Your search keyword '"Nano-electronics"' showing total 130 results

1. Design of Testable Adder in Quantum‐dot Cellular Automata with Fault Secure Logic

Author

Goswami, Mrinal, Sen, Bibhash, Mukherjee, Rijoy, and Sikdar, Biplab K

Published

2017

2. A fast and energy-efficient hybrid 4–2 compressor for multiplication in nanotechnology.

Author

Maleknejad, Mojtaba, Sharifi, Fazel, and Sharifi, Hojjat

Subjects

*COMPRESSORS, *NANOTECHNOLOGY, *FIELD-effect transistors, *CARBON nanotubes, *MULTIPLICATION, *EMBEDDING theorems

Abstract

In this paper, a novel high-speed and energy-efficient 4–2 compressor cell is proposed using carbon nanotube field-effect transistors. The proposed compressor is realized efficiently based on NAND–NOR gates and multiplexers. To estimate the performance of the presented design, simulations are carried out using Synopsis HSPICE under different conditions. The results demonstrate the improvement of the proposed design compared to the best reference designs in terms of delay and energy consumption, by 20–26%, respectively. Also, the susceptibility of the proposed design against the process, voltage, temperature (PVT), and noise variations is examined. It is robust against PVT variations and high amplitude of noises compared with its counterpart. Further, embedding the proposed compressor in an 8 × 8-bit binary multiplier demonstrates that it has better speed and energy consumption with regard to its counterparts. [ABSTRACT FROM AUTHOR]

Published

2024

3. Superconductivity in AuGeNi Ohmic contacts to a GaAs-based high mobility two-dimensional electron gas

Author

Beauchamp, Christopher Brian

Subjects

AuGeNi, ohmic contact, superconducting, 2DEG, Transistor, low temperature, nano-electronics, Electronic, GaAs, AlGaAs, semiconductors, heterostructures

Abstract

The initial aim of this thesis was to cool two-dimensional electrons down to temperatures below 10 mK. In order to cool a high mobility two-dimensional electron gas (2DEG) at a GaAs–AlGaAs heterojunction to milliKelvin temperatures, different processing techniques and recipes for low resistance Ohmic contacts based on alloys of Au, Ni, and Ge are fabricated on these semiconductor devices. Scanning electron microscope (SEM) and Energy Dispersive X-ray (EDX) images establish that the Ohmic contacts have the same inhomogeneous microstructure observed in the literature. The unexpected result from electrical measurements of the contact resistance RC, the four-terminal resistance along the top of a single contact Rtop, and the vertical resistance RV, is that there is superconductivity in the Ohmic contact below 0.9 K. Measurements for different Ohmic contacts investigated, show some have multiple superconducting transitions, whereas others have a single transition; there is no correlation discovered between the annealing recipe and the number of transitions. I-V measurements show the superconductor is turned completely normal with a DC current of 2.1 mA and in a magnetic field, the superconductor is turned completely normal with a magnetic field of 0.15 T. This thesis speculates on the superconductor, suggesting that the Ohmic contact is a granular superconductor comprised of multiple alloys of different phases, and reviews the possible compounds that may be superconducting below 0.9 K. There is a discussion on how this superconductivity affects electrical transport measurements in similar systems such as quantum conductance, four-terminal Hall measurements and electron cooling experiments in 2DEGs below 0.1 K.

Published

2021

4. Intelligent Materials and Nanomaterials Improving Physical Properties and Control Oriented on Electronic Implementations.

Author

Massaro, Alessandro

Subjects

ELECTRONIC control, ARTIFICIAL intelligence, NANOSTRUCTURED materials, TECHNOLOGY assessment, ELECTRONIC systems

Abstract

The review highlights possible research topics matching the experimental physics of matter with advances in electronics to improve the intelligent design and control of innovative smart materials. Specifically, following the European research guidelines of Key Enabling Technologies (KETs), I propose different topics suitable for project proposals and research, including advances in nanomaterials, nanocomposite materials, nanotechnology, and artificial intelligence (AI), with a focus on electronics implementation. The paper provides a new research framework addressing the study of AI driving electronic systems and design procedures to determine the physical properties of versatile materials and to control dynamically the material's "self-reaction" when applying external stimuli. The proposed research framework allows one to ideate new circuital solutions to be integrated in intelligent embedded systems formed of materials, algorithms and circuits. The challenge of the review is to bring together different research concepts and topics regarding innovative materials to provide a research direction for possible AI applications. The discussed research topics are classified as Technology Readiness Levels (TRL) 1 and 2. [ABSTRACT FROM AUTHOR]

Published

2023

5. Design and Analysis of Area and Energy-Efficient Quantum-Dot Half Adder Using Intercellular Interaction Technique

Author

Tripathi, Neeraj, Fazili, Mohammad Mudakir, Singh, Abhishek, Shivam, Pangotra, Suksham, Xhafa, Fatos, Series Editor, Verma, Pankaj, editor, Charan, Chhagan, editor, Fernando, Xavier, editor, and Ganesan, Subramaniam, editor

Published

2022

6. Nanotechnology for Food and Packing Application

Author

Barua, Pranta, Khan, Adnan Hossain, Hossain, Nazia, Thakur, Vijay Kumar, Series Editor, Mubarak, Nabisab Mujawar, editor, Gopi, Sreerag, editor, and Balakrishnan, Preetha, editor

Published

2022

7. Island Engineering of Single-Electron Transistor for Room Temperature Operation

Author

Shah, Raj, Parekh, Rutu, Dhavse, Rasika, Angrisani, Leopoldo, Series Editor, Arteaga, Marco, Series Editor, Panigrahi, Bijaya Ketan, Series Editor, Chakraborty, Samarjit, Series Editor, Chen, Jiming, Series Editor, Chen, Shanben, Series Editor, Chen, Tan Kay, Series Editor, Dillmann, Rüdiger, Series Editor, Duan, Haibin, Series Editor, Ferrari, Gianluigi, Series Editor, Ferre, Manuel, Series Editor, Hirche, Sandra, Series Editor, Jabbari, Faryar, Series Editor, Jia, Limin, Series Editor, Kacprzyk, Janusz, Series Editor, Khamis, Alaa, Series Editor, Kroeger, Torsten, Series Editor, Liang, Qilian, Series Editor, Martín, Ferran, Series Editor, Ming, Tan Cher, Series Editor, Minker, Wolfgang, Series Editor, Misra, Pradeep, Series Editor, Möller, Sebastian, Series Editor, Mukhopadhyay, Subhas, Series Editor, Ning, Cun-Zheng, Series Editor, Nishida, Toyoaki, Series Editor, Pascucci, Federica, Series Editor, Qin, Yong, Series Editor, Seng, Gan Woon, Series Editor, Speidel, Joachim, Series Editor, Veiga, Germano, Series Editor, Wu, Haitao, Series Editor, Zhang, Junjie James, Series Editor, Patel, Zuber, editor, Gupta, Shilpi, editor, and Kumar Y. B., Nithin, editor

