Electrostatic particle accelerator: Difference between revisions

An '''electrostatic particle accelerator''' is one of the two main types ofa [[particle accelerator]]s, in which [[charged particle]]s are accelerated to a high energy by passing through a static [[high voltage|high-voltage]] potential. The Thisreason contraststhat withonly thecharged otherparticles categorycan ofbe particleaccelerated accelerator,is [[Particlethat accelerator#Oscillatingonly field particle accelerators|oscillating field particle accelerators]], in which thecharged particles are acceleratedinfluenced by passingan electric successivelyfield, through multiple voltage drops created by oscillating voltages on electrodes. Owingaccording to theirthe simplerformula designF=qE, historicallywhich electrostaticcauses typesthem wereto the first particle acceleratorsmove. This Thecontrasts two main types arewith the [[Vanother demajor Graafcategory generator]]of inventedparticle by [[Robert Van de Graaff]] in 1929accelerator, and the [[Cockcroft-WaltonParticle accelerator]]#Electrodynamic invented(electromagnetic) byparticle [[Johnaccelerators|oscillating Cockcroft]]field andparticle [[Ernest Waltonaccelerators]], in 1932. The maximum particle energy produced by electrostatic accelerators is limited bywhich the acceleratingparticles voltageare on the machine, which is limitedaccelerated by [[electricaloscillating breakdown|insulationelectric breakdown]]fields. Oscillating accelerators do not have this limitation, so they can achieve higher particle energies than electrostatic machines.

Using a [[high voltage|high-voltage]] terminal kept at a static potential on the order of millions of volts, [[charged particle]]s can be accelerated. In simple language, an [[electrostatic generator]] is basically a giant [[capacitor]] (although lacking plates). The high voltage is achieved either using the methods of [[Cockcroft-WaltonCockcroft–Walton generator|Cockcroft & Walton]] or [[Van de Graaff generator|Van de Graaff]], with the accelerators often being named after these inventors. Van de Graaff's [[Van de Graaff generator|original design]] places electrons on an insulating sheet, or belt, with a metal comb, and then the sheet physically transports the immobilized electrons to the terminal. Although at high voltage, the terminal is a conductor, and there is a corresponding comb inside the conductor which can pick up the electrons off the sheet; owing to [[Gauss's law]], there is no electric field inside a conductor, so the electrons are not repulsed by the platform once they are inside. The belt is similar in style to a [[Conveyor belt|conventional conveyor belt]], with one major exception: it is seamless. Thus, if the belt is broken, the accelerator must be disassembled to some degree in order to replace the belt, which, owing to its constant rotation and being made typically of a [[rubber]], is not a particularly uncommon occurrence. The practical difficulty with belts led to a different medium for physically transporting the charges: a chain of pellets. Unlike a normal chain, this one is non-conducting from one end to the other, as both insulators and conductors are used in its construction. These typetypes of accelerators are usually called [[Pelletron]]s.

Once the platform can be electrically charged by one of the above means, some [[Ionion source|source of positive ions]] is placed on the platform at the end of the beam line, which is why it's called the terminal. However, as the ion source is kept at a high potential, one cannot access the ion source for control or maintenance directly. Thus, methods such as plastic rods connected to various levers inside the terminal can branch out and be toggled remotely. Omitting practical problems, if the platform is positively charged, it will repel the ions of the same electric polarity, accelerating them. As E=qV, where E is the emerging energy, q is the ionic charge, and V is the terminal voltage, the maximum energy of particles accelerated in this manner is practically limited by the discharge limit of the high -voltage platform, about 12  MV under ambient atmospheric conditions. This limit can be increased, for example, by keeping the HV platform in a tank of an [[insulating gas]] with a higher [[dielectric constant]] than air, such as [[Sulfur hexafluoride|SF₆]] which has dielectric constant roughly 2.5 times that of air. However, even in a tank of SF₆ the maximum attainable voltage is around 30  MV. There could be other gases with even better insulating powers, but SF₆ is also chemically [[Chemically inert|inert]] and non-[[Toxicity|toxic]]. To increase the maximum acceleration energy further, the [[tandem]] concept was invented to use the same high voltage twice.

