Frequency Conversion in Punch-Through Semiconductor Devices.

Abstract

The objectives of this investigation are to study the frequency conversion properties of punch-through semiconductor devices and to establish the frequency regions of their potential application as efficient detectors and mixers of information-bearing signals. The physics of two punch-through devices are studied in detail: the three-terminal punch-through transistor and the two-terminal BARITT (barrier injection transit-time) diode. The particle current injection process for both devices is examined and identified as simple diffusion over a potential barrier (exponential injection with respect to the barrier height). Dc and small-signal ac models for both punch-through structure are derived from standard bipolar junction transistor theory by applying a current-dependent, rather than the standard voltage-dependent, boundary condition for the minority carrier concentration at the collector edge of the low-field base region. The small-signal models include carrier transit-time effects in the diffusion-drift, reverse-biased regions of the devices by means of a transit-time factor similar to the factor used in the standard frequency domain analysis of pure saturated drift transit-time diodes. The small-signal noise properties of the BARITT diode are developed employing the same techniques used in the formulation of the BARITT diode circuit model. Both, small-signal impedances predicted by the circuit model and small-signal noise measures predicted by the noise analysis, compare very well with experimentally measured values of typical BARITT structures.

Document Details

Document Type

Technical Report

Publication Date

Aug 01, 1978

Accession Number

ADA063558

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