Published

2021

8. A Comparative Study on Electronic Transport Behavior of Silicene and B40-Nano Onions.

Author

Kaur, Harleen, Kaur, Jupinder, and Kumar, Ravinder

Abstract

Density Functional Theory is utilized to scrutinize the electronic state of silicene and boron nano-onion which is a round compact mass formed by placing an N20, C20, and B20 fullerene within its parent atom fullerene B40. The NEGF is used to investigate the quantum transport at both equilibrium and non-equilibrium. Firstly the I-V curve for both silicene and boron-based devices is studied. From the results, it is concluded that boron-based devices are better than silicene. Therefore to get deeper insights into why boron-based devices are better transport properties of boron-based devices are suited. Later on, the transport mechanism is analyzed by computing the DOS, transmission and molecular spectra, HLG, I-V curve, electron densities, and differential conductance. When the Boron nano-onion is placed between the pair of Au electrodes. The calculated results are evaluated and a comparative study is done. From the results, it is deduced that the N20 variant nano-onion has reduced the HOMO-LUMO gap (HLG) and highest value of current in comparison to other devices. Thus by infusing a smaller fullerene of N20 inside the hollow cage of B40 fullerene the amplification of current and conductance can be observed in Boron-nano-onion in comparison to other devices. [ABSTRACT FROM AUTHOR]

Published

2022

9. Positive impact of surface defects on Maxwell's displacement current-driven nano-LEDs: The application of TENG technology.

Author

Li, Wenhao, Zhang, Shuqian, Wang, Kun, Qiu, Jiawen, Li, Junlong, Zhu, Jiaye, Suk, Chan Hee, Wu, Chaoxing, Zhou, Xiongtu, Zhang, Yongai, Guo, Tailiang, and Kim, Tae Whan

Abstract

As the core component of a nanopixel light-emitting display, the GaN-based nanoscale light-emitting diode (nLED) faces the problem of low electroluminescence efficiency resulting from the introduction of surface defects when its lateral size is reduced to the nanometer scale. Thus, reducing the surface defect density is an important direction in nLED-related research. This study, with the triboelectric nanogenerator-driven LED as its inspiration, reveals that surface defects have a positive impact on the performance of nLEDs driven by Maxwell's displacement current, and we call the related driving mode the noncarrier injection mode. Through finite element simulations, we studied the dynamic variations of the carrier concentration, the energy band, and the light emission rate to analyze the impact of the behavior of surface defect excitation on device performance. We found that surface defects can act as electron pumps under the combined effect of the reverse electric field and the built-in electric field and can generate carriers through surface defect excitation to increase the intensity of noncarrier injection luminescence, which is completely different from the traditional understanding of surface defects. In addition, we propose a tapered structure to further increase the light emission rate by regulating the behaviors of radiation recombination and surface defect excitation. The results of this work open a new perspective on the impacts of surface defects on nLEDs and provide significant information for additional applications of Maxwell's displacement current. [Display omitted] • Surface defects have a positive impact on the performance of MDC-nLEDs. • Surface defect excitation leads to carrier redistribution in MDC-nLEDs. • Surface defects acting as carrier pumps provide more carriers for light emission. • A tapered structure can improve output by regulating surface DE. [ABSTRACT FROM AUTHOR]

Published

2024

10. An Efficient Layout of Single-Layer Full Adder Using QCA

Author

Patidar, Nilesh, Gupta, Namit, Kacprzyk, Janusz, Series Editor, Pal, Nikhil R., Advisory Editor, Bello Perez, Rafael, Advisory Editor, Corchado, Emilio S., Advisory Editor, Hagras, Hani, Advisory Editor, Kóczy, László T., Advisory Editor, Kreinovich, Vladik, Advisory Editor, Lin, Chin-Teng, Advisory Editor, Lu, Jie, Advisory Editor, Melin, Patricia, Advisory Editor, Nedjah, Nadia, Advisory Editor, Nguyen, Ngoc Thanh, Advisory Editor, Wang, Jun, Advisory Editor, Pant, Millie, editor, Kumar Sharma, Tarun, editor, Arya, Rajeev, editor, Sahana, B.C., editor, and Zolfagharinia, Hossein, editor

Published

2020

11. Energy Efficient Tri-State CNFET Ternary Logic Gates.

Author

Tabrizchi, Sepehr, Sharifi, Fazel, and Badawy, Abdel-Hameed

Subjects

*LOGIC circuit design, *LOGIC circuits, *FIELD-effect transistors, *MANY-valued logic, *TECHNOLOGICAL innovations, *THRESHOLD voltage, *METAL oxide semiconductor field-effect transistors, *CARBON nanotubes

Abstract

Power consumption and especially leakage power are the main concerns of nano MOSFET technology. On the other hand, binary circuits face a huge number of interconnection wires, which results in power dissipation and area. Researchers introduced emerging nanodevices and multiple-valued logic (MVL) as two feasible solutions to overcome the challenges mentioned above. Carbon nanotube field-effect transistor (CNFET) is one of the emerging technologies that has some unique properties and advantages over MOSFET, such as adjusting the carbon nanotube (CNT) diameters to have the desired threshold voltage and have the same mobility as P-FET and N-FET transistors. In this paper, we present a novel method for designing ternary logic circuits based on CNFETs. Each of our designed logic circuits implements a logic function and its complementary via a control signal. Also, these circuits have a high impedance state, which saves power while the circuits are not in use. Moreover, we designed a two-digit adder/ subtractor and a power-efficient ternary logic arithmetic logic unit (ALU) based on the proposed gates. The proposed ternary circuits are simulated using HSPICE via standard 32 nm CNFET technology. The simulation results indicate the designs' correct operation under different process, voltage, and temperature (PVT) variations. Also, simulation results show that the two-digit adder/ subtractor using our proposed gates has 12X and 5X lower power consumption and power-delay product (PDP), respectively, compared to previous designs. [ABSTRACT FROM AUTHOR]

Published

2022

12. Terahertz Applications of Non-Simply-Connected and Helical Nanostructures

Author

Collier, Thomas P., Saroka, Vasil A., Downing, Charles A., Alexeev, Arseny M., Hartmann, Richard R., Portnoi, Mikhail E., Maffucci, Antonio, editor, and Maksimenko, Sergey A., editor

Published

2019

13. Reversible Palm Vein Authenticator Design With Quantum Dot Cellular Automata for Information Security in Nanocommunication Network

Author

Bikash Debnath, Jadav Chandra Das, Debashis De, Ferial Ghaemi, Ali Ahmadian, and Norazak Senu

Subjects

Nano-electronics, QCA, majority logic, security, Feynman gate, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Palm vein pattern recognition is one of the most promising and rapidly developing fields of study in biometrics, which makes it an important solution for identity security in biometrics-based user identification systems. Quantum-dot Cellular Automata (QCA) is a developing field of nanotechnology which facilitates the creation of nano-scale logical circuits. Irreversible technology has faced some difficulties, such as higher heat energy dissipation. Reversible logic is therefore essential where heat dissipation is almost insignificant. This article proposes QCA design of a reversible circuit for palm vein authentication utilizing the Feynman gate. Fully reversible Feynman gate is designed. Using this newly designed Feynman gate the palm vein authenticator circuit is designed. The theoretical values and the results of the simulation correspond to the reliability of the planned circuit. Circuit complexity and circuit cost are explored. Validation of authenticated users by the proposed authenticator explores its design accuracy as per theoretical values. Energy dissipation of the proposed designs shows that it remains within Lauderer's limit (0.06meV). This proves that the circuits designed are fully reversible in nature and dissipates very less amount of energy. Comparison with recent QCA state of the art architectures explores its characteristics.

