Your search keyword '"Floating gate devices"' showing total 10 results

1. The Nonvolatile Memory and Neuromorphic Simulation of ReS 2 /h-BN/Graphene Floating Gate Devices Under Photoelectrical Hybrid Modulations.

Author

Li W, Li J, Mu T, Li J, Sun P, Dai M, Chen Y, Yang R, Chen Z, Wang Y, Wu Y, and Wang S

Abstract

The floating gate devices, as a kind of nonvolatile memory, obtain great application potential in logic-in-memory chips. The 2D materials have been greatly studied due to atomically flat surfaces, higher carrier mobility, and excellent photoelectrical response. The 2D ReS 2 flake is an excellent candidate for channel materials due to thickness-independent direct bandgap and outstanding optoelectronic response. In this paper, the floating gate devices are prepared with the ReS 2 /h-BN/Gr heterojunction. It obtains superior nonvolatile electrical memory characteristics, including a higher memory window ratio (81.82%), tiny writing/erasing voltage (±8 V/2 ms), long retention (>1000 s), and stable endurance (>1000 times) as well as multiple memory states. Meanwhile, electrical writing and optical erasing are achieved by applying electrical and optical pulses, and multilevel storage can easily be achieved by regulating light pulse parameters. Finally, due to the ideal long-time potentiation/depression synaptic weights regulated by light pulses and electrical pulses, the convolutional neural network (CNN) constructed by ReS 2 /h-BN/Gr floating gate devices can achieve image recognition with an accuracy of up to 98.15% for MNIST dataset and 91.24% for Fashion-MNIST dataset. The research work adds a powerful option for 2D materials floating gate devices to apply to logic-in-memory chips and neuromorphic computing., (© 2024 Wiley‐VCH GmbH.)

Published

2024

2. Depth Dependence of Threshold Voltage Shift in 3-D Flash Memories Exposed to X-Rays.

Author

Bagatin, Marta, Gerardin, Simone, Paccagnella, Alessandro, and Beltrami, Silvia

Subjects

*FLASH memory, *THRESHOLD voltage, *BIT error rate, *X-rays, *TISSUE arrays, *NAND gates

Abstract

The effects of total ionizing dose on 3-D NAND floating gate cells with vertical architecture are analyzed as a function of the cell depth in the pillar. The focus of this work is on TID-induced threshold voltage shifts, but the implications on the raw bit error rates are also discussed. Underlying mechanisms are elucidated, concluding that due to the manufacturing process and the geometry of the pillars, the effects of total dose are larger at the bottom than at the top of the cell array. [ABSTRACT FROM AUTHOR]

Published

2021

3. Secondary Particles Generated by Protons in 3-D nand Flash Memories

Author

M. Bagatin, S. Gerardin, A. Paccagnella, A. Costantino, V. Ferlet-Cavrois, G. Santin, M. Muschitiello, A. Pesce, and S. Beltrami

Subjects

Nuclear and High Energy Physics, Monitoring, Loss measurement, Floating gate devices, Detectors, Flash memories, Particle beams, Heavy ion detectors, Nuclear Energy and Engineering, Proton detectors, Three-dimensional displays, Protons, Electrical and Electronic Engineering

Published

2022

4. Single Event Upsets Induced by Direct Ionization from Low-Energy Protons in Floating Gate Cells.

Author

Bagatin, Marta, Gerardin, Simone, Paccagnella, Alessandro, Visconti, Angelo, Virtanen, Ari, Kettunen, Heikki, Costantino, Alessandra, Ferlet-Cavrois, Veronique, and Zadeh, Ali

Subjects

*SINGLE event effects, *FLASH memory, *PROTON beams, *THRESHOLD voltage, *LINEAR energy transfer

Abstract

Floating gate cells in advanced NAND Flash memories, with single-level and multi-level cell architecture, were exposed to low-energy proton beams. The first experimental evidence of single event upsets by proton direct ionization in floating gate cells is reported. The dependence of the error rate versus proton energy is analyzed in a wide energy range. Proton direct ionization events are studied and energy loss in the overlayers is discussed. The threshold LET for floating gate errors in multi-level and single-level cell devices is modeled and technology scaling trends are analyzed, also discussing the impact of the particle track size. [ABSTRACT FROM PUBLISHER]

Published

2017

5. Depth Dependence of Threshold Voltage Shift in 3-D Flash Memories Exposed to X-Rays

Author

S. Beltrami, Marta Bagatin, Alessandro Paccagnella, and Simone Gerardin

Subjects

Nuclear and High Energy Physics, Materials science, 010308 nuclear & particles physics, business.industry, floating gate devices, NAND gate, total dose effects, Depth dependence, 01 natural sciences, Flash memories, Threshold voltage, total ionizing dose, Non-volatile memory, Flash (photography), Optics, Nuclear Energy and Engineering, Logic gate, Absorbed dose, 0103 physical sciences, sense organs, Electrical and Electronic Engineering, Focus (optics), business, 3-D NAND

Abstract

The effects of total ionizing dose on 3-D NAND floating gate cells with vertical architecture are analyzed as a function of the cell depth in the pillar. The focus of this work is on TID-induced threshold voltage shifts, but the implications on the raw bit error rates are also discussed. Underlying mechanisms are elucidated, concluding that due to the manufacturing process and the geometry of the pillars, the effects of total dose are larger at the bottom than at the top of the cell array.

