A low-voltage high-speed electronic switch based on piezoelectric transduction

Abstract: We propose a novel digital switch, the piezoelectronic transistor or PET. Based on properties of known materials, we predict that a nanometer-scale PET can operate at low voltages and relatively high speeds, exceeding the capabilities of any conventional field effect transistor (FET). Depending on the degree to which these attributes can be simultaneously achieved, the device has a broad array of potential applications in digital logic. The PET is a 3-terminal switch in which a gate voltage is applied to a pie… Show more

“…9), which links together strain at several lengths scales from nm (interferometry) to fm (diffraction) as well as time scales from 0.01 Hz to presently 55 Hz, allows new insights to be gleaned on the correlation between induced strain and material properties-information of crucial importance for the development of novel devices such as IBM's patented piezoelectric effect transistor. 17,30 Since the origin of the extraordinarily large electromechanical coupling and piezoelectric coefficients within 0.68PMN-0.32PT at the morphotropic phase boundary is not yet adequately explained in the literature, the ability to tune the piezoelectric response through domain engineering (with different orientations of crystal cuts, poling and/or direction of working electrodes) offers a variety of geometries that may be investigated within the novel experimental development on the XMaS beamline. The incident angle and the energy tunability that a synchrotron beamline offers allow the investigation of samples as function of x-ray penetration depth together with elemental sensitivity/selectivity.…”

Simultaneous dynamic electrical and structural measurements of functional materials

“…9), which links together strain at several lengths scales from nm (interferometry) to fm (diffraction) as well as time scales from 0.01 Hz to presently 55 Hz, allows new insights to be gleaned on the correlation between induced strain and material properties-information of crucial importance for the development of novel devices such as IBM's patented piezoelectric effect transistor. 17,30 Since the origin of the extraordinarily large electromechanical coupling and piezoelectric coefficients within 0.68PMN-0.32PT at the morphotropic phase boundary is not yet adequately explained in the literature, the ability to tune the piezoelectric response through domain engineering (with different orientations of crystal cuts, poling and/or direction of working electrodes) offers a variety of geometries that may be investigated within the novel experimental development on the XMaS beamline. The incident angle and the energy tunability that a synchrotron beamline offers allow the investigation of samples as function of x-ray penetration depth together with elemental sensitivity/selectivity.…”

Simultaneous dynamic electrical and structural measurements of functional materials

“…A similar concept is the piezoelectronic transistor [16]. This device combines a piezoelectric layer and a piezoresistive material to obtain a transistor.…”

“…Recently the piezoelectronic transistor has been proposed [16]. In this device a piezoelectric layer compresses a strongly piezoresistive resistor and thus modulates the resistance.…”

“…Simulations [16] showed the possibility of increasing the applied stress by increasing the relative volume of the piezoelectric compared to the semiconductor. This solution comes at a significant price.…”

“…To obtain a larger amount of strain in the semiconductor a piezoelectric layer with a larger surface area [16] than the fin may be used. In our design this corresponds to a piezoelectric layer that is higher and longer than the FinFET itself.…”

Tailoring strain in microelectronic devices

NEMS Switch Technology