Published

2020

14. A complete set of logic gates with an identical single-stage structure based on periodic nature of single-electron devices.

Author

Sharifi, Mohammad Javad and Ahmadian, Mehdi

Abstract

In this paper, a new method for implementing all two-input logic gates on an identical single-stage structure is proposed. We have used unique characteristics of single-electron transistors, which have periodic output–input relation, to design the gates and implement all two-input logic gates (symmetric/non-symmetric, monotonic/non-monotonic) by a single-stage design including only one single-electron transistor. In conventional monotonic devices, such as BJTs and MOSFETs, implementing non-monotonic logic gates such as XOR and XNOR is impossible with a single-stage circuit and a multistage design is required which leads to more complexity, more chip area and higher power consumption. We present the proposed methodology at first, and then, the details of the designs are investigated. The results are obtained analytically using a new approach named two-potential and then confirmed by numerical methods. Furthermore, important characteristics of the proposed gates such as maximum operating temperature, speed of the gates and frequency limitations, power consumption (static and dynamic) and scaling to other technologies have been investigated. Finally, a general idea has been presented about the application of the introduced approach and gate structures in the field of logic circuit and system designing. [ABSTRACT FROM AUTHOR]

Published

2021

15. Carbon Nanotubes and Graphene Nanoribbons for Terahertz Applications : CNTs and GNRs for THz Applications

Author

Maffucci, Antonio, Maksimenko, Sergey A., Portnoi, Mikhail E., Maffucci, Antonio, editor, and Maksimenko, Sergey A., editor

Published

2016

16. Towards Deep Integration of Electronics and Photonics.

Author

Pshenichnyuk, Ivan A., Kosolobov, Sergey S., and Drachev, Vladimir P.

Subjects

QUANTUM electronics, MOLECULAR electronics, ELECTRONIC equipment, PHOTONICS, QUANTUM computing, SURFACE plasmons, POWER electronics, ELECTRONICS

Abstract

A combination of computational power provided by modern MOSFET-based devices with light assisted wideband communication at the nanoscale can bring electronic technologies to the next level. Obvious obstacles include a size mismatch between electronic and photonic components as well as a weak light–matter interaction typical for existing devices. Polariton modes can be used to overcome these difficulties at the fundamental level. Here, we review applications of such modes, related to the design and fabrication of electro–optical circuits. The emphasis is made on surface plasmon-polaritons which have already demonstrated their value in many fields of technology. Other possible quasiparticles as well as their hybridization with plasmons are discussed. A quasiparticle-based paradigm in electronics, developed at the microscopic level, can be used in future molecular electronics and quantum computing. [ABSTRACT FROM AUTHOR]

Published

2019

17. Computational Electronics and 21st Century Education

Author

Vasileska, Dragica, Davcev, Danco, editor, and Gómez, Jorge Marx, editor

Published

2010

18. Brief review of monolayer molybdenum disulfide application in gas sensor.

Author

Akbari, Elnaz, Jahanbin, Kia, Afroozeh, Abdolkarim, Yupapin, P., and Buntat, Zolkafle

Subjects

*MOLYBDENUM, *DISULFIDES, *BAND gaps, *PHOTOCATALYSTS, *PHOTOCATALYSIS

Abstract

Abstract With the continuous increase in technological applications, the progress of new semiconductor materials continues to be a significant research field. In recent years, new materials such as molybdenum disulfide, has been researched as a substitute for graphene and silicon. The monolayer molybdenum disulfide (MoS 2), one of the promising 2D materials with a direct bandgap has high potential for applications in nano electronic devices, energy storage, photocatalysts, and chemical sensors. As such, this paper examines the present gas-sensing applications of MoS 2 and have been compared it with other nanomaterials. [ABSTRACT FROM AUTHOR]

Published

2018

19. A low-power high-speed hybrid multi-threshold full adder design in CNFET technology.

Author

Maleknejad, Mojtaba, Mohammadi, Somayyeh, Mirhosseini, Seyed Mostafa, Navi, Keivan, Naji, Hamid Reza, and Hosseinzadeh, Mehdi

Abstract

In this paper, a low-power high-speed hybrid full adder cell is proposed, which is implemented based on two-input multi-threshold (Vt) XNOR circuit and transmission gate multiplexers. In order to implement this circuit, carbon nanotube field-effect transistors are utilized. For evaluating the proposed design, comprehensive simulations are performed with regard to the most important aspects of digital circuits: power, delay and power-delay product. The results are presented and confirm the superiority of the proposed cell with the previously reported one in different voltage levels, load conditions, temperatures and robustness in large structures and against process variations. [ABSTRACT FROM AUTHOR]

Published

2018

20. On Wires Holding a Handful of Electrons

Author

Beiu, Valeriu, Ibrahim, Walid, Makki, Rafic Z., Akan, Ozgur, Series editor, Bellavista, Paolo, Series editor, Cao, Jiannong, Series editor, Dressler, Falko, Series editor, Ferrari, Domenico, Series editor, Gerla, Mario, Series editor, Kobayashi, Hisashi, Series editor, Palazzo, Sergio, Series editor, Sahni, Sartaj, Series editor, Shen, Xuemin (Sherman), Series editor, Stan, Mircea, Series editor, Xiaohua, Jia, Series editor, Zomaya, Albert, Series editor, Coulson, Geoffrey, Series editor, Schmid, Alexandre, editor, Goel, Sanjay, editor, Wang, Wei, editor, Beiu, Valeriu, editor, and Carrara, Sandro, editor

Published

2009

21. Simulation of Biomolecular Adsorption on a Microcantilever Biosensor Regarding Surface Charge Distribution

Author

Mollaei, Fouad, Naghash, Abolghasem, and Aliparast, Peiman

Published

2021

22. Towards Deep Integration of Electronics and Photonics

Author

Ivan A. Pshenichnyuk, Sergey S. Kosolobov, and Vladimir P. Drachev

Subjects

plasmon, light-matter interaction, photonics, nano-electronics, quasiparticle, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

A combination of computational power provided by modern MOSFET-based devices with light assisted wideband communication at the nanoscale can bring electronic technologies to the next level. Obvious obstacles include a size mismatch between electronic and photonic components as well as a weak light−matter interaction typical for existing devices. Polariton modes can be used to overcome these difficulties at the fundamental level. Here, we review applications of such modes, related to the design and fabrication of electro−optical circuits. The emphasis is made on surface plasmon-polaritons which have already demonstrated their value in many fields of technology. Other possible quasiparticles as well as their hybridization with plasmons are discussed. A quasiparticle-based paradigm in electronics, developed at the microscopic level, can be used in future molecular electronics and quantum computing.

Published

2019

23. Mounting at the Nanoscale by Addressing Nanostructured Biological Templates — Another Packaging Strategy for Nanoscaled Electronics?

