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Hamdy Mohamed Abdelhamid Hamed
- Associate Professor
- Ext: 6551
Hamdy Abdelhamid, in 2005, he obtained a Diplôme des Etudes Approfondies (DEA) and in 2007 a Ph.D. and European Doctorate from the Universitat Rovira i Virgili in Spain. His doctoral research focused on the development of CAD models for modern (nanoscale) SOI MOSFETs from DC to RF conditions. In 2005, Abdelhamid was a Graduate Visiting researcher at the University of Liverpool’s Electrical Engineering Department in the U.K. In 2007, he joined the Microelectronics Laboratory at Université catholique de Louvain in Belgium. He participated in a number of short courses on Silicon On Insulator (SOI) technology at universities, industrial companies and conferences. He also attended several Euro training courses on SOI technology, devices and circuits. From October 2007 to September 2009, Abdelhamid worked as a Postdoctoral Fellow at McMaster University’s Department of Electronics Engineering in Canada. Since Sep. 2012 to 2019, Dr Abdelhamid joined the center of nanoelectronics and devices, Zewail city of science and technology, Egypt. Abd El-Hamid authored and coauthored more than seventy research papers in device modeling, Energy harvesting, biosensors, VLSI and device/circuit simulations that were published in international journals and conference proceedings. He also has couples of book chapters, patents and prototypes. Dr. Abdelhamid received funds from ITIDA (Egypt) for Energy harvesting and for biomedical platform projects. He received funds from ASRT- Egyptian Deepen Local Manufacturing- Electronics Industry (DLMEI) for design and fabricate CMOS micro-energy harvesting sources. Dr. Abdelhamid also has received funds from Ajman University for implementing micro-grid systems, a Biosensor platform for bacteria detection, and COIVD-19. Dr. Abdelhamid is an IEEE senior member since 2015. Dr. Abd El-Hamid has been made a member of the American Nano Society and the Nanotech-Bank, in light of his scientific contributions in nanoelectronics and nanotechnology. In 2020, Dr. Abdelhamid has been nominated as technical committee member of IEEE Electron Devices Society (EDS). In Jan. 2019, Dr. Abdelhamid joined the Electrical Engineering, department, University of Ajman, UAE as a full-time associate professor to present.
Education
- PhD of electronics Engineering, Rovira i Virigili University, Spain, 2007
- Diplôme des Etudes Approfondies (DEA) , Rovira i Virgili University, Spain, 2005
- Master Of Electronics Engineering, Ain Shams University, Egypt, 2000
- Bsc of Electrical Engineering,
PhD of electronics Engineering, Rovira i Virigili University, Spain, 2007
Diplôme des Etudes Approfondies (DEA) , Rovira i Virgili University, Spain, 2005
Master Of Electronics Engineering, Ain Shams University, Egypt, 2000
Bsc of Electrical Engineering,
Experience
- Associate professor, Zewail city of science and technology also adjunct at the American University in Cairo
- Associate professor, Nanoelectronics and Devices, American University in Cairo
- Assistant Professor, Electronics Engineering, British University in Egypt,
- Postdoctoral Fellowship, McMaster University, Canada,
- Associate professor, college of Engineering and IT, Ajman university, UAE
Associate professor, Zewail city of science and technology also adjunct at the American University in Cairo
Associate professor, Nanoelectronics and Devices, American University in Cairo
Assistant Professor, Electronics Engineering, British University in Egypt,
Postdoctoral Fellowship, McMaster University, Canada,
Associate professor, college of Engineering and IT, Ajman university, UAE
Teaching Area
- Semiconductor devices,
- Nanoelectronics and Nanotechnology,
- Digital and analog design,
- CAD tools for modern nanoscale transistors
- Electric circuit analysis (undergraduate)
- Digital logic design (undergraduate)
- Computer architecture (undergraduate)
- Analog electronics
- Energy harvesting sources
Semiconductor devices,
Nanoelectronics and Nanotechnology,
Digital and analog design,
CAD tools for modern nanoscale transistors
Electric circuit analysis (undergraduate)
Digital logic design (undergraduate)
Computer architecture (undergraduate)
Analog electronics
Energy harvesting sources
Research
- CAD tools for Nanoscale devices
- Renewable Energy
- Nanotechnology Engineering
- Very Large Integrated Circuits Design and Testing
- Biosensors
- Nano-systems
CAD tools for Nanoscale devices
Renewable Energy
Nanotechnology Engineering
Very Large Integrated Circuits Design and Testing
Biosensors
Nano-systems
Publications
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https://scholar.google.com/citations?user=f31xXtcAAAAJ
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JournalHamdy Abdelhamid, Amgad El-Deib, Khalil ElKhamisy, Khaled El-Shekh & Zulfiqar Memon , Experimental validation of different PV technologies using a physical-based model, Optical and quantum electronics, Jan 2022, doi: 10.1007/s11082-022-03768-8
