Wire chamber

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"Multiwire" redirects here. For the electrical connection technique, see printed circuit board § Multiwire boards.

A multi-wire proportional chamber is a type of proportional counter that detects charged particles and photons and can give positional information on their trajectory,[1] by tracking the trails of gaseous ionization.[2]

Description

File:Wire chamber schematic.svg
Wire chamber with wires (W) and cathode (-) plates (P). The particles flying through T will ionize and set free a charge that an amplifier A collects (impulse at the output)

The multi-wire chamber uses an array of wires at high voltage (anode), which run through a chamber with conductive walls held at ground potential (cathode). The chamber is filled with carefully chosen gas, such as an argon/methane mix, such that any ionizing particle that passes through the tube will ionize surrounding gaseous atoms. The resulting ions and electrons are accelerated by the electric field around the wire, causing a localised cascade of ionization known as a Townsend avalanche. This collects on the nearest wire and results in a charge proportional to the ionisation effect of the detected particle. By computing pulses from all the wires, the particle trajectory can be found.

Adaptions of this basic design are the thin gap, resistive plate and drift chambers. The drift chamber is also sub-divided into ranges of specific use in the chamber designs known as time projection, microstrip gas, and those types of detectors that use silicon.[3][4]

Development

In 1968, Georges Charpak, while at the European Organization for Nuclear Research in CERN, invented and developed the multi-wire proportional chamber (MWPC). The chamber was an advancement of the earlier bubble chamber rate of detection of only one or two particles every second to 1000 particle detections every second. The MWPC produced electronic signals from particle detection allowing scientists to examine data via computers.[5][6][7] The multi-wire chamber is a development of the spark chamber.[8]

Fill gases

In a typical experiment, the chamber contains a mixture of these gases:[2]

The chamber could also be filled with:

File:MWPC electric field.svg
Equipotential line and field line in a MWPC

Use

For high energy physics experiments, it is used to observe a particle's path. For a long time, bubble chambers were used for this purpose, but with the improvement of electronics, it became desirable to have a detector with fast electronic read-out. (In bubble chambers, photographs were made, printed and then looked through.) A wire chamber is a chamber with many parallel wires, arranged as a grid and put on high voltage, with the metal casing being on ground potential. As in the Geiger counter, a particle leaves a trace of ions and electrons, which drift toward the case or the nearest wire, respectively. By marking off the wires which had a pulse of current, one can see the particle's path.

The chamber has a very good relative time resolution, good positional accuracy, and a self-triggered operation (Ferbel 1977).[12]

The development of the chamber enabled scientists to study the trajectories of particles with much improved precision, and also for the first time observe and study the rarer interactions that occur through particle interaction.

Drift chambers

File:Chambre-a-derive-IMG 0524.jpg
Cut-away showing interior of a drift chamber
File:Chambre-a-derive-IMG 0523.jpg
Drift chamber at the Musée des Arts et Métiers in Paris

If one also precisely measures the timing of the current pulses of the wires and takes into account that the ions need some time to drift to the nearest wire, one can infer the distance at which the particle passed the wire. This greatly increases the accuracy of the path reconstruction and is known as a drift chamber.

The drift chamber functions by balancing the loss of energy from particles caused by impacts with particles of gas, with the accretion of energy created with high-energy electrical fields in use to cause the particle acceleration.[13] Design is similar to the Mw chamber but instead with central layer wires at a greater distance apart.[8] The detection of charged particles within the chamber is possible by the ionizing of particles of gas due to the motion of the charged particle.[14]

The Fermilab detector CDF II contains a drift chamber called the Central Outer Tracker.[15] The chamber contains argon and ethane gas, and wires separated by 3.56 millimetres gaps.[16]

If two drift chambers are used with the wires of one orthogonal to the wires of the other, both orthogonal to the beam direction, a more precise detection of the position is obtained. If an additional simple detector (like the one used in a veto counter) is used to detect, with poor or null positional resolution, the particle at a fixed distance before or after the wires, a tri-dimensional reconstruction can be made and the speed of the particle deducted from the difference in time of the passage of the particle in the different part of the detector. This setup gives up the detector called Time Projection Chamber (often written just TPC)

For measuring the velocity of the electrons in a gas (drift velocity) there are special drift chambers, Velocity Drift Chambers which measure the drift time for known location of ionisation.

See also

References

  1. F. Sauli (1977), - Principles of operation of multiwire proportional and drift chambers Retrieved 2012-02-25
  2. 2.0 2.1 Lua error in package.lua at line 80: module 'strict' not found. was located via Dr. C.N. Booth PHY304 Particle Physics Sheffield University
  3. I. Kisel - [1] Retrieved 2012-02-28
  4. University of Manchester - HEP - 101 Retrieved 2012-02-28
  5. Computers in Physics, Sep/Oct 1992 - The Polish Language School for Foreign Students - Adam Mickiewicz University in Poznań - European Organization for Nuclear Research Retrieved 2012-02-25
  6. H. Johnston - Physics world Retrieved 2012-02-25
  7. Lua error in package.lua at line 80: module 'strict' not found. - U.S. Department of Energy Research and Development Accomplishments Retrieved 2012-02-23
  8. 8.0 8.1 Lua error in package.lua at line 80: module 'strict' not found.
  9. S.E.Derenzo - SLAC National Accelerator Laboratory, Stanford University ( U.S. Department of Energy Office of Science ); Lua error in package.lua at line 80: module 'strict' not found.
  10. Lua error in package.lua at line 80: module 'strict' not found.
  11. Lua error in package.lua at line 80: module 'strict' not found. ; > G. Charpak Research on particle imaging detectors p.537 World Scientific, 1995 Retrieved 2012-02-28
  12. T. Ferbel - (CERN report 1977)>
  13. Lua error in package.lua at line 80: module 'strict' not found.
  14. Lua error in package.lua at line 80: module 'strict' not found.
  15. Lua error in package.lua at line 80: module 'strict' not found.
  16. Fermilab - glossary-photo- J. L. Lee Retrieved 2012-02-12

External links

  • hypermail_ archive of links to CLAS drift chambers
  • [2] Heidelberg lecture on research ionisation chambers.
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