Author

Fiedler, S., Zwanzig, M., Fischer, T., Hampp, N., Knobloch, Harald, editor, and Kaminorz, Yvette, editor

Published

2004

24. Optimization of parameters of adders and barrel shifter based on emerging QCA technology

Author

Pathak, Nirupma, Misra, Neeraj Kumar, Bhoi, Bandan Kumar, Kumar, Santosh, Pathak, Nirupma, Misra, Neeraj Kumar, Bhoi, Bandan Kumar, and Kumar, Santosh

Abstract

Compared to metal-oxide-semiconductor field-effect transistors (MOS), the quantum-dot cellular automata (QCA) offer great advantages. This paper deals with the QCA implementation of digital circuits such as full adder, multiplexer, carry-save adder, carry-select adder, carry-skip adder, and barrel shifter for robust architecture in the nanoelectronics domain. The goal is to provide a framework for optimizing QCA designs utilizing coplanar cells that is also flexible enough to be used in complicated system design. As a result of this synthesis, the new design is appropriate for the creation of nanoelectronic circuits. The QCADesigner tool was used to verify the digital circuits in the synthesized designs presented in this article. The QCA simulation environment is used to verify designs, extract parameters, and perform digital computing. The primary goal of this study is to develop a robust adder design in terms of bounded box area and other cost primitives. The coplanar method is used to construct the QCA layouts of various adders, which is more efficient and compact. The comparison results have shown that the adoption of novel digital designs offers better results and provides a more robust architecture as compared to the literature works.

Published

2022

25. Progress in electronics and photonics with nanomaterials.

Author

Mishra, Yogendra Kumar, Murugan, N. Arul, Kotakoski, Jani, and Adam, Jost

Subjects

*NANOSTRUCTURED materials, *NANOPHOTONICS, *NANOELECTRONICS, *NANOTECHNOLOGY

Abstract

Nanomaterials have been at the center of attraction for almost five decades as their contributions to different disciplines such as electronics, photonics and medicine are enormous. Various kinds of nanomaterials have been developed and are currently utilized in innumerable applications. Nevertheless, their simple realization and easy and efficient upscaling are topics under intense investigation. Innovative strategies have been adopted for nanomaterial synthesis and their usability. Here, we provide a brief overview on nanomaterials ranging from basic understanding of their structure-property relationship to advanced applications. This editorial covers various aspects about nanomaterials, which will be useful/attractive for beginners in the field of nanotechnology as well as for experts and for industrialists looking forward to exploit them for real world applications. [ABSTRACT FROM AUTHOR]

Published

2017

26. Active thermal-electronic devices based on heat-sensitive metal-insulator-transition resistor elements.

Author

Mizsei, János, Lappalainen, Jyrki, and Pohl, Laszló

Subjects

*THERMOELECTRIC apparatus & appliances, *ELECTRIC resistors, *METAL-insulator transitions, *TEMPERATURE sensors, *RESISTANCE heating, *THYRISTORS

Abstract

New active thermal-electronic device family is proposed. These devices operate by means of thermal (or hot electron) coupling between adjacent domains containing heating (input) and thermally sensitive (output) elements. The theoretical background, basic equations and comparison with the conventional electron devices are the main subject of this work. According to the theoretical assumptions the realization of the thermal-electronic device needs a very sensitive output element i.e. temperature sensor. Among others, the metal-insulator transition (MIT) based resistor fulfills this requirement. The MIT resistor itself has got thyristor-like I–V characteristics due to solely the high electric field, or Joule heating induced extremely strong step-like resistance drop at a given temperature. Using thermally coupled MIT and/or other resistors it is possible to build a special device, namely phonsistor (=phonon transistor). This device consists of only bulk type intrinsic domains, containing significantly fewer regions, junctions, depleted layers, surfaces and interfaces compared to conventional electron devices. Thus, these devices can be integrated together with each other and with conventional CMOS, forming, for example, thermal-electronic logic circuit (TELC) for the More-Than-Moore concept devices. [ABSTRACT FROM AUTHOR]

Published

2017

27. High-throughput ion beam analysis at imec.

Author

Meersschaut, J. and Vandervorst, W.

Subjects

*ION beams, *BACKSCATTERING, *ELASTIC recoil detection analysis, *DATA acquisition systems, *NANOELECTRONICS

Abstract

We describe the ion beam analysis activities at imec. Rutherford backscattering spectrometry and time of flight-energy (TOF-E) elastic recoil detection analysis are pursued to support the nano-electronics research and development. We outline the experimental set-up and we introduce a new data acquisition software platform. Finally, we illustrate the use of Rutherford backscattering spectrometry to map the thickness of a metallic thin film on a 300 mm Si wafer. [ABSTRACT FROM AUTHOR]

Published

2017

28. An efficient three-level nano-design for reversible gate using quantum dot-cellular automata with cost analysis.

Author

Li, Zongwei, Zhang, Shubo, and Omar Mohammed, Bayan

Subjects

*COST analysis, *QUANTUM gates, *QUANTUM dots, *CELLULAR automata

Abstract

• An improved Feynman gate based on quantum-dot CA architecture is presented. • A comparison of the suggested gate to the quantum-dot CA-based designs is examined in terms of quantum cost. • The suggested quantum-dot CA-based Feynman gate is evaluated and validated using the truth table, assessing the circuit's functional efficacy. • A new reversible gate based on Feynman logic with a multi-layer construction is proposed that uses less space and a number of cells. Quantum-dot Cellular Automata (CA) is a suitable nanotechnology for replacing CMOS circuits. The majority, inverter, and reversible structures, are the primary building blocks in quantum-dot CA circuits. Since the reversible gates have recently attained great attention, this paper proposes a new design of a reversible building block based on the Feynman gate. The proposed quantum-dot CA-based Feynman gate is denser and has low delay than the existing circuits. This paper also tests the possible implementation of the proposed design in quantum-dot CA. The QCADesigner is employed to test the functionality of the proposed structure. The proposed efficient quantum-dot CA-based Feynman gate has only 36 cells in three-layer. It consumes 0.03 µ m2, which is the smallest among all previous designs. A quantum-cost comparison of the proposed reversible Feynman gate with conventional reversible gates demonstrates the cost-effectiveness of quantum-dot CA. The simulation result matched the truth table of the Feynman gate, indicating that the suggested quantum-dot CA architecture is functional. The proposed architecture can also be used for n -bit code converters as well. [ABSTRACT FROM AUTHOR]

Published

2023

29. Multi-Beam Interference Advances and Applications: Nano-Electronics, Photonic Crystals, Metamaterials, Subwavelength Structures, Optical Trapping, and Biomedical Structures

Author

Thomas K. Gaylord and Guy M. Burrow

Subjects

multi-beam interference, interference lithography, nano-electronics, photonic crystals, metamaterials, subwavelength structures, optical trapping, biomedical structures, Mechanical engineering and machinery, TJ1-1570

Abstract

Research in recent years has greatly advanced the understanding and capabilities of multi-beam interference (MBI). With this technology it is now possible to generate a wide range of one-, two-, and three-dimensional periodic optical-intensity distributions at the micro- and nano-scale over a large length/area/volume. These patterns may be used directly or recorded in photo-sensitive materials using multi-beam interference lithography (MBIL) to accomplish subwavelength patterning. Advances in MBI and MBIL and a very wide range of applications areas including nano-electronics, photonic crystals, metamaterials, subwavelength structures, optical trapping, and biomedical structures are reviewed and put into a unified perspective.