Published

2021

6. Investigation of Low Dose Rate and Bias Conditions on the Total Dose Tolerance of a CMOS Flash-Based FPGA.

Author

Rezgui, Sana, Wilcox, Edward P., Lee, Poongyeub, Carts, Martin A., LaBel, Kenneth, Nguyen, Victor, Telecco, Nicola, and McCollum, John

Subjects

*COMPLEMENTARY metal oxide semiconductors, *GAMMA rays, *FIELD programmable gate arrays, *SINGLE event effects, *NUCLEAR science

Abstract

TID test results of CMOS Flash-based FPGAs in gamma-rays are presented. The use of realistic low dose-rates and oriented bias-conditions are shown to extend the FPGA TID tolerance. Implications to qualification methods and to most of the new CMOS technologies are noted. [ABSTRACT FROM PUBLISHER]

Published

2012

7. Novel approaches to radiation detection and readout using the latch up effect

Author

Villani, E.G., Gabrielli, A., DeMarchi, D., and Weber, M.

Subjects

*NUCLEAR counters, *SOLID state electronics, *THYRISTORS, *SILICON rectifiers, *PHYSICS experiments, *PIXELS

Abstract

Abstract: An alternative topology for solid-state pixel detectors is described. It is based on latch-up effect, usually exploited in solid-state electronic switches like thyristor and Silicon Controlled Rectifiers (SCRs). It is proposed here to use this effect as a simple building-block element for particle and radiation detection. Review of the latch-up effect and description of circuit topologies under investigation to assess the operating principle and initial experimental results will be presented. Applications in particle and radiation detection will be suggested. [Copyright &y& Elsevier]

Published

2009

8. Simulation of a Floating Gate device fabricated in standard CMOS technology for dosimetry applications

Author

Gabrielli A. and Villani G.

Subjects

Computer Science::Hardware Architecture, radiation detectors, Hardware_INTEGRATEDCIRCUITS, FLOATING GATE DEVICES, Hardware_PERFORMANCEANDRELIABILITY, Hardware_ARITHMETICANDLOGICSTRUCTURES

Abstract

The use of floating gate devices for storing digital information is well known. More recently, these devices have been proposed for analogue applications and for use in radiation detection. In this case, the charge generated in the SiO2 due to the ionizing radiation is collected by the floating gate by virtue of the electric field generated by the charge stored in it. This in turn changes some electrical characteristics of the device that can be measured and referred to the absorbed dose of ionizing radiation. A comprehensive device simulation that includes the process of charging the floating gate via tunnelling and the mechanism of charge collection from the SiO2 has been carried out using the process parameters of a standard CMOS 0.18μm technology. The results suggest that this device could be used as a sensitive integrated dosimeter that allows the fabrication of the readout electronics on the same silicon chip.

Published

2009

9. Floating gate devices: operations and compact modeling

Author

Paolo PAVAN, Luca Larcher, and Marmiroli, A.

Subjects

Floating Gate devices, device simulation, non-volaitle memories, Compact modeling

Published

2004

10. Impact Ionization and Hot-Electron Injection Derived Consistently from Boltzmann Transport

Author

Andreas G. Andreou, Carver A. Mead, Christopher J. Diorio, Bradley A. Minch, and Paul Hasler

Subjects

Physics, silicon electron transport, floating gate devices, Collision, Computer Graphics and Computer-Aided Design, Boltzmann equation, hot electron injection, lcsh:QA75.5-76.95, Computational physics, symbols.namesake, Impact ionization, MOSFET modeling, Distribution function, Depletion region, Hardware and Architecture, Boltzmann constant, symbols, lcsh:Electronic computers. Computer science, Electrical and Electronic Engineering, Simulation, Caltech Library Services, Hot-carrier injection, Voltage

Abstract

We develop a quantitative model of the impact-ionizationand hot-electron–injection processes in MOS devices from first principles. We begin by modeling hot-electron transport in the drain-to-channel depletion region using the spatially varying Boltzmann transport equation, and we analytically find a self consistent distribution function in a two step process. From the electron distribution function, we calculate the probabilities of impact ionization and hot-electron injection as functions of channel current, drain voltage, and floating-gate voltage. We compare our analytical model results to measurements in long-channel devices. The model simultaneously fits both the hot-electron- injection and impact-ionization data. These analytical results yield an energydependent impact-ionization collision rate that is consistent with numerically calculated collision rates reported in the literature.

Published

1998