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JournalHamdyAbdelhamid, Tamer Z.Salem, Mohamed Wahb, Dina Mofed, Omar E.Morsy, Red Abdelbaset, A capacitive sensor for differentiation between virus-infected and uninfected cells, June 2022, Sensing and Bio-Sensing Research, Jan 2022, doi: 10.1016/j.sbsr.2022.100497
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JournalKhalil ElKhamisy, Hamdy Abdelhamid, Salah Elagooz & El-Sayed El-Rabaie , The efficiency of silicon thin film solar cell: impact of temperature with different surface shapes, 2022, Optical and quantum electronics, Jan 2022, doi: 10.1007/s10825-021-01729-0
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ConferenceKhalil ElKhamisy; Hamdy Abdelhamid; Salah Elagooz; El-Sayed M. El-Rabaie, The Effects of surface plasmon polariton on Silicon Thin Film Solar Cell Array, 2022, 2021 9th International Japan-Africa Conference on Electronics, Communications, and Computations (JAC-ECC), Cairo
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The effect of different surface plasmon polariton shapes on thin-film solar cell efficiency, Journal of Computational Electronics volume 20, pp 1807–1814 (2021)
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ConferenceHamdy Abdelhamid; Ibrahim Khalaf; Ahmed Hussien; Reda Abdelbaset, Dielectrophoretic based Microfluidic for nanoparticles “viruses” separation, 2021, 2021 3rd Novel Intelligent and Leading Emerging Sciences Conference (NILES), Cairo
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Detection of foodborne pathogens using novel vertical capacitive sensors, Alexandria Engineering Journal, September 2021
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Electrical characteristics of modified truncated cone nanowire for efficient light trapping, Journal of Photonics and Nanostructures-Fundamentals and Applications 38, 2020
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Charge Independent DC Model for Floating Gate MOSFET Used for Flash Memory and Electro-optic Switching Applications. Nonlinear Optics, Quantum Optics: Concepts in Modern Optics 50 (4), 2019
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CMOS-compatible hybrid bi-metallic TE/TM-pass polarizers based on ITO and ZrN. journal of Applied optics 58 (24), 2019
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Two-dimensional model for double-gate LDMOSFET devices. Journal of Computational Electronics, 1-11, 2019
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A Novel Physical Modelling of FGMOSFET used in Circuit Simulators for Low-Power Systems and Optical Devices Applications. 2019 36th National Radio Science Conference (NRSC), 350-359, 2019
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Fast and accurate PV model for SPICE simulation. Journal of Computational Electronics 18 (1), 260-270, 2019
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An electro-kinetic platform based on printed circuit Board technology for identification and characterization of biological cells. Journal of Microelectronic Engineering, 2019
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Unified Quantum and Reliability Model for Ultra-Thin Double-Gate MOSFETs. Journal of Silicon, 1-8, 2019
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Magnetic Field Effect on Threshold Voltage for Ultrathin Silicon Gate-All-Around Nanowire Field-Effect-Transistors. Journal of Silicon, 2019
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Charge Independent DC Model for Floating Gate MOSFET Used for Flash Memory and Electro-optic Switching Applications. Journal of Nonlinear Optics Quantum Optics, 1-16, 2019
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Technology Scaling Roadmap for FinFET-Based FPGA Clusters Under Process Variations. Journal of Circuits, Systems and Computers 27 (04), 1850056, 2018
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Thermal resistance model for standard CMOS thermoelectric generator. Journal of IEEE Access 6, 8123-8132, 2018
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Detection of Hepatocellular carcinoma in clinical specimens using Dielectrophoresis based ElectroKinetic Platform, Sensors and Actuators A: Physical 316, 112402
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JournalQiong Zhang, Minglin Zhao, Yang Li, Ang Bian, Ramy El-Bashar, Hamdy Abdelhamid, Salah S. A. Obayya, Mohamed Farhat O. Hameed, and Jun Dai, Polarization dependent exciton-plasmon coupling in PEA2PbI4/Al and its application to perovskite solar cell, 2024, Optics Express, Jun 2024, doi: https://doi.org/10.1364/OE.529605
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JournalAwad Khaled, Mohamed Farhat O. Hameed, Hamdy Abdelhamid, and Salah S. A. Obayya, Impact of aluminum concentration and grading configuration of AlxGa1-xAs nanostructures for solar absorber applications, 2024, Journal of Photonics for Energy, Apr 2024, doi: https://doi.org/10.1117/1.JPE.14.025501