Published

2011

30. 'CAM-Brain∝ ATR's billion neuron artificial brain project a three year progress report

Author

de Garis, Hugo, Carbonell, Jaime G., editor, Siekmann, Jörg, editor, Goos, G., editor, Hartmanis, J., editor, van Leeuwen, J., editor, Furuhashi, Takeshi, editor, and Uchikawa, Yoshiki, editor

Published

1996

31. CAM-Brain : The Evolutionary Engineering of a Billion Neuron Artificial Brain by 2001 which Grows/Evolves at Electronic Speeds inside a Cellular Automata Machine (CAM)

Author

de Garis, Hugo, Pearson, David W., Steele, Nigel C., and Albrecht, Rudolf F.

Published

1995

32. Optimization of parameters of adders and barrel shifter based on emerging QCA technology

Author

Nirupma Pathak, Neeraj Kumar Misra, Bandan Kumar Bhoi, and Santosh Kumar

Subjects

Nano-electronics, Barrel-shifter, Hardware_INTEGRATEDCIRCUITS, Computational electronics, Hardware_PERFORMANCEANDRELIABILITY, Complexity, Electrical and Electronic Engineering, Hardware_ARITHMETICANDLOGICSTRUCTURES, Adders, Hardware_LOGICDESIGN

Abstract

Compared to metal-oxide-semiconductor field-effect transistors (MOS), the quantum-dot cellular automata (QCA) offer great advantages. This paper deals with the QCA implementation of digital circuits such as full adder, multiplexer, carry-save adder, carry-select adder, carry-skip adder, and barrel shifter for robust architecture in the nanoelectronics domain. The goal is to provide a framework for optimizing QCA designs utilizing coplanar cells that is also flexible enough to be used in complicated system design. As a result of this synthesis, the new design is appropriate for the creation of nanoelectronic circuits. The QCADesigner tool was used to verify the digital circuits in the synthesized designs presented in this article. The QCA simulation environment is used to verify designs, extract parameters, and perform digital computing. The primary goal of this study is to develop a robust adder design in terms of bounded box area and other cost primitives. The coplanar method is used to construct the QCA layouts of various adders, which is more efficient and compact. The comparison results have shown that the adoption of novel digital designs offers better results and provides a more robust architecture as compared to the literature works.

Published

2022

33. Thermal-electronic Integrated Circuits Using Thermally Sensitive VO2 MIT Material.

Author

Mizsei, János and Lappalainen, J.

Subjects

INTEGRATED circuits, THERMOELECTRIC apparatus & appliances, METAL-insulator transitions, VANADIUM dioxide, ENERGY dissipation

Abstract

Traditional integrated electronics is based only on electric signal processing, thermal phenomena are considered as a parasitic (side) effect. However, the thermal state of a device may represent information too. Thermal-electronic devices and integrated circuits can be created using power dissipating and thermally sensitive elements, such as pn junctions, thermoelectric semiconductor devices, metal-insulator transition (MIT) or semiconductor-metal transition (SMT) resistors. We propose a new active thermal-electronic device, specifically, a phonsistor = phonon transistor, patent pending [1] . The basis of the way this device operates is the thermal or hot electron coupling between adjacent domains containing metal-insulator transition (MIT) material. [ABSTRACT FROM AUTHOR]

Published

2016

34. A First Principle Study of Phosphorous Doped Graphyne.

Author

Deb, Jyotirmoy, Paul, Debolina, and Sarkar, Utpal

Subjects

DENSITY functional theory, DOPING agents (Chemistry), COHESIVE strength (Mechanics), NANOELECTROMECHANICAL systems, ELECTRODES

Abstract

Based on density functional theory (DFT) calculation with generalized gradient approximation (GGA), we have investigated the effect of doping by phosphorous (P) atom at ring and chain position on the electronic properties of graphyne. The stability of the P-doped graphyne system has been determined on the basis of cohesive energy. Doping at chain position shows the possibility of modulating its band gap which might be useful for nano-electronics application. The surprising change from semiconducting to metallic behavior when P atom is placed at ring position of graphyne might be utilized in electronics for the fabrication of metal-semiconductor interfaces and also as an electrode in batteries. [ABSTRACT FROM AUTHOR]

Published

2017

35. Waste Heat Driven Membrane Distillation for Industrial Wastewater Treatment

Author

Noor, Imtisal-e and Noor, Imtisal-e

Abstract

The European Union has placed a high priority on reaching the goals described in the 2030 Agenda for Sustainable Development. This aim has provided added momentum to member-state environmental regulatory authorities to further tighten the discharge limits of industrial wastewater. These measures strongly influence existing industrial practices as many traditional wastewater treatment methods cannot achieve these strict release limits. Moreover, industrial sectors are encouraged to employ a zero liquid discharge strategy for advanced wastewater management, particularly for process water reuse. Emphasis is thus now placed on improved water treatment systems to recover, reuse and release water in a manner that protects natural resources, guarantees stringent regulatory constraints and ensures financial viability. In this context membrane distillation (MD) is a promising industrial wastewater treatment technology capable of meeting these requirements while utilizing low-grade heat sources. This thesis focuses on experimental investigations and techno-economic analysis of waste heat driven MD systems for water purification in two water-intensive industries: nano-electronics facilities and cogeneration plants. Samples collected at relevant facilities were tested in an air gap MD bench unit and a semi-commercial pilot plant, with a focus on separation efficiency and potential for achieving high recovery ratios. For the techno-economic analysis of the industrial scale system, the performance of the chosen semi-commercial unit was considered to evaluate the full-scale system operation in terms of thermal energy demand and expected water purification cost. Various thermal integration approaches were investigated while considering locally available heat sources to realize the energy requirements of the specific MD system. The selected case studies include: removal of tetramethylammonium hydroxide (TMAH) from photolithography process wastewater in nano-electronics industries; t, Den Europeiska Unionen har lagt högt prioritet på uppfyllelsen av de målen som finns i 2030 Agenda för Hållbar Utveckling. Denna ambition har gett ytterligare fart till medlemsländernas miljöförvaltningar för att strama åt utsläppsnivåer av industriella avloppsvatten. Dessa åtgärder har stor betydelse för existerande förhållningssätt i industrin eftersom många traditionella metoder för rening av avloppsvatten når inte de åtstramade utsläppsnivåerna. Dessutom finns det en uppmaning hos industrin att implementera strategier för noll utsläpp, framför allt för återanvändning av processvatten. Betoningen ligger på förbättrad vattenreningsteknik för återhämtning, återanvändning och utsläpp av vatten på det sättet som skyddar naturresurser, garanterar tuffa miljölagstiftningar och säkerställer ekonomin. I detta sammanhang är membrandestillering (MD) en lovande teknik för rening av avloppsvatten och är kapabel att bemöta dessa krav genom utnyttjandet av låg-temperatur värmekällor. Denna avhandling fokuserar på experimentella undersökningar och tekno-ekonomiska utvärderingar av spillvärmedrivna MD-system för vattenrening i två vattenintensiva industrier: nano-elektronisk tillverkning och kraftvärmeverk. Vattenprover hämtade från relevanta anläggningar testades i en luftspalt MD rigg i bänkskala och hos en halv-kommersiell pilotanläggning, med fokus på separationsverkningsgrad och möjligheten att nå en hög grad av uppkoncentrering. För den tekno-ekonomiska analysen av ett system i industriellt skal undersöktes prestandan hos den valda halv-kommersiell enhet för att utvärdera drift i fullt skal gällande termiskt energibehov och förväntad kostnad för renat vatten. Olika termiska integreringssätt utvärderades med hänsyn till lokala värmekällor för att tillgodose energibehoven hos det specifika MD-systemet. De valda fallstudierna omfattar: avskiljning av tetrametylammonium hydroxid (TMAH) från fotolitografiska avloppsvatten i nano-elektronisk tillverkning; behandling av kemisk-me

