Yi-Chuen Eng

Bio: Yi-Chuen Eng is an academic researcher from National Sun Yat-sen University. The author has contributed to research in topics: MOSFET & Transistor. The author has an hindex of 7, co-authored 88 publications receiving 219 citations.

Novel Vertical SOI-Based 1T-DRAM With Trench Body Structure

Abstract: A vertical silicon-on-insulator (VSOI)-based capacitorless 1T-DRAM cell with a trench body structure is proposed. The trench body is added as an additional neutral region under the device channel region through a self-aligned fabrication process in a 300 nm wide VSOI MOSFET that enables the device to separate the hole storage region and sense electron current region without extra area penalty. With the holes stored in the trench body, the floating-body effect occurs and affects the threshold voltage significantly. A Synopsys TCAD software tool is also used to evaluate the device performance for DC and transient analysis. The electrical and transient characteristics confirm how the proposed device with trench body can be used perfectly as a 1T-DRAM application to achieve desirable performance in terms of a larger programming window and longer retention time.

A simple process of thin-film transistor using the trench-oxide layer for improving 1T-DRAM performance

Abstract: In this paper, we propose a simple trench-oxide thin-film transistor (TO TFT) process for 1T-DRAM applications. Our proposed TO TFT structure has several novel features as follows: 1. The buried oxide and the isolation oxide are carried out simultaneously in order to achieve a goal of simple process. 2. The trench design is used to improve both the sensing current windows (∼ 72%) and the retention time (∼ 50%). 3. The thermal stability is drastically improved by its naturally formed source/drain tie. The above mentioned features help our proposed device structure to demonstrate the desired characteristics that are better than that of a conventional TFT. Additionally, the thermal instability is drastically improved which is good for long-term device operation.

Characteristics of a new trench-oxide thin-film transistor and its 1T-DRAM applications

Abstract: In this paper, we propose a simple trench-oxide thin-film transistor (TO TFT) process for 1T-DRAM applications. Our proposed TO TFT structure has several novel features as follows: 1. The buried oxide and the isolation oxide are carried out simultaneously in order to achieve a goal of simple process. 2. The trench design is used to improve both the sensing current windows (∼ 84%) and the retention time (∼ 57%). 3. The thermal stability is drastically improved by its naturally formed source/drain tie. The above mentioned features help our proposed device structure to demonstrate the desired characteristics that are better than that of a conventional TFT. Additionally, the thermal instability is drastically improved which is good for long-term device operation.

A novel high-performance junctionless vertical MOSFET produced on bulk-Si wafer

Abstract: In this paper, we propose a junctionless vertical MOSFET (JLVMOS) based on bulk-Si wafer. According to the numerical simulations, the proposed JLVMOS can get a steep subthreshold swing (S. Swing), reduced DIBL, and higher I ON /I OFF ratio, in comparison to a junctionless planar SOI MOSFET. This is because the vertical double-gate (DG) structure truly helps reduce the short-channel effects (SCEs). More importantly, SOI wafer is not necessary as a starting material for our proposed junctionless transistor, which is good for low-cost mass production.

Numerical Study of a Highly Scaled Bulk MOSFET With Block Oxide and Source/Drain-Tied Structure

Abstract: In this paper, we present a highly scaled bulk metal-oxide-semiconductor field-effect transistor with block oxide (BO) and source/drain (S/D)-tied structure that meets the International Technology Roadmap for Semiconductors requirements for high-performance devices. This new device requires only a simple BO fabrication process using SiGe-Si epitaxial growth with selective SiGe removal and requires no additional lithography masks. This proposed BO fabrication process is simple due to it being controllable, repeatable, and fully compatible with standard complementary metal-oxide-semiconductor technology. According to 3-D simulations, our proposed structure not only exhibits its structural advantages to overcome scaling obstacles but also extends the use of planar bulk technology to the decananometer regime.

Enhanced Electrostatic Integrity of Short-Channel Junctionless Transistor With High- $\kappa$ Spacers

Abstract: We propose the use of a high-κ spacer to improve the electrostatic integrity and, thereby, the scalability of silicon junctionless transistors (JLTs) for the first time. Using extensive simulations of n-channel JLTs, we demonstrate that the high-κ spacers improve the electrostatic integrity of JLTs at sub-22-nm gate lengths. Electric field that fringes through the high-κ spacer to the device layer on either sides of the gate results in an effective increase in electrical gate length in the off-state. However, the effective gate length is unaffected in the on-state. Hence, the off-state leakage current is reduced by several orders of magnitude with the use of a high-κ spacer with concomitent improvements in the subthreshold swing and drain-induced barrier lowering. A marginal improvement in the on-state current is observed with the use of the high-κ spacer, and this is related to the reduction in parasitic resistance in the silicon under the spacer due to fringe fields.

Investigation of Silicon Nanowire Gate-All-Around Junctionless Transistors Built on a Bulk Substrate

Abstract: A silicon nanowire (Si-NW) with a gate-all-around (GAA) structure is implemented on a bulk wafer for a junctionless (JL) field-effect transistor (FET). A suspended Si-NW from the bulk-Si is realized using a deep reactive ion etching (RIE) process. The RIE process is iteratively applied to make multiply stacked Si-NWs, which can increase the on-state current when amplified with the number of iterations or enable integration of 3-D stacked Flash memory. The fabricated JL FETs exhibit excellent electrostatic control with the aid of the GAA and junction-free structure. The influence on device characteristics according to the channel dimensions and additional doping at the source and drain extension are studied for various geometric structures of the Si-NW.

Semiconductor device having electrically floating body transistor, semiconductor device having both volatile and non-volatile functionality and method of operating

Abstract: A semiconductor memory cell includes a floating body region configured to be charged to a level indicative of a state of the memory cell; a first region in electrical contact with said floating body region; a second region in electrical contact with said floating body region and spaced apart from said first region; and a gate positioned between said first and second regions. The cell may be a multi-level cell. Arrays of memory cells are disclosed for making a memory device. Methods of operating memory cells are also provided.