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JournalKhalil ElKhamisy, Hamdy Abdelhamid, El-Sayed M. El-Rabaie & Nariman Abdel-Salam, A Comprehensive Survey of Silicon Thin-film Solar Cell: Challenges and Novel Trends,2024, Plasmonics, Jul 2023, doi: https://doi.org/10.1007/s11468-023-01905-x
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ConferenceNumerical Investigation of Si Nanowires Integrated Perovskite for Efficient Tandem Solar Cell, 2024, Information Technology (ACIT), Ajman
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JournalThe Effects of Temperature Variation with Surface Triangle Grating on Silicon Thin-Film Solar Cell Array Efficiency, 2021, Plasmonics, Oct 2023, doi: https://doi.org/10.1007/s11468-023-02093-4
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JournalImpact of Bottom Dielectric Isolation of Si-Stacked Nanosheet Transistor on Stress and Self-Heating at 3-nm Node and Beyond, 2023, IEEE Transactions on Electron Devices, Oct 2023, doi: 10.1109/TED.2023.3318554
https://scholar.google.com/citations?user=f31xXtcAAAAJ
Hamdy Abdelhamid, Amgad El-Deib, Khalil ElKhamisy, Khaled El-Shekh & Zulfiqar Memon , Experimental validation of different PV technologies using a physical-based model, Optical and quantum electronics, Jan 2022, doi: 10.1007/s11082-022-03768-8
In this work, a simple, compact, and accurate model for PV is introduced. The introduced model used the five-parameter approximation that accounts for both irradiance and temperature variations. The introduced model studied the effect of semiconductor parameters such as doping level, electron, and whole mobilities. The model is verified experimentally using electronic power load at different levels of irradiance and temperature. Also, an integrated module using Simulink simulation is introduced of about 1% error compared to the experimental results. In this work, we used four different PV modules to verify the introduced model. The model accuracy of the proposed reaches 0.85% at different levels of temperature and irradiance of 1000 W/m2.
About the journal
HamdyAbdelhamid, Tamer Z.Salem, Mohamed Wahb, Dina Mofed, Omar E.Morsy, Red Abdelbaset, A capacitive sensor for differentiation between virus-infected and uninfected cells, June 2022, Sensing and Bio-Sensing Research, Jan 2022, doi: 10.1016/j.sbsr.2022.100497
Traditional biosensors are costly, cumbersome, and take a long time to report results, which limits their use in resource-constrained areas. Due to its high integration, customized architecture, and ease of mass processing, biosensors have been widely used in biomedical applications in recent years. In this paper, a biosensor is implemented using flexible printed circuit board technology for monitoring and identifying the effect of Baculovirus infection on one of its host cells (Sf9 cells) through many electrical features such as capacitance, impedance, permittivity, and conductivity. Furthermore, the effect of viral infection with different particle concentrations at different times was characterized. The results proved that the virus has a rapid effect on the cell by losing its electrical properties, which were clear from the decrease in electrical properties (e.g., capacitance, impedance, permittivity, and conductivity). Moreover, we introduced an equivalent model to represent the normal cells and infected cells based on the experimental results obtained for capacitance values. The proposed model simulation results are matched with the results obtained experimentally, which leads to the use of the model for predicting baculovirus infection. © 2022 The Authors
About the journal
Khalil ElKhamisy, Hamdy Abdelhamid, Salah Elagooz & El-Sayed El-Rabaie , The efficiency of silicon thin film solar cell: impact of temperature with different surface shapes, 2022, Optical and quantum electronics, Jan 2022, doi: 10.1007/s10825-021-01729-0
In this work, the temperature effects on the PV’s electrical and optical parameters of different surface gratings are studied. A 3D simulation is introduced for studying the PV’s electrical parameters such as short circuit current, open-circuit voltage, and efficiency at different levels of temperature with and without surface gratings. We observed that the efficiency is increased for the PV of surface grating by about 4.87% compared to the free grating surface’s PV. The efficiency of PV efficiency is degraded when the temperature is increased above 300 K. The solar cell efficiency of gratings free is aggressively degraded compared to the solar cell that includes gratings by about 4.89% at 360 K. The electrical parameters such as the open-circuit voltage and short-circuit current are enhanced compared to the PV of surface grating free. Also, we observed that the triangle grating geometry of dimensions about 10 × 10 nm produced a higher efficiency compared to the other PV of other grating geometries of the same dimensions. © 2021, The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature.