Published

2021

36. On the reliability estimation of nano-circuits using neural networks.

Author

Beg, Azam, Awwad, Falah, Ibrahim, Walid, and Ahmed, Faheem

Subjects

*CIRCUIT reliability, *ESTIMATION theory, *ARTIFICIAL neural networks, *MONTE Carlo method, *NANOELECTRONICS

Abstract

As the integrated circuit geometries shrink, it becomes important for the designers to take into consideration the reliability of the circuits. Different techniques can be used for reliability calculation or estimation. Some of these techniques are accurate but time-consuming while others are quick but not accurate . For example, using a set of mathematical equations for reliability estimation is very fast but not precise enough for large systems. Alternatively, Monte Carlo simulations are highly accurate, but very time-intensive. This work presents three different neural network models for estimating circuit reliability. The models provide better prediction accuracies than the mathematical technique. A reasonably large number of combinational circuits were simulated over a wide range of device reliabilities to collect the training data for the models. Multiple slices of an ISCAS-85 benchmark circuit were used to validate the models’ prediction results. [ABSTRACT FROM AUTHOR]

Published

2015

37. Body doping analysis of vertical strained-SiGe Impact Ionization MOSFET incorporating dielectric pocket (VESIMOS-DP).

Author

Saad, Ismail, Zuhir, H. Mohd., Bun Seng, C., Pogaku, Divya, Bakar, A R Abu, Khairul, A. M., Ghosh, Bablu, Bolong, N., Ismail, Razali, and Hashim, U.

Abstract

The Vertical Strained Silicon Germanium (SiGe) Impact Ionization MOSFET with Dielectric Pocket (VESIMOS-DP) has been successfully developed and analyzed in this paper. There are significant drop in subthreshold slope (S) while threshold voltage is increase as the body doping concentration increases. It is notable that for body doping concentration above 1020, the S values keep increasing which is not recommended as the switching speed getting higher distracting performance of the device. An improved stability of threshold voltage, VTH was found for VESIMOS-DP device of various DP size ranging from 20nm to 80nm. The stability is due to the reducing charge sharing effects between source and drain region. In addition, the output characteristic was also highlighted a very good drain current at different gate voltage with the increasing of drain voltage for VESIMOS-DP with high body doping concentration. VESIMOS-DP with low body doping concentration suffers PBT effect that prevents the device from being able to switch off. Hence, high body doping concentrations are imperative for obtaining better device characteristics and ensure the device works in II mode. [ABSTRACT FROM PUBLISHER]

Published

2013

38. Mobility enhancement on Vertical Strained-SiGe Impact Ionization MOSFET incorporating Dielectric Pocket (VESIMOS-DP).

Author

Saad, Ismail, Zuhir H., Mohd., Seng C., Bun, Bakar AR, Abu, Bolong, N., A.M, Khairul, Ghosh, Bablu, and Ismail, Razali

Abstract

The Vertical Strained Silicon Germanium (SiGe) Impact Ionization MOSFET with Dielectric Pocket (VESIMOS-DP) has been successfully developed and analyzed in this paper. The electron mobility in the VESIMOS-DP (∼1440m2/V-s), was found to be increased by 4% in comparison to VESIMOS (∼1386 m2/V-s) device. The mobilities in strained layer is depends on the transport direction, either parallel to the original SiGe growth interface or in the perpendicular direction. Carrier mobilities in strained SiGe layer is also based on the local distortion due to the strain effects which contribute to the alloy scattering on the carriers. With the vicinity of DP, the carrier scattering effect has reduced which merits the introduction of DP on the device. Due to the DP layer, improve stability of threshold voltage, VTH and subthreshold slope, S was found for VESIMOS-DP device of various size ranging from 20nm to 80nm justified the vicinity of the DP on improving the performance of the device. [ABSTRACT FROM PUBLISHER]

Published

2013

39. Impact of strain and DP position on the performance of Vertical Strained-SiGe Impact Ionization MOSFET incorporating dielectric pocket (VESIMOS-DP).

Author

Saad, Ismail, Mohd. Zuhir, H., Bun Seng, C., Abu Bakar, AR, Bolong, N., Khairul, A.M, Bablu, Ghosh, and Razali, Ismail

Abstract

The Vertical Strained Silicon Germanium (SiGe) Impact Ionization MOSFET with Dielectric Pocket (VESIMOS-DP) has been successfully developed and analyzed in this paper. The strain is induced in the structure by varying the mole fraction of Silicon Germanium layer as well as the channel thickness. Increase in mole fraction at the interface of channel region results in increase in strain in the channel. In order to maintain strain in the channel region, a relaxed Si1−xGex layer is required. S value for DP place at source side is higher (S=24.4 mV/decade) as compared at the drain side (S=18.9 mV/decade) intrinsic region. The impact ionization rate depends on the electric field at drain side intrinsic zone. The vicinity of DP near the drain region reduces charge sharing effects associated with the source and thus improves impact ionization rate. Due to the DP layer, improve stability of threshold voltage, VTH and subthreshold slope, S was found for VESIMOS-DP device of various size ranging from 20nm to 80nm which justified the vicinity of DP on improving the performance of the device [ABSTRACT FROM PUBLISHER]

Published

2013

40. Semiconductor-to-metallic flipping in a ZnFe2O4–graphene based smart nano-system: Temperature/microwave magneto-dielectric spectroscopy.

Author

Ameer, Shahid, Gul, Iftikhar Hussain, Mahmood, Nasir, and Mujahid, Muhammad

Subjects

*SEMICONDUCTORS, *ZINC compounds, *GRAPHENE, *NANOSTRUCTURED materials, *X-ray diffraction

Abstract

Zn-(FeO 2 ) 2 –graphene smart nano-composites were synthesized using a novel modified solvothermal synthesis with different percentages of graphene. The structure of the nanocomposite was confirmed through X-ray diffraction, micro-Raman scattering spectroscopy, Ultraviolet–Visible spectroscopy, and Fourier transform infrared spectroscopy. The structural growth and morphological aspects were analyzed using scanning/transmission electron microscopy, revealing marvelous micro-structural features of the assembled nano-system resembling a maple leaf. To determine the composition, energy dispersive spectroscopy and X-ray photoelectron spectroscopy were used. Microwave magneto-dielectric spectroscopy revealed the improved dielectric properties of the nano-composite compared to those of the parent functional nanocrystals. Temperature gradient dielectric spectroscopy was used over the spectral range from 100 Hz to 5 MHz to reveal the phenomenological effect that the nanosystem flips from its usual semiconductor nature to a metallic nature with sensing temperature. Electrical conductivity and dielectric analysis indicated that the dielectric loss and the dielectric permittivity increased at room temperature. This extraordinary switching capability of the functionalized graphene nanosystem opens up a new dimension for engineering advanced and efficient smart composite materials. [ABSTRACT FROM AUTHOR]

Published

2015

41. Comparative Analysis of MGFETs and their Logic Implementations for Different Technology Nodes.

Author

YASEEN, I., KANT, N. A., KHANDAY, FAROOQ A., and SYCHALINOS, COSTAS P.

