A, the power supply charges the Blumlein. In figure 8B, silicon carbide switches surrounding the Blumlein close, shorting out the edge of the Blumlein. The energy stored in the Blumlein rushes toward the dielectric wall as a high voltage pulse.
Usage in Proton Therapy
Particle beams such as protons and heavier ions offer improved dose distributions compared with the system known as intensity-modulated radiation therapy (IMRT).[3] IMRT uses an indirect ionization of water in the cell to produce free radicals. These react chemically with the cell destroying single strands of the dual strand DNA.
Protons are many times heavier than electrons, which makes them easier to control and allows them to more precisely target a tumor. Protons are charged particles and are accelerated to a predetermined energy level which, using the bragg peak delivers the energy directly within 1–2 mm inside the tumor and stops. IMRT photons primarily indirectly ionizes the single strand DNA nuecleotide using the free radical method to disrupt cell life. Tumors are notorious for having a poor blood supply called cell (hypoxia). This requires the use of drugs to oxygenate the tumor. Since the tumor is fast growing it has a poor blood supply meaning any drugs directed at them will have difficulty getting to them.
Advantages and Limitations
The DWA addresses the main issues with the current proton therapy systems—cost and size Video. Depending on the desired final beam energy, the conventional medical accelerator solutions (cyclotrons and small synchrotrons) can have large cost factors and space requirements, which could be circumvented by DWAs. The cost estimate for a DWA is about 20 million US dollars.
DWAs are expected to reach acceleration gradients around 100 MV/m.[2]
The system is a spinoff of a DOE device to inspect nuclear weapons. This system requires several new advances because of the high energies, like e.g. high gradient insulators.[4] A wide band-gap photoconductive switch, about 4,000 are needed. A Symmetric Blumlein, typical width 1mm.
References
- ↑ US patent 5811944, Sampayan, S.E.; Caporaso, G.J.; Kirbie, H.C, "Enhanced Diaelectric-Wall Linear Accelerator", issued 1998-09-22
- 1 2 3 Jermey N. A. Matthews (Mar 2009). "Accelerators shrink to meet growing demand for proton therapy". Physics Today 62: 22–24. Bibcode:2009PhT....62c..22M. doi:10.1063/1.3099570.
- ↑ Daniela Schulz-Ertner and Hirohiko Tsujii (March 10, 2007). "Particle Radiation Therapy Using Proton and Heavier Ion Beams". Journal of Clinical Oncology 25: 953–64. doi:10.1200/jco.2006.09.7816. PMID 17350944.
- ↑ US patent 6331194, Sampayan, Stephen, "Process for manufacturing hollow fused-silica insulator cylinder", issued 2001-12-18
External links
- Dielectric Wall Accelerator G. J. Caporaso, Y.-J. Chen, S. E. Sampayan September 3, 2009, Reviews of Accelerator Science and Technology
- High Gradient Dielectric Wall Accelerators Muon Collider Design Workshop, December 8–12, 2008, Thomas Jefferson National Laboratory
- Ultra‐High‐Current Electron Induction Accelerators Physics today [0031-9228] Kapetanakos, C yr:1985 vol:38 iss:2 pg:58
- US Patent 7924121 Dispersion-Free Radial Transmission Lines, April 12, 2011