About the journal
Khalil ElKhamisy; Hamdy Abdelhamid; Salah Elagooz; El-Sayed M. El-Rabaie, The Effects of surface plasmon polariton on Silicon Thin Film Solar Cell Array, 2022, 2021 9th International Japan-Africa Conference on Electronics, Communications, and Computations (JAC-ECC), Cairo
In this paper, we investigate the impact of surface plasmon polariton on the entire array of silicon thin-film solar cells. The electromagnetic and semiconductor models are used to investigate the optical and electrical properties of thin-film solar cells, respectively. This study is introduced by using the 3D Multiphysics simulator. A 14.76% efficiency is achieved for the triangle’ SPPs of 1.07% improvement compared with a solar cell with SPPs free. MATLAB/SIMULINK model based on mathematical equations was introduced for thin-film solar cells to study the complete array. This method is suggested to simulate the thin film array in a very short time.
About the journal
The effect of different surface plasmon polariton shapes on thin-film solar cell efficiency, Journal of Computational Electronics volume 20, pp 1807–1814 (2021)
The effects of surface plasmon polaritons (SPPs) on the efficiency, series resistance, and shunt resistance of thin-film Si solar cells are studied and analyzed in this work. Different SPP shapes and their effects on the optical and electrical properties and thereby the efficiency of thin-film solar cells are studied. Semiconductor and electromagnetic models are incorporated to study the electrical and optical behaviors of the thin-film solar cells, respectively, using COMSOL Multiphysics three-dimensional (3D) numerical simulation software. An efficiency of 14.76% is achieved for triangular SPPs, representing a 1.07% improvement compared with SPP-free solar cells. The solar cell electrical parameters are also extracted based on a single-diode equivalent model. The series resistance is decreased by 3% for solar cells having equilateral-triangle SPPs compared with SPP-free solar cells.
About the journal
Hamdy Abdelhamid; Ibrahim Khalaf; Ahmed Hussien; Reda Abdelbaset, Dielectrophoretic based Microfluidic for nanoparticles “viruses” separation, 2021, 2021 3rd Novel Intelligent and Leading Emerging Sciences Conference (NILES), Cairo
The objective of this paper is to provide a microfluidic platform that may be useful to manipulate and characterize different submicron particles such as latex spheres as well as viruses (E.g. SARS-COV-2) through the concept of dielectrophoresis. The significance of recent research towards microfluidics-based diagnostic chips is apparent in health care, in our homes, and also very prominently in the fight against the COVID-19 pandemic: Coronavirus disease 2019 (COVID-19) is a newly emerging human infectious disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), early diagnosis and management are crucial for containing the outbreak. Here, we report a microfluidic device for separating a mixture of different viruses. Using appropriate microfluidic channels, flow velocity, microelectrode arrays, and voltage settings, particles can be trapped or moved between regions of high or low electric fields. The magnitude and direction of the dielectrophoretic force on the particle depend on the effective dielectric properties of fluid and particles so that a heterogeneous mixture of particles can be separated to produce a more homogeneous population. In this paper, the controlled separation of nanoparticles is demonstrated. With upper and lower electrode arrays, it is shown that different types of submicron latex beads can be spatially separated. The separation occurs because of differences in the magnitude and direction of the dielectrophoretic force and drag force on different populations of particles.
