Fabrication and characterization of modulation doped field effect transistors for quantum waveguide structures

Yindeepol, Wipawan, 1960-

12 July 1990

Split and normal gate A1GaAs /GaAs MODFETs were fabricated along with the ohmic test structures and the Hall bar geometries. The DC characteristics of normal gate transistors were evaluated at room temperature and at 77K and the threshold voltages were extracted from the measurements and compared to the theoretical results. The performance of normal gate transistors was reasonable. The sheet carrier density and the mobility extracted from Hall measurements using the Hall bar geometry showed increase of carrier density with increasing gate voltage and an increase of mobility with increasing carrier density. The contact resistance obtained from the ohmic test structure was high and not uniform within the sample. / Graduation date: 1991

Submicron and nanoscale organic field-effect transistors and circuits

Jung, Tae Ho

28 August 2008

Not available / text

Field-effect transistors

Organic semiconductors

Effects of illumination on the properties of organic field-effect transistors

Wasapinyokul, Kamol

January 2011

No description available.

620

Organic field-effect transistors

The replacement of diffused resistors in integrated digital circuits by field effect current limiters

Whalen, James W.

January 1966

No description available.

Field-effect transistors.

Electric resistors.

Development of chemically sensitive field-effect transistor arrays and selective materials

Polk, Brian Joseph

08 1900

No description available.

Field-effect transistors

Chemical detectors

Field effect transistors in differential amplifiers

Gray, James Stephen

08 1900

No description available.

Amplifiers (Electronics)

Field-effect transistors

A theory for optically-gated gallium-arsenide MESFETS

Darling, Robert Bruce

05 1900

No description available.

Field-effect transistors

Microwave devices

Charge transport in polymer semiconductors

Basu, Debarshi,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.

Studies on field effect transistors with conjugated polymer and high permittivity gate dielectrics using pulsed plasma polymerization

Xu, Yifan.

January 2005

Thesis (Ph. D.)--Ohio State University, 2005. / Title from first page of PDF file. Document formatted into pages; contains xx, 187 p.; also includes graphics (some col.). Includes bibliographical references (p. 174-187). Available online via OhioLINK's ETD Center

Silicon implant profile control by co-implantation

Gwilliam, Russell

January 1991

This thesis reports the development of two rapid thermal annealing systems, one based on resistive heating of graphite strips, the second on heating from incoherent lamp radiation. Electrical activation studies of silicon implanted gallium arsenide has been used to compare the systems with those available commercially. It has been shown that commercial systems can yield temperature measurement errors in excess of 50° C. Furthermore, the systems have been used to investigate the electrical activation of silicon implants co-implanted with other ions into gallium arsenide, with a view to either, improving the activation of the silicon for high doses, or modifying the carrier profile shape for low doses. A factor of two improvement in the electrical activation of high dose silicon implants has been achieved by the co-implantation of phosphorus, with a reduction in the annealing temperature required to achieve a given activity also being observed. An alternative processing methodology is also proposed for through- nitride implantation. Phosphorus implants have also been used to "pre-amorphise" substrates to prevent ion channelling. Providing the damage is maintained below a certain level, improvements in profile shape can be obtained. Other compensation techniques using boron and carbon implants have also been investigated. Boron has been demonstrated to provide improved carrier activation for low implant doses, with thermally stable profile modification capability as the dose is increased. The electrical activation of single carbon implants (40% maximum) is below the level of compensation of silicon implants (approximately 90%) co-implanted with carbon. This in turn means carbon is excellent for profile modification as no p-type layer is created beyond the donor implant.

530.41

Semiconductors. Field effect transistors