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In this paper, we propose a novel structure with Control Source and Control Gate structured tunnel field-effect transistor (CSCG‑iTFET), which achieves an unprecedentedly steep subthreshold swing (SS) while maintaining high ON-state current ( ). In addition, using Schottky contacts at the source without doping reduces leakage current and thermal budget. We compared the performance of four different device structures, including conventional Double Gate TFET with Control Gate, iTFET with Control Gate, iTFET with Charge Enhancement Layer and Control Gate, and our structure. The accumulation layer can be enhanced by using the characteristic of Control Source to modulate the voltage. We performed simulation studies using Sentaurus TCAD. Utilize calibrated models for accurate simulations, exploiting the same referenced processes, demonstrate that the Control Source iTFET exhibits an average subthreshold swing S.S AVG of 9.69 mV/Dec and a minimum subthreshold swing S.S MIN of 1.72 mV/Dec, respectively. At V D = 0.2 V, the I ON current is 2.95 × 10 − 7 A/µm, and the I ON / I OFF ratio is 3.84 × 10 9 . It is believed that the performance can be further improved if the fabrication processes are optimized.

Nanosheet transistors are poised to become the preferred choice for the next generation of smaller-sized devices in the future. To address the future demand for high-performance and low-power computing applications, this study proposes a nanosheet structure with a vertically stacked design, featuring a high ION/IOFF ratio. This Nanosheet design is combined with an induced tunnel field-effect transistor. By utilizing SiGe with a carrier mobility three times that of Si and employing a line tunneling mechanism, the research successfully achieves superior Band to Band characteristics, resulting in improved switching behavior and a lower Subthreshold Swing (SS). Comparative studies were conducted on three TFET types: Nanosheet PIN TFET, Nanosheet Schottky iTFET, and Fin iTFET. Results show that the Nanosheet PIN TFET has a higher ION/IOFF ratio but poorer SSavg values at 47.63 mV/dec compared to the others. However, with a SiGe Body thickness of 3 nm, both Nanosheet iTFET and Fin iTFET exhibit higher ION/IOFF ratios and superior SSavg values at 17.64 mV/dec. These findings suggest the potential of Nanosheet iTFET and Fin iTFET for low-power, lower thermal budgets, and fast-switching applications.

In this paper, we introduce a novel Forkshape nanosheet Inductive Tunnel Field-Effect Transistor (FS-iTFET) featuring a Gate-All-Around structure and a full-line tunneling heterojunction channel. The overlapping gate and source contact regions create a strong and uniform electric field in the channel. Furthermore, the metal–semiconductor Schottky junction in the intrinsic source region induces the required carriers without the need for doping. This innovative design achieves both a steeper subthreshold swing (SS) and a higher ON-state current (ION). Using calibration-based simulations with Sentaurus TCAD, we compare the performance of three newly designed device structures: the conventional Nanosheet Tunnel Field-Effect Transistor (NS-TFET), the Nanosheet Line-tunneling TFET (NS-LTFET), and the proposed FS-iTFET. Simulation results show that, compared to the traditional NS-TFET, the NS-LTFET with its full line-tunneling structure improves the average subthreshold swing (SSAVG) by 19.2%. More significantly, the FS-iTFET, utilizing the Schottky-inductive source, further improves the SSAVG by 49% and achieves a superior ION/IOFF ratio. Additionally, we explore the impact of Trap-Assisted Tunneling on the performance of the three different integrations. The FS-iTFET consistently demonstrates superior performance across various metrics, highlighting its potential in advancing tunnel field-effect transistor technology.

This article presents a new line tunneling dominating metal–semiconductor contact-induced SiGe–Si tunnel field-effect transistor with control gate (CG-Line SiGe/Si iTFET). With a structure where two symmetrical control gates at the drain region are given a sufficient negative bias, the overlap of the energy bands at the drain in the OFF-state is effectively suppressed, thus reducing the tunneling probability and significantly decreasing leakage current. Additionally, the large overlap area between the source and gate improves the gate’s ability to control the tunneling interface effectively, improving the ON-state current and subthreshold swing characteristics. By using the Schottky contact characteristics of a metal–semiconductor contact with different work functions to form a PN junction, the need to control doping profiles or random doping fluctuations is avoided. Furthermore, as ion implantation is not required, issues related to subsequent annealing are also eliminated, greatly reducing thermal budget. Due to the different material bandgap characteristics selected for the source and drain regions, the probability of overlap of the energy bands in the source region in the ON-state is increased and that in the drain region in the OFF-state is reduced. Based on the feasibility of the actual fabrication process and through rigorous 2D simulation studies, improvements in subthreshold swing and high on/off current ratio can be achieved simultaneously based on the proposed device structure. Additionally, the presence of the control gate structure effectively suppresses leakage current, further enhancing its potential for low-power-consumption applications.