About the journal
Detection of foodborne pathogens using novel vertical capacitive sensors, Alexandria Engineering Journal, September 2021
Food poisoning, infection of open wounds, and sepsis are the serious clinical consequences that pathogens can cause. Rapid identification of these pathogens allows prompt monitoring of infections, which improves clinical outcomes. An integrated platform is proposed to manipulate and identify the microorganisms (e.g., foodborne pathogens) in this work. An electrokinetic-based Actuator and capacitive-based sensor are the two primary components of the proposed platform. Dielectrophoresis-based microelectrode is proposed to manipulate the microorganisms. A novel vertical array of capacitive sensors is suggested To identify the levitated microorganisms. The mass of microorganisms can be extracted according to the applied dielectrophoretic force respecting the gravitational force. The whole platform is simulated using 2D numerical simulation, COMSOL Multiphysics, to evaluate design efficiency. Furthermore, the proposed platform is developed and experimentally evaluated using the most common food bacterium type (Escherichia coli (E. coli)). The practical prototype is implemented using cheap technology (rigid and flexible printed circuit board technology). Experiments demonstrated that the proposed biochip could identify E. coli without the need of complex and expensive tools and with a simple manufacturing method.
About the journal
Electrical characteristics of modified truncated cone nanowire for efficient light trapping, Journal of Photonics and Nanostructures-Fundamentals and Applications 38, 2020
Charge Independent DC Model for Floating Gate MOSFET Used for Flash Memory and Electro-optic Switching Applications. Nonlinear Optics, Quantum Optics: Concepts in Modern Optics 50 (4), 2019
CMOS-compatible hybrid bi-metallic TE/TM-pass polarizers based on ITO and ZrN. journal of Applied optics 58 (24), 2019
Two-dimensional model for double-gate LDMOSFET devices. Journal of Computational Electronics, 1-11, 2019
A Novel Physical Modelling of FGMOSFET used in Circuit Simulators for Low-Power Systems and Optical Devices Applications. 2019 36th National Radio Science Conference (NRSC), 350-359, 2019
Fast and accurate PV model for SPICE simulation. Journal of Computational Electronics 18 (1), 260-270, 2019
An electro-kinetic platform based on printed circuit Board technology for identification and characterization of biological cells. Journal of Microelectronic Engineering, 2019
Unified Quantum and Reliability Model for Ultra-Thin Double-Gate MOSFETs. Journal of Silicon, 1-8, 2019
Magnetic Field Effect on Threshold Voltage for Ultrathin Silicon Gate-All-Around Nanowire Field-Effect-Transistors. Journal of Silicon, 2019
Charge Independent DC Model for Floating Gate MOSFET Used for Flash Memory and Electro-optic Switching Applications. Journal of Nonlinear Optics Quantum Optics, 1-16, 2019
Technology Scaling Roadmap for FinFET-Based FPGA Clusters Under Process Variations. Journal of Circuits, Systems and Computers 27 (04), 1850056, 2018
Thermal resistance model for standard CMOS thermoelectric generator. Journal of IEEE Access 6, 8123-8132, 2018
Detection of Hepatocellular carcinoma in clinical specimens using Dielectrophoresis based ElectroKinetic Platform, Sensors and Actuators A: Physical 316, 112402
Qiong Zhang, Minglin Zhao, Yang Li, Ang Bian, Ramy El-Bashar, Hamdy Abdelhamid, Salah S. A. Obayya, Mohamed Farhat O. Hameed, and Jun Dai, Polarization dependent exciton-plasmon coupling in PEA2PbI4/Al and its application to perovskite solar cell, 2024, Optics Express, Jun 2024, doi: https://doi.org/10.1364/OE.529605
This paper reports the strong coupling between Al nanostructure and two-dimensional (2D) layered perovskite PEA2PbI4 (PEPI) films. The high exciton binding energy of 118 meV and long carrier lifetime of 216 ps are characterized from the 2D PEA2PbI4 film, which indicates that the excitons in perovskite are robust and can couple to metal plasmons. The ordinary and extraordinary optical dispersions are revealed from the anisotropic 2D perovskite. The transmission spectra of PEA2PbI4/Al nanoparticle arrays are simulated under different polarization excitations, and the typical anti-crossing behaviors originating from exciton-plasmon strong coupling are demonstrated. We found that compared with transverse magnetic (TM) polarization, transverse electric (TE) polarization excitation is more conducive to the realization of exciton-plasmon coupling with a larger Rabi splitting. Furthermore, the PEA2PbI4/Al nanoparticle arrays are proposed, which present polarization-dependent local electrical field enhancement due to the exciton-local surface plasmon polariton coupling. Additionally, it is noticed that the proposed plasmonic structure increases the photo-generation rate inside the active material with improved current density. Therefore, the 2D proposed plasmonic design increases the power conversion efficiency (PCE) with an enhancement of 3.3% and 1.3% relative to the planar structures for TE and TM polarizations, respectively. This study provides a deeper understanding of polarized exciton-plasmon coupling properties, promoting the development of the field of plasmon and providing guidance for the design and preparation of efficient optoelectronic devices.
