An accurate analytical model for tunnel FET output characteristics

The analytical models for the output characteristics of tunnel FETs (TFETs) based on Maxwell–Boltzmann (MB) statistics have some accuracy issues, especially in linear region of operation, when compared with more sophisticated numerical approaches. In this letter, by exploiting the thermal injection method (TIM), an accurate analytical model for the TFET potential profile is proposed. Although the approach is initially envisaged for heterojunction TFETs (H-TFETs), it could be straightforwardly adopted for homojunction TFETs. After an accurate description of the potential profile is obtained, then, the current is computed by means of a Landauer-like expression. Comparison with the numerical simulations at different bias conditions show that the predicted output characteristics qualitatively improve, leading to a significant enhancement in accuracy at a much less-computational cost

A review of selected topics in physics based modeling for tunnel field-effect transistors

The research field on tunnel-FETs (TFETs) has been rapidly developing in the last ten years, driven by the quest for a new electronic switch operating at a supply voltage well below 1 V and thus delivering substantial improvements in the energy efficiency of integrated circuits. This paper reviews several aspects related to physics based modeling in TFETs, and shows how the description of these transistors implies a remarkable innovation and poses new challenges compared to conventional MOSFETs. A hierarchy of numerical models exist for TFETs covering a wide range of predictive capabilities and computational complexities. We start by reviewing seminal contributions on direct and indirect band-to-band tunneling (BTBT) modeling in semiconductors, from which most TCAD models have been actually derived. Then we move to the features and limitations of TCAD models themselves and to the discussion of what we define non-self-consistent quantum models, where BTBT is computed with rigorous quantum-mechanical models starting from frozen potential profiles and closed-boundary Schr\uf6dinger equation problems. We will then address models that solve the open-boundary Schr\uf6dinger equation problem, based either on the non-equilibrium Green's function NEGF or on the quantum-transmitting-boundary formalism, and show how the computational burden of these models may vary in a wide range depending on the Hamiltonian employed in the calculations. A specific section is devoted to TFETs based on 2D crystals and van der Waals hetero-structures. The main goal of this paper is to provide the reader with an introduction to the most important physics based models for TFETs, and with a possible guidance to the wide and rapidly developing literature in this exciting research field

Comprehensive Mapping and Benchmarking of Esaki Diode Performance

The tunneling-FET (TFET) has been identified as a prospective MOSFET replacement technology with the potential to extend geometric and electrostatic scaling of digital integrated circuits. However, experimental demonstrations of the TFET have yet to reliably achieve drive currents necessary to power large scale integrated circuits. Consequentially, much effort has gone into optimizing the band-to-band tunneling (BTBT) efficiency of the TFET. In this work, the Esaki tunnel diode (ETD) is used as a short loop element to map and optimize BTBT performance for a large design space. The experimental results and tools developed for this work may be used to (1) map additional and more complicated ETD structures, (2) guide development of improved TFET structures and BTBT devices, (3) design ETDs targeted BTBT characteristics, and (4) calibrate BTBT models. The first objective was to verify the quality of monolithically integrated III-V based ETDs on Si substrates (the industry standard). Five separate GaAs/InGaAs ETDs were fabricated on GaAs-virtual substrates via aspect ratio trapping, along with two companion ETDs grown on Si and GaAs bulk substrates. The quality of the virtual substrates and BTBT were verified with (i) very large peak-valley current ratios (up to 56), (ii) temperature measurements, and (iii) deep sub-micron scaling. The second objective mapped the BTBT characteristics of the In1-xGaxAs ternary system by (1) standardizing the ETD structure, (2) limiting experimental work to unstrained (i) GaAs, (ii) In0.53Ga0.47As, and (iii) InAs homojunctions, and (3) systematically varying doping concentrations. Characteristic BTBT trendlines were determined for each material system, ranging from ultra-low to ultra-high peak current densities (JP) of 11 μA/cm2 to 975 kA/cm2 for GaAs and In0.53Ga0.47As, respectively. Furthermore, the BTBT mapping results establishes that BTBT current densities can only be improved by ~2-3 times the current record, by increasing doping concentration and In content up to ~75%. The E. O. Kane BTBT model has been shown to accurately predict the tunneling characteristics for the entire design space. Furthermore, it was used to help guide the development of a new universal BTBT model, which is a closed form exponential using 2 fitting parameters, material constants, and doping concentrations. With it, JP can quickly be predicted over the entire design space of this work

Digital and analog TFET circuits: Design and benchmark

In this work, we investigate by means of simulations the performance of basic digital, analog, and mixed-signal circuits employing tunnel-FETs (TFETs). The analysis reviews and complements our previous papers on these topics. By considering the same devices for all the analysis, we are able to draw consistent conclusions for a wide variety of circuits. A virtual complementary TFET technology consisting of III-V heterojunction nanowires is considered. Technology Computer Aided Design (TCAD) models are calibrated against the results of advanced full-quantum simulation tools and then used to generate look-up-tables suited for circuit simulations. The virtual complementary TFET technology is benchmarked against predictive technology models (PTM) of complementary silicon FinFETs for the 10 nm node over a wide range of supply voltages (VDD) in the sub-threshold voltage domain considering the same footprint between the vertical TFETs and the lateral FinFETs and the same static power. In spite of the asymmetry between p- and n-type transistors, the results show clear advantages of TFET technology over FinFET for VDDlower than 0.4 V. Moreover, we highlight how differences in the I-V characteristics of FinFETs and TFETs suggest to adapt the circuit topologies used to implement basic digital and analog blocks with respect to the most common CMOS solutions

A Study on the Effect of the Structural Parameters and Internal Mechanism of a Bilateral Gate-Controlled S/D Symmetric and Interchangeable Bidirectional Tunnel Field Effect Transistor

A bilateral gate-controlled S/D symmetric and interchangeable bidirectional tunnel field effect transistor (B-TFET) is proposed in this paper, which shows the advantage of bidirectional switching characteristics and compatibility with CMOS integrated circuits compared to the conventional asymmetrical TFET. The effects of the structural parameters, e.g., the doping concentrations of the N+ region and P+ region, length of the N+ region and length of the intrinsic region, on the device performances, e.g., the transfer characteristics, Ion–Ioff ratio and subthreshold swing, and the internal mechanism are discussed and explained in detail.The Natural Science Foundation of Liaoning Province No. 2019-MS-250. This fund is used to pay for the publication of papers