Physics:Transmission line measurement

From HandWiki
Short description: Transfer length method (a.k.a. Transmission line measurement)

Transfer Length Measurement or (often named incorrectly) the "Transmission Line Method" is a technique used in semiconductor physics and engineering to determine the contact resistance between a metal and a semiconductor. The technique involves making a series of metal–semiconductor contacts separated by various distances.[1][2] In electronic devices the contacts are make a part of the device, and it is often useful to determine their resistance to get an idea of how it might affect device performance.[lower-alpha 1]

General description

Probes are applied to pairs of contacts, and the resistance between them is measured by applying a voltage across the contacts and measuring the resulting current. The current flows from the first probe, into the metal contact, across the metal–semiconductor junction, through the sheet of semiconductor, across the metal–semiconductor junction again (except this time in the other direction), into the second contact, and from there into the second probe and into the external circuit to be measured by an ammeter. The resistance measured is a linear combination (sum) of the contact resistance of the first contact, the contact resistance of the second contact, and the sheet resistance of the semiconductor in-between the contacts.

When several such measurements are made between pairs of contacts that are separated by different distances, a plot of resistance versus contact separation can be obtained. The contact separation can then be expressed in terms of the ratio L/W – where L and W are the length and width of the area between the contacts – such a plot should be linear, with the slope of the line being the sheet resistance. The intercept of the line with the y-axis, is two times the contact resistance. Thus the sheet resistance as well as the contact resistance can be determined from this technique.

See also

Notes

  1. Especially in radio communication applications.[3](p37)

References

  1. Williams, Ralph (1990). Modern GaAs Processing Methods. Artech House. ISBN 0890063435. 
  2. Schroder, Dieter K. (2006). Semiconductor Material and Device Characterization. John Wiley & Sons. ISBN 0471739065. 
  3. Zennaro, Marco; Fonda, Carlo (2004). Radio Laboratory Handbook (1 ed.). http://wireless.ictp.it/handbook/index.html. 

Further reading