About the journal
Awad Khaled, Mohamed Farhat O. Hameed, Hamdy Abdelhamid, and Salah S. A. Obayya, Impact of aluminum concentration and grading configuration of AlxGa1-xAs nanostructures for solar absorber applications, 2024, Journal of Photonics for Energy, Apr 2024, doi: https://doi.org/10.1117/1.JPE.14.025501
In this work, AlxGa1−xAs nanostructures on a planar Si substrate are employed to achieve highly efficient light trapping with improved light absorption. In this context, cylindrical and conical nanostructures are shown to render themselves as better light absorption surfaces. The effects of the AlxGa1xAs nanostructures geometrical parameters and the Al concentration (x%) on the optical characteristics of the proposed solar absorber (SA) are studied. The optical performance of the suggested SA is numerically simulated using three-dimensional finite difference time domain method. The reported absorber has a superior performance in terms of absorption and short circuit current density, compared to its counterparts in the literature. The SA with cylindrical and truncated cone nanostructures can offer a high short circuit current density of 31.28 and 33.20mA/cm2, respectively.
About the journal
Khalil ElKhamisy, Hamdy Abdelhamid, El-Sayed M. El-Rabaie & Nariman Abdel-Salam, A Comprehensive Survey of Silicon Thin-film Solar Cell: Challenges and Novel Trends,2024, Plasmonics, Jul 2023, doi: https://doi.org/10.1007/s11468-023-01905-x
olar cells are commonly recognized as one of the most promising devices that can be utilized to produce energy from renewable sources. As a result of their low production costs, little material consumption, and projected increasing trajectory in terms of efficiency, thin-film solar cells have emerged as the technology of choice in the solar industry at present. This study aims to provide a comprehensive review of silicon thin-film solar cells, beginning with their inception and progressing up to the most cutting-edge module made in a laboratory setting. There is a review of the fantastic development of each technology, as well as its cell configuration, restrictions, equivalent circuit model, cell performance, and global market share. The dependability and availability of cell materials, in addition to the comparison of numerous characteristics, are both areas of research that are conducted concurrently for each of the distinct technologies. New advances in solar cells are also highlighted; these hold the potential to be significant variables and solutions in the process of the future's development. This abbreviated and brief version of the comprehensive analysis is provided to readers in the hope that it will aid them in evaluating potential research avenues about the proper applications and production of solar cells.
About the journal
Numerical Investigation of Si Nanowires Integrated Perovskite for Efficient Tandem Solar Cell, 2024, Information Technology (ACIT), Ajman
In this study, tandem solar cell (SC) based on MAPbI 3 -prevoskiteISi-nanowires (P|Si-NWs) structure is proposed and numerically investigated. The simulation results are calculated using the finite difference time domain (FDTD) method. The optical efficiency of the proposed tandem SC is increased to 40% compared to 37.5% for the counterpart planar tandem structure. This is owing to the high absorption coefficient and optimum MAPbI3 band gap of the perovskite SC. Further, the supported wave-guided modes and excited Bloch modes due to the periodic SiNWs help increase the optical absorption through the suggested SC. Further, the perovskite thickness can be controlled to efficiently balance the photo-generated current with the bottom Si layer with improved output efficiency. The J ph of the reported SC is equal to 13.1 mA/cm 2 with an enhancement of 37.5% relative to planar P|Si structure. Consequently, the proposed tandem PSiNWs structure offers better electrical performance with reduced Si-material and low manufacturing cost.
