Namrata Mendiratta scite author profile

Namrata Mendiratta

5Publications

20Citation Statements Received

87Citation Statements Given

How they've been cited

123

How they cite others

102

Affiliations

Lovely Professional University, Birla Institute of Technology, Mesra

Publications

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A review on performance comparison of advanced MOSFET structures below 45 nm technology node

Mendiratta¹,

Tripathi²

2020

J. Semicond.

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CMOS technology is one of the most frequently used technologies in the semiconductor industry as it can be successfully integrated with ICs. Every two years the number of MOS transistors doubles because the size of the MOSFET is reduced. Reducing the size of the MOSFET reduces the size of the channel length which causes short channel effects and it increases the leakage current. To reduce the short channel effects new designs and technologies are implemented. Double gate MOSFET design has shown improvement in performance as amplifiers over a single MOSFET. Silicon-based MOSFET design can be used in a harsh environment. It has been used in various applications such as in detecting biomolecules. The increase in number of gates increases the current drive capability of transistors. GAA MOSFET is an example of a quadruple gate around the four sides of channel that increases gate control over the channel region. It also increases effective channel width that improves drain current and reduces leakage current keeping short channel effects under limit. Junctionless MOSFET operates faster and uses less power with increase in ON-state current leading to a good value of I ON/I OFF ratio. In this paper, several gate and channel engineered MOSFET structures are analyzed and compared for sub 45 nm technology node. A comparison among different MOSFET structures has been made for subthreshold performance parameters in terms of I OFF, subthreshold slope and DIBL values. The analog/RF performance is analyzed for transconductance, effective transistor capacitances, stability factor and critical frequency. The paper also covers different applications of advance MOSFET structures in analog/digital or IoT/ biomedical applications.

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18nm n-channel and p-channel Dopingless Asymmetrical Junctionless DG-MOSFET: Low Power CMOS Based Digital and Memory Applications

Mendiratta

Tripathi

2021

Silicon

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In this paper, an 18nm dopingless asymmetrical junctionless (AJ) double gate (DG) MOSFET has been designed for suppressed short channel effects (SCEs) for low power applications. A desired ON and OFF state current ratio with subthreshold performance parameters under limit, is the major focus of the proposed transistor. Different sensitivity parameters of dopingless AJ DG MOSFET such as drain extension, length of gate overlapping and oxide thickness are compared with the AJ DG MOSFET with doped channel region. The ON-state current obtained is 3.80 x 10 −6 A/μm with reduced OFF-state leakage current up to1.37 x 10 −17 A/μm. The subthreshold slope (SS) and drain induced barrier lowering (DIBL) of the device obtained are 59.5 mV/decade and 10.5 mV/V respectively. Temperature analysis of proposed device at various temperature such as 250 K,300 K, 350 K and 400 K shows a small variation in OFF-state current (<15%). Additionally, a p-channel AJ DG MOSFET along with n-channel AJ DG MOSFET are designed and their performance is evaluated for CMOS inverter circuit and 6T SRAM cell. All the design and analysis has been done with a 2D/3D Visual TCAD device simulator.

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Design and Analysis of Heavily Doped n+ Pocket Asymmetrical Junction-Less Double Gate MOSFET for Biomedical Applications

et al. 2020

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The Complementary Metal-Oxide Semiconductor (CMOS) technology has evolved to a great extent and is being used for different applications like environmental, biomedical, radiofrequency and switching, etc. Metal-Oxide-Semiconductor Field-Effect Transistor (MOSFET) based biosensors are used for detecting various enzymes, molecules, pathogens and antigens efficiently with a less time-consuming process involved in comparison to other options. Early-stage detection of disease is easily possible using Field-Effect Transistor (FET) based biosensors. In this paper, a steep subthreshold heavily doped n+ pocket asymmetrical junctionless MOSFET is designed for biomedical applications by introducing a nanogap cavity region at the gate-oxide interface. The nanogap cavity region is introduced in such a manner that it is sensitive to variation in biomolecules present in the cavity region. The analysis is based on dielectric modulation or changes due to variation in the bio-molecules present in the environment or the human body. The analysis of proposed asymmetrical junctionless MOSFET with nanogap cavity region is carried out with different dielectric materials and variations in cavity length and height inside the gate–oxide interface. Further, this device also showed significant variation for changes in different introduced charged particles or region materials, as simulated through a 2D visual Technology Computer-Aided Design (TCAD) device simulator.

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Optimization of Capacitor for Piezoelectric Energy Harvesting

Mendiratta

Singh

Chattoraj

et al. 2018

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Analysis of gate engineered asymmetric junctionless double gate MOSFET for varying operating conditions

Mendiratta

Tripathi

Prakash

2020

IOP Conf. Ser.: Mater. Sci. Eng.

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In this paperan asymmetrical junctionless double-gate MOSFET(AJDG-MOSFET) has been analyzed using different gate oxide material like SiO2 and HfO2 and different gate contact material like aluminium, copper and polysilicon. To check the sensitivity of AJDG-MOSFET, a temperature analysis has been performed at a different temperature ranging 250-400K. The performance of AJDG-MOSFET is analyzed with transfer and output characteristics using 2D/3D simulation on Cogenda TCAD. The device performs better using HfO2 as gate oxide and polysilicon as gate contact. The ideal subthreshold performance (DIBL=65mV/V, SS=68 mV/decade) is observed with a high value of Ion/Ioff(∼1012) for 300K temperature. The analysis for temperature shows a very small variation in OFF current and found suitable for low power applications.

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