Abstract
For some years now, the ever continuing dimensional scaling has no longer been considered to be sufficient for the realization of advanced CMOS devices. Alternative approaches, such as employing new materials and introducing new device architectures, appear to be the way to go forward. A currently hot approach is to employ ferroelectric materials for obtaining a positive feedback in the gate control of a switch. This work elaborates on two device architectures based on this approach: the negative-capacitance and the piezoelectric field-effect transistor, i.e., the NC-FET (negative-capacitance field-effect transistor), respectively -FET. It briefly describes their operation principle and compares those based on earlier reports. For optimal performance, the adopted ferroelectric material in the NC-FET should have a relatively wide polarization-field loop (i.e., “hard” ferroelectric material). Its optimal remnant polarization depends on the NC-FET architecture, although there is some consensus in having a low value for that (e.g., HZO (Hafnium-Zirconate)). -FET is the piezoelectric coefficient, hence its polarization-field loop should be as high as possible (e.g., PZT (lead-zirconate-titanate)). In summary, literature reports indicate that the NC-FET shows better performance in terms of subthreshold swing and on-current. However, since its operation principle is based on a relatively large change in polarization the maximum speed, unlike in a -FET, forms a big issue. Therefore, for future low-power CMOS, a hybrid solution is proposed comprising both device architectures on a chip where hard ferroelectric materials with a high piezocoefficient are used.
Highlights
As is commonly known, the key component of the microprocessor, the conventional metal-oxide-semiconductor field-effect transistor (MOSFET), needs some refurbishment
We observed that the converse π-effect reduced the subthreshold swing (SS) by ∼5 mV/dec which can be attributed to the strain-induced reduction of the trap density at the Si/SiO2 interface, as confirmed in the higher electron mobility values obtained in these structures at low vertical electric fields
The so-called Curie temperature TC, which is the minimum temperature at which a ferroelectric material becomes paraelectric, should be above the desired operating temperature range; otherwise, in principle, the devices won’t function properly
Summary
The key component of the microprocessor, the conventional metal-oxide-semiconductor field-effect transistor (MOSFET), needs some refurbishment. Its slope against the gate-source voltage (VGS) has a maximum value dictated by Boltzmann’s tyranny being ∼60 mV/dec at room temperature, or, equivalently, a minimum ideality factor m equal to unity To break this tyranny, alternative device architectures have been proposed based on other physical principles, such as tunnel FETs [8,9,10,11] and impact-ionization MOSFETs [12]. Depending on the asymmetry in the lattice those ions form dipoles, which in turn form domains depending on the quality of the material Because of those dipoles, a hysteretic polarization-electric field (P-E ) curve is obtained (see Figure 2).
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