About the journal
The Effects of Temperature Variation with Surface Triangle Grating on Silicon Thin-Film Solar Cell Array Efficiency, 2021, Plasmonics, Oct 2023, doi: https://doi.org/10.1007/s11468-023-02093-4
This paper examines the effect of temperature variation on the surface triangular grating of the surface plasmon polariton (SPP) on the effectiveness of the entire array of silicon thin-film solar cells. Thin-film solar cells’ optical and electrical characteristics are examined using the electromagnetic and semiconductor models. The 3D Multiphysics simulator is used to present this study. The MATLAB/SIMULINK model based on mathematical formulas is developed to simulate the entire array of solar cells with thin films. This approach is suggested for quickly simulating the thin-film array. The presented model was applied on thin-film solar cells with and without SPP depending on the complete cell parameters from the COMSOL Multiphysics model. The triangle’s SPPs accomplish a 14.76% efficiency increase of 1.07% over a solar cell without SPPs.
About the journal
Impact of Bottom Dielectric Isolation of Si-Stacked Nanosheet Transistor on Stress and Self-Heating at 3-nm Node and Beyond, 2023, IEEE Transactions on Electron Devices, Oct 2023, doi: 10.1109/TED.2023.3318554
This study examines the effect of leakage current reduction techniques on the performance of the nanosheet FETs (NS-FETs) at 3 nm and beyond. We study the effects of the punchthrough stopper (PTS) and bottom dielectric isolation (BDI) schemes on stress and self-heating. We have developed a new simulation flow based on quantum correction of Monte Carlo (MC) simulation and calibration of drift diffusion model. We calibrate the simulation results with the latest available published experimental data. BDI was found to lower the average channel stress by 85% and reduced drive current compared with PTS with ideal source/drain (S/D) stressors. The impact of nonideal, defective S/D stressors on the development of channel stress of PTS is also covered in this article. We also found that the BDI structure raises the lattice temperature dramatically compared with the PTS structure at the same dc bias current level. The performance of the BDI structure is improved by introducing metal S/D to increase the contact area between M0 and S/D epi, leading to a significant improvement in lattice temperature, drive current, and RC delay up to 30%.
About the journal
Conference Presentation
- Micro-electrodes Based on CMOS Technology for Characterization of Biological Cells. IEEE, ISSPIT2019 proceeding, Displayed 2020
- Planar Micro-electrodes Versus Cone Plate for Biological Cell Trapping and Characterization. IEEE, ISSPIT2019 proceeding, 2020
- 3D Analytical Modeling of Potential, Drain Current, and Threshold Characteristics for LongChannel Square. Springer, RAEMP 2019 proceeding, 2020
- Dielectrophoretic based Microfluidic for nanoparticles “viruses” separation, Sep. 2021
- 2023 IEEE Conference on Power Electronics and Renewable Energy (CPERE)
- Japan-Egypt International Conference on Electronics, Communications and Computers (JEC-ECC)
- 2023 24th International Arab Conference on Information Technology (ACIT)
Micro-electrodes Based on CMOS Technology for Characterization of Biological Cells. IEEE, ISSPIT2019 proceeding, Displayed 2020
Planar Micro-electrodes Versus Cone Plate for Biological Cell Trapping and Characterization. IEEE, ISSPIT2019 proceeding, 2020
3D Analytical Modeling of Potential, Drain Current, and Threshold Characteristics for LongChannel Square. Springer, RAEMP 2019 proceeding, 2020
Dielectrophoretic based Microfluidic for nanoparticles “viruses” separation, Sep. 2021
2023 IEEE Conference on Power Electronics and Renewable Energy (CPERE)
Japan-Egypt International Conference on Electronics, Communications and Computers (JEC-ECC)
2023 24th International Arab Conference on Information Technology (ACIT)
Memberships, Awards and Honors
- IEEE senior member
- American nanosociety
- Nano-bank nominated member
- Deepen local electronics manufacturing in Egypt
- IEEE Electron devices Society (EDS), Technical member
- IEEE Solid-State Circuits Society
- IEEE Electron Devices Society