In this paper, we propose an inductive line tunneling FET using Epitaxial Tunnel Layer with Ge-Source and Charge Enhancement Insulation (CEI ETL GS-iTFET). The CEI ETL GS-iTFET allows full overlap between the gate and source regions, thereby enhancing the line tunneling. In addition, a germanium layer is introduced on the source side to form a heterojunction, effectively improving the device's conduction current. An ETL is incorporated to combat point tunneling leakage, resulting in a steeper subthreshold swing. Furthermore, a CEI consisting of Si3N4 is introduced between the germanium source and the Schottky metal, which effectively reduces carrier losses in the inversion layer and improves the overall device performance. This study presents a calibration-based approach to simulations, taking into account practical process considerations. Simulation results show that at VD = 0.2 V, the CEI ETL GS-iTFET achieves an average subthreshold swing (SSavg) of 30.5 mV/dec, an Ion of 3.12 × 10–5 A/μm and an Ion/Ioff ratio of 1.81 × 1010. These results demonstrate a significantly low subthreshold swing and a high current ratio of about 1010. In addition, the proposed device eliminates the need for multiple implantation processes, resulting in significant manufacturing cost reductions. As a result, the CEI ETL GS-iTFET shows remarkable potential in future low-power device competition.

In this paper, we propose the use of punch-through nMOS (PTnMOS) as an alternative to pMOS in complementary metal oxide semiconductor (CMOS) circuits. According to the TCAD simulation results, PTnMOS exhibit sub-threshold characteristics similar to those of pMOS and can be formed by simply changing the doping concentration of the source and drain. Without the need for sizing, which solves the area occupation problem caused by the need to increase the width of pMOS due to insufficient hole mobility. In addition, we compose a PTnMOS and nMOS without sizing to form a single-carrier CMOS in which only electrons are transmitted, and We extract its performance for comparison with conventional CMOS (Wp/Wn = 1). The results indicate that single-carrier CMOS has symmetric noise margin and 29% faster delay time compared to conventional CMOS (Wp/Wn = 1). If III–V or II–VI group materials could be applied to single-carrier CMOS, not only could costs be reduced and wafer area occupancy minimized, but also significant improvements in the performance and bandwidth application of microwave circuits could be achieved.

In this paper, we present a new novel simple iTFET with overlapping gate on source-contact (SGO), Drain Schottky Contact, and intrinsic SiGe pocket (Pocket-SGO iTFET). The aim is to achieve steep subthreshold swing (S.S) and high ION current. By optimizing the gate and source-contact overlap, the tunneling efficiency is significantly enhanced, while the ambipolar effect is suppressed. Additionally, using a Schottky contact at the drain/source, instead of ion implantation drain/source, reduces leakage current and thermal budget. Moreover, the tunneling region is replaced by an intrinsic SiGe pocket posing a narrower bandgap, which increases the probability of band-to-band tunneling and enhances the ION current. Our simulations are based on the feasibility of the actual process, thorough Sentaurus TCAD simulations demonstrate that the Pocket-SGO iTFET exhibits an average and minimum subthreshold swing of S.Savg = 16.2 mV/Dec and S.Smin = 4.62 mV/Dec, respectively. At VD = 0.2 V, the ION current is 1.81 × 10–6 A/μm, and the ION/IOFF ratio is 1.34 × 109. The Pocket-SGO iTFET design shows great potential for ultra-low-power devices that are required for the Internet of Things (IoT) and AI applications.

While same-sex marriage has been a particularly salient issue in recent years in Taiwan, few scholarly attentions have been paid to examine the determinants of individual attitudes toward same-sex marriage. This study attempts to understand how personality influences individual support for same-sex marriage in Taiwan. Using the original data collected in July 2017 in Taiwan, this study finds that people with higher levels of agreeableness are more likely to oppose same-sex marriage. Besides, conscientiousness and openness to experience have heterogeneous effects on individual attitudes toward same-sex marriage for people of different ages. Specifically, a higher level of conscientiousness is positively associated with support for same-sex marriage among younger people but is negatively correlated with support for same-sex marriage among older people. Similarly, a higher level of openness to experience would lead to increased support for same-sex marriage for younger people but would result in decreased support for same-sex marriage for older people. Overall, our findings indicate that personality can provide some explanatory power for individual attitudes toward homosexual rights.

The original version of this article unfortunately contained a mistake. The name of “Tsong-Jyi Lin” is now corrected in the author group of this article.

We demonstrate improved device performance by applying oxide sidewall spacer technology to a block-oxide-enclosed Si body to create a fully depleted silicon-on-insulator (FDSOI) nMOSFET, which overcomes the need for a uniform ultrathin silicon film. The presence of block-oxide along the sidewalls of the Si body significantly reduces the influence of drain bias over the channel. The proposed FDSOI structure therefore outperforms conventional FDSOI with regard to its drain-induced barrier lowering (DIBL), on/off current ratio, subthreshold swing, and threshold voltage rolloff. The new FDSOI structure is in fact shown to behave similarly to an ultrathin body (UTB) SOI but without the associated disadvantages and technological challenges of the ultrathin film, because a thick Si body allows for reduced sensitivity to self-heating, thereby improving thermal stability.