Input I-V and sampling time characteristics of the ACT device
Abstract
The input I-V and sampling-time characteristics of the acoustic charge transport (ACT) device are presented for ohmic-contact charge injection and Schottky-gate-modulated charge injection. A computationally efficient analysis technique is developed to calculate the I-V and sampling-time data from two-dimensional potential and carrier-density distributions. Device physics and architecture are incorporated into the analysis through a numerical charge-injection model which is used to compute the potential and carrier-density distributions. Theoretical results are presented to demonstrate the charge injection characteristics of some typical device structures. The effects that the injection method, the epitaxial layer structure, and the acoustic wave amplitude have on device performances are discussed. The physical basis of the analysis enables it to be used to study several other design parameters. Experimental measurements of a device I-V and input transconductance show good agreement with calculated data. This analysis technique provides a means of assessing the performance potential of new device designs.
- Publication:
-
IEEE Transactions on Electron Devices
- Pub Date:
- April 1991
- DOI:
- Bibcode:
- 1991ITED...38..831B
- Keywords:
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- Carrier Density (Solid State);
- Charge Coupled Devices;
- Charge Transfer Devices;
- Gallium Arsenides;
- Schottky Diodes;
- Volt-Ampere Characteristics;
- Electric Contacts;
- P-N Junctions;
- Piezoelectricity;
- Sampling;
- Surface Acoustic Wave Devices;
- Electronics and Electrical Engineering