Subjects

PERFORMANCE of field-effect transistors, GATE array circuits, INTEGRATED circuit design, COMPARATIVE studies, COMPLEMENTARY metal oxide semiconductors, NANOTECHNOLOGY, NANOELECTRONICS

Abstract

Multi-Gate FET (MGFET) device technology is the most promising technology for extending Moore's Law all the way down to 5nm. Besides being fully compatible with CMOS in both bulk and SOI varieties, MGFET device technology offers excellent solution to the problems of tunnelling carriers through ultra-thin gate dielectrics, short-channel effects, degraded sub-threshold performance and eventual quantum-mechanical effects that plagued planar CMOS as it is scaled down towards 20nm. Furthermore, it offers the ability to operate at much lower supply voltages and allows both static and dynamic power savings. In this paper. Common-mode (CM) MGFETs for three technology nodes (32nm, 22nm and 16nm) were simulated using SPICE simulator and compared for various performance characteristics. The variation in performance parameters was studied and compared for Double-Gate (DG), Triple-Gate (TG) and Gate-All-Around (GAA) to verify their scope for analogue and digital applications. In addition, the comparative results and performance parameters of CM MGFETs based logic gates for the three technology nodes are also presented. [ABSTRACT FROM AUTHOR]

Published

2014

42. Probabilistic Modeling and Analysis of Molecular Memory.

Author

KUMAWAT, RENU, SAHULA, VINEET, and GAUR, MANOJ S.

Subjects

MOLECULAR memory, NANOPARTICLES, INFORMATION retrieval research, MOLECULAR switches, MODEL validation

Abstract

This article investigates the aspects of designing a nanocell based molecular memory. An empirical model for molecular device is developed, based on circuit behavior of nitro-substituted Oligo (Phynylene Ethynylene) molecule (OPE). This device model is subsequently used to design nanocell based 1-bit memory and verified using HSPICE. The approach is extended to train the nanocell for multibit storage capability using external voltage signals. It is observed that to successfully train a 2-bit molecular memory, the number of control signals should be approx. one-fourth of total number of nanoparticles. A computational framework is proposed to compute the probability of retrieving the stored data bits correctly, at the output terminal of the nanocell buffer. This nanocell configuration is simulated by systematically varying number of nanoparticles and molecular switches. It is observed that the probability of the existence of at least one path from input to output approaches close to unity with presence of 20 or more nanoparticles in a nanocell. During memory model validation, 1000 samples of 1-bit memory (consisting of 20 nanoparticles) were generated and verified for read and write operations. The model verification results obtained for this memory cell closely match those obtained using analytical solution of probabilistic graph model. [ABSTRACT FROM AUTHOR]

Published

2014

43. Nano-Crossbar Memories Comprising Parallel/Serial Complementary Memristive Switches.

Author

Vourkas, Ioannis and Sirakoulis, Georgios

Abstract

This work explores anti-serial (anti-parallel) memristive switches-ASMs (APMs)-as potential cross-point elements in nano-crossbar resistive random access memory arrays. The memory operation principles for both device combinations are shown in detail. The effectiveness of these memristive structures to the solution of the parasitic conducting (current sneak paths) problem is presented via an analytical approach which is based on the basic setup of resistive crossbar memories. Simulation results of crossbars of up to 4,096 elements, arranged in quadratic configurations, are conducted. The provided results supplement this comprehensive analysis of APMs and ASMs, outlining their overall performance characteristics and commenting on their applicability to the practical realization of large crossbar memory systems. Finally, a special array topology is applied to an ASM-based crossbar memory. Its performance is compared to the performance of the pure ASM-based memory. The conducted simulations reveal significantly improved read-out voltage margins which further contribute to addressing the parasitic current paths which prevent the reliable operation of memristive crossbar circuit topologies. [ABSTRACT FROM AUTHOR]

Published

2014

44. Doping Concentrations Analysis on The Performance of Vertical Strained-SiGe Impact Ionization MOSFET Incorporating Dielectric Pocket (VESIMOS-DP).

Author

Mohd Ismail Saad, Zuhir, H., Bun Seng, C., Khairul, A. M., Ghosh, Bablu, Bolong, N., and Ismail, Razali

Subjects

METAL oxide semiconductor field-effect transistors, THRESHOLD voltage, DIELECTRIC properties, BIPOLAR transistors, BIPOLAR transistor switches

Abstract

The Vertical Strained SiGe Impact Ionization MOSFET incorporating Dielectric Pocket (VESIMOS-DP) has been successfully developed and analyzed in this paper. The effect of doping concentration for both Source and Drain (S/D) as well as body doping concentration to the performance of VESIMOS-DP in terms of subthreshold slope (S), threshold voltage (VTH) and drain current has been observed in this paper. An inverse proportional of S and VTH value was found when S/D doping concentration increased. It is notable that for S/D doping concentration above 1019 atoms/cm3, there is a significant increase in S values which is not recommended as the switching speed getting higher distracting performance of the device. However, too low S/D doping concentration is not essential as it didn't show any significant improvement on the performance of the device. It is also revealed that with low body doping concentration, the device suffers tremendous Parasitic Bipolar Transistor (PBT) effect that prevents the device from switched off. Thus, optimum doping concentration is imperative to obtain superb device characteristic. Due to the DP layer, a stable VTH =1.35V obtained due to the vicinity of DP layer near the drain end has reduced charge sharing between the source and drain. The slight different and consistency of VESIMOS-DP subthreshold value (S = 19 mV/dec) has given advantages for incorporating DP layer near the drain end. In many aspects, it is revealed that the incorporation of DP has enhanced the electrical performance and suppressed PBT effect of IMOS in the nanometer regime for future development of nanoelectronic device. [ABSTRACT FROM AUTHOR]

Published

2014

45. Techno-economic system analysis of membrane distillation process for treatment of chemical mechanical planarization wastewater in nano-electronics industries

Author

Imtisal-e Noor, Olli Dahl, Andrew Martin, School services, CHEM, KTH Royal Institute of Technology, Clean Technologies, Department of Bioproducts and Biosystems, Aalto-yliopisto, and Aalto University

Subjects

Exergy, Filtration and Separation, Membrane distillation, 02 engineering and technology, Wastewater treatment, Desalination, Analytical Chemistry, ENERGY, REMOVAL, 020401 chemical engineering, DESIGN, Chemical-mechanical planarization, EXERGY, ELECTROCOAGULATION, 0204 chemical engineering, PLANT, Process engineering, SOLAR, Operating cost, SCALE, business.industry, Techno-economic system analysis, Low-grade heat sources, RECOVERY, 021001 nanoscience & nanotechnology, Chemical mechanical planarization, Nano-electronics, Wastewater, DESALINATION, Environmental science, Sewage treatment, 0210 nano-technology, business, Thermal energy