Conventionally, positively charged ions are accelerated because this is the polarity of the atomic nucleus. However, if one wants to use the same [[Static electricity|static electric]] potential twice to accelerate ions[[ion]]s, then the polarity of the ions' charge must change from anions to cations or vice versa while they are inside the conductor where they will feel no electric force. It turns out to be simple to remove, or strip, electrons from an energetic ion. One of the properties of ion interaction with matter is the exchange of electrons, which is a way the ion can lose energy by depositing it within the matter, something we should intuitively expect of a projectile shot at a solid. However, as the target becomes thinner or the projectile becomes more energetic, the amount of energy deposited in the foil becomes less and less.

Tandems locate the ion source outside the terminal, which means that accessing the ion source while the terminal is at high voltage is significantly less difficult, especially if the terminal is inside a gas tank. So then an anion beam from a [[sputter]]ing ion source is injected from a relatively lower voltage platform towards the high -voltage terminal. Inside the terminal, the beam impinges on a thin foil (on the order of micrograms per square centimeter), often [[carbon]] or [[beryllium]], stripping electrons from the ion beam so that they become cations. As it is difficult to make anions of more than -1 charge state, then the energy of particles emerging from a tandem is E=(q+1)V, where we have added the second acceleration potential from that anion to the positive charge state q emerging from the stripper foil; we are adding these different charge signs together because we are increasing the energy of the nucleus in each phase. In this sense, we can see clearly that a tandem can double the maximum energy of a proton beam, whose maximum charge state is merely +1, but the advantage gained by a tandem has diminishing returns as we go to higher mass, as, for example, one might easily get a 6+ charge state of a [[silicon]] beam.

The name 'tandem' originates from this dual-use of the same high voltage, although tandems may also be named in the same style of conventional electrostatic accelerators based on the method of charging the terminal.

One trick which has to be considered with electrostatic accelerators is that usually vacuum beam lines are made of steel. However, one cannot very well connect a conducting pipe of steel from the high -voltage terminal to the ground. Thus, many rings of a strong glass, like [[Pyrex]], are assembled together in such a manner that their interface is a vacuum seal, like a copper [[gasket]]; a single long glass tube could implode under vacuum or fracture supporting its own weight. Importantly for the physics, these inter-spaced conducting rings help to make a more uniform electric field along the accelerating column. This beam line of glass rings is simply supported by compression at either end of the terminal. As the glass is non-conducting, it could be supported from the ground, but such supports near the terminal could induce a discharge of the terminal, depending on the design. Sometimes the compression is not sufficient, and the entire beam line may collapse and shatter. This idea is especially important to the design of tandems, because they naturally have longer beam lines, and the beam line must run through the terminal.

In a single-ended electrostatic accelerator the charged particle is accelerated through a single potential difference between two electrodes, so the output particle energy <math>E</math> is equal to the charge on the particle <math>q</math> multiplied by the accelerating voltage <math>V</math>

In a tandem accelerator the particle is accelerated twice by the same voltage, so the output energy is <math>2qV(1+q)V</math>, as the anion form is singly charged. If the charge <math>q</math> is in conventional units of [[coulomb]]s and the potential <math>V</math> is in [[volt]]s the particle energy will be given in [[joule]]s. However, because the charge on elementary particles is so small (the charge on the electron is 1.6x10⁻¹⁹ coulombs), the energy in joules is a very small number.

Since all elementary particles have charges which are multiples of the [[elementary charge]] on the electron, <math>e = 1.6(10^{-19})</math> coulombs, particle physicists use a different unit to express particle energies, the ''[[electronvolt|electron volt]]'' (eV) which makes it easier to calculate. The electronvolt is equal to the energy a particle with a charge of 1''e'' gains passing through a potential difference of one volt. In the above equation, if <math>q</math> is measured in elementary charges ''e'' and <math>V</math> is in volts, the particle energy <math>E</math> is given in eV. For example, if an an [[alpha particle]] which has a charge of 2''e'' is accelerated through a voltage difference of one million volts (1&nbsp;MV), it will have an energy of two million electron volts, abbreviated 2&nbsp;MeV. The accelerating voltage on electrostatic machines is in the range 0.1 to 25&nbsp;MV and the charge on particles is a few elementary charges, so the particle energy is in the low MeV range. More powerful accelerators can produce energies in the giga electron volt (GeV) range.