Abstract

Membrane distillation (MD) is a promising separation technology for the treatment of chemical mechanical planarization (CMP) wastewater releasing from nano-electronics industries. In order to determine the feasibility of the process at industrial scale, the most important factors are large-scale system evaluation and related economics. Since membrane distillation is a thermally driven process, therefore, different integration possibilities between an air gap membrane distillation (AGMD) system and low-grade heat sources are identified and analyzed in this work. Global mass and energy balances are conducted around AGMD system for CMP wastewater treatment in a typical nano-electronics manufacturing facility. It is determined that around 100 GWh of thermal energy can be readily recovered via internal sources and reused to treat 120,000 m(3) CMP wastewater/ year with MD feed temperature of 80 degrees C. Along with the technical feasibility of the system, the detailed economic evaluation has also been performed. Annual capital investment and operating cost showed that the expected CMP wastewater treatment cost can be as low as 3 $/m(3), which is estimated to be nearly 95% lower than the wastewater treatment cost using electro-chemical systems.

Published

2020

46. Performance assessment of chemical mechanical planarization wastewater treatment in nano-electronics industries using membrane distillation

Author

Noor, Imtisal-e, Coenen, Jan, Martin, Andrew R., Dahl, Olli, Noor, Imtisal-e, Coenen, Jan, Martin, Andrew R., and Dahl, Olli

Abstract

Wastewater from chemical mechanical planarization (CMP) processes in nano-electronics industries must be treated properly in order to fulfil local and international environmental regulations. This study is focused on a performance assessment of membrane distillation (MD) technology for CMP wastewater treatment. A new prototype of air gap membrane distillation (AGMD) module was utilized, with feed water consisting of CMP wastewater collected from imec, Belgium. The module was tested at different operating conditions (temperatures, flow rates and filtration time) and responses in terms of separation efficiency, permeate water quality, transmembrane flux, specific heat demand and exergy efficiency were determined. High quality permeate was produced in all trials, i.e. conductivity ~2.11 µS/cm, pH ~5.4, TOC ~1.13 ppm, IC ~0.24 ppm, TDS ~1.18 ppm and COD ~ 1.9 ppm; for most of the contaminants the separation efficiency was >99%. These findings clearly show that the resulting MD permeate does not exceed environmental regulations for release to recipient, and the permeate can even be considered for reuse. Moreover, the determined specific heat demand at different operating conditions was varying between 1390 and 2170 kWh/m3 whereas; the achievable exergy efficiency was ~19%., QC 20191202

Published

2020

47. Techno-economic system analysis of membrane distillation process for treatment of chemical mechanical planarization wastewater in nano-electronics industries

Author

Noor, Imtisal-e, Martin, Andrew R., Dahl, Olli, Noor, Imtisal-e, Martin, Andrew R., and Dahl, Olli

Abstract

Membrane distillation (MD) is a promising separation technology for the treatment of chemical mechanical planarization (CMP) wastewater releasing from nano-electronics industries. In order to determine the feasibility of the process at industrial scale, the most important factors are large-scale system evaluation and related economics. Since membrane distillation is a thermally driven process, therefore, different integration possibilities between an air gap membrane distillation (AGMD) system and low-grade heat sources are identified and analyzed in this work. Global mass and energy balances are conducted for the AGMD system for CMP wastewater treatment in a typical nano-electronics manufacturing facility. It is determined that around 100 GWh of thermal energy can be readily recovered via internal sources and reused to treat 120,000 m3 CMP wastewater/year with MD feed temperature of 80◦C. Along with the technical feasibility of the system, the detailed economic evaluation has also been performed. Annual capital investment and operating cost showed that the expected CMP wastewater treatment cost can be as low as 3 $/m3 of treated water, which is estimated to be nearly 95% lower than the wastewater treatment cost from electro-chemical systems., QC 20200625

Published

2020

48. Contact transparency inducing negative differential resistance in nanotube–molecule–nanotube junction predicted by first-principles study.

Author

Min, Y., Fang, J.H., Zhong, C.G., Dong, Z.C., Wang, C.N., Xue, T.L., and Yao, K.L.

Subjects

*CARBON nanotubes, *SEMICONDUCTOR junctions, *CONTACT mechanics, *NANOELECTRONICS, *TRANSPORT theory, *AB-initio calculations

Abstract

Abstract: We construct a molecular junction where propyl contacts two armchair carbon nanotubes through five-member ring and perform the first-principles calculations of its transport properties. The negative differential resistance effect with peak-to-valley ratio of 700% is present. Our investigations indicate that contact transparency can induce negative differential resistance in nanotube–molecule–nanotube junction, which may promise the potential application in nano-electronics devices in the future. [Copyright &y& Elsevier]

Published

2014

49. ILP Formulations for Variation/Defect-Tolerant Logic Mapping on Crossbar Nano-Architectures.

Author

ZAMANI, MASOUD, MIRZAEI, HANIEH, and TAHOORI, MEHDI B.

Subjects

NANOELECTRONICS, COMPLEMENTARY metal oxide semiconductors, LINEAR programming, FIELD-effect transistors, CROSSBAR switches (Electronics)

Abstract

Several emerging nano-technologies, including crossbar nano-architectures, have recently been studied as possible replacement or supplement to CMOS technology in the future. However, extreme process variation and high failure rates, mainly due to atomic device sizes, are major challenges for crossbar nanoarchitectures. This article presents variation- and defect-tolerant logic mapping on crossbar nano-architectures. Since variation/defect-aware mapping is an NP-hard problem, we introduce a set of Integer Linear Programming (ILP) formulations to effectively solve the problem in a reasonable time. The proposed ILP formulations can be used for both diode-based and FET-based crossbars. Experimental results on benchmark circuits show that our approach can reduce the critical-path delay 39% compared to the Simulated Annealing (SA) method. It can also successfully achieve 97% defect-free mapping with 40% defect density. It can tolerate process variations to meet timing constraints in 95% of the cases, compared to only 77% achieved by SA. [ABSTRACT FROM AUTHOR]

Published

2013

50. Optical Capsule and Tweezer Array for Molecular Motor Use.

Author

Yupapin, Preecha P., Kulsirirat, Kathawut, and Techithdeera, Wicharn

Abstract

A generation of optical capsules and tweezers within a modified optical add-drop filter known as PANDA ring resonator with a new concept is proposed. By using dark and bright solitons, the orthogonal tweezers can be formed within the system and observed simultaneously at the output ports. Under the resonant condition, the optical capsules and tweezers generated by dark and bright soliton pair corresponding to the left-hand and right-hand rotating solitons (tweezers) can be generated. When a soliton is interacted by an object, an angular momentum of either bright or dark tweezers is imparted to the object, in which two possible spin states known as tweezer spins are exhibited. Furthermore, an array of molecular capsules and spins, i.e., trapped molecules can be generated and detected by using the proposed system, which can be used to form large scale tweezer or capsule spins. In application, the trapped molecules can be moved and rotated securely to the required destinations, which can be useful for many applications, especially, in medical diagnosis, therapy and surgery. [ABSTRACT FROM PUBLISHER]

Published

2013