LEADER 10184nam  22004453  450 
001 9911066119903321
005 20260207060324.0
010   $a1-394-33648-9
010   $a1-394-33647-0
035   $a(MiAaPQ)EBC32536954
035   $a(Au-PeEL)EBL32536954
035   $a(CKB)45227924600041
035   $a(OCoLC)1572094561
035   $a(EXLCZ)9945227924600041
100   $a20260207d2026      uy         0
101 0 $aeng
135   $aurcnu||||||||
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aMicroelectronics $eSimulations, Modeling and Applications
205   $a1st ed.
210  1$aNewark :$cJohn Wiley & Sons, Incorporated,$d2026.
210  4$dİ2026.
215   $a1 online resource (561 pages)
311 08$a1-394-33645-4 
327   $aCover -- Series Page -- Title Page -- Copyright Page -- Contents -- Preface -- Acknowledgment -- Chapter 1 2D Materials for Microelectronic Devices -- 1.1 Introduction -- 1.2 Fundamental Properties of 2D Materials -- 1.2.1 Graphene -- 1.2.2 Hexagonal Boron Nitride (h-BN) -- 1.2.3 Transition Metal Dichalcogenides (TMDs) -- 1.2.4 Borophene -- 1.2.5 Phosphorene -- 1.2.6 Silicene -- 1.2.7 Germanene -- 1.2.8 MXenes -- 1.3 Synthesis and Fabrication Techniques -- 1.3.1 Mechanical Exfoliation -- 1.3.2 Chemical Vapor Deposition -- 1.3.3 Liquid Phase Exfoliation -- 1.3.4 Molecular Beam Epitaxy -- 1.3.5 Fabrication Techniques -- 1.4 Microelectronic Devices Based on 2D Materials -- 1.4.1 Transistors -- 1.4.2 Memory Devices -- 1.4.3 Sensors -- 1.4.4 Optoelectronic Devices -- 1.5 Conclusion and Future Prospects -- References -- Chapter 2 Microelectronic Devices -- 2.1 Introduction -- 2.2 Microelectronic Devices for Gas Sensor -- 2.3 Microelectronic Devices for Biosensor -- 2.4 MEMS-Based Sensors -- 2.5 Microelectronic Packaging -- 2.6 Various Microelectronic Devices for Distinct Uses -- 2.7 Summary -- References -- Chapter 3 Insights Review of Microelectronic Devices -- 3.1 Simulations of Microelectronic Devices -- 3.2 FinFET -- 3.3 Tunnel FET -- 3.4 Nanowire-FET -- 3.5 Nanosheet FET -- 3.6 FeFET -- 3.7 NCFET -- 3.8 Planar and Vertical Nano-FET Structures -- References -- Chapter 4 Novel Devices with Carbon and Graphene -- 4.1 Introduction -- 4.1.1 Overview of Carbon and Graphene -- 4.1.2 Carbon-Based Materials -- 4.1.3 Importance of Graphene in Modern Technology -- 4.2 Graphene and Carbon's Properties -- 4.2.1 Structural Characteristics -- 4.2.2 Electrical and Thermal Conductivity -- 4.2.3 Mechanical Strength -- 4.2.4 Optical Properties -- 4.3 Carbon and Graphene Synthesis -- 4.3.1 Chemical Vapor Deposition -- 4.3.2 Mechanical Exfoliation.
327   $a4.3.3 Reduction of Graphene Oxide -- 4.3.4 Exfoliation in Liquid Phase -- 4.3.5 Silicon Carbide (SiC) Epitaxial Growth -- 4.3.6 Plasma-Enhanced Chemical Vapor Deposition -- 4.4 Carbon-Based Devices -- 4.4.1 Carbon Nanotubes in Electronics -- 4.4.2 Carbon-Based Transistors and FETs -- 4.4.3 Energy Storage Devices (Batteries, Supercapacitors) -- 4.4.4 Carbon Sensors and Actuators -- 4.5 Graphene-Based Devices -- 4.5.1 Graphene Transistors and FETs -- 4.5.2 Graphene for Energy Harvesting and Storage -- 4.5.3 Graphene Photodetectors and Optoelectronics -- 4.5.4 Graphene-Based Flexible Electronics -- 4.6 Comparative Study of Carbon Nanotube and Graphene-Based Devices -- 4.7 Applications of Carbon and Graphene in Novel Devices -- 4.7.1 Wearable Electronics -- 4.7.2 Biomedical Applications -- 4.7.3 Environmental Sensors and Water Purification -- 4.7.4 Energy Harvesting and Solar Cells -- 4.7.5 Quantum Computing and Advanced Memory Devices -- 4.8 Challenges and Future Directions -- 4.8.1 Production Scalability and Cost -- 4.8.2 Integration with Current Technology -- 4.8.3 Environmental and Safety Concerns -- 4.8.4 Future of Carbon and Graphene in Electronics -- 4.9 Conclusion -- 4.9.1 Summary of Key Points -- 4.9.2 Potential of Carbon and Graphene in Future Technologies -- References -- Chapter 5 Carbon and Graphene Devices with Applications -- 5.1 Introduction -- 5.2 Carbon: Advantages and Properties -- 5.2.1 Advantages of Carbon -- 5.2.2 Properties of Carbon -- 5.3 Graphene: Advantages and Properties -- 5.3.1 Advantages of Graphene -- 5.3.2 Properties of Graphene -- 5.4 Novel Device Structures Based on Carbon -- 5.4.1 Carbon Nanotube FETs (CNTFETs) -- 5.4.2 Carbon-Based Sensors -- 5.4.3 Carbon-Based Solar Cells -- 5.4.4 Carbon-Based Energy Storage Devices -- 5.4.5 Carbon-Based Memristors -- 5.5 Novel Device Structures Based on Graphene.
327   $a5.5.1 Graphene Transistors -- 5.5.2 Graphene-Based Sensors -- 5.5.3 Graphene-Based Memory Devices -- 5.5.4 Graphene-Based Solar Cells -- 5.5.5 Graphene-Based Quantum Devices -- 5.6 Fabrication and Integration Challenges -- 5.7 Future Outlook -- 5.8 Conclusion -- 5.9 Summary -- References -- Chapter 6 III-V Compound Semiconductor Devices -- 6.1 Introduction -- 6.2 Properties of III-V Compound Semiconductors -- 6.3 Fabrication Processes -- 6.4 Applications of III-V Compound Semiconductors -- 6.5 Optoelectronic Devices -- 6.6 Challenges and Future Prospects -- 6.7 Conclusion -- References -- Chapter 7 Dopingless Heterojunction Tunnel FET and its Application -- 7.1 Introduction -- 7.1.1 New Approaches for Upcoming Technology Generations -- 7.2 Tunnel FET Technology: State of the Art -- 7.2.1 Band-to-Band Tunneling Current -- 7.3 Device Design and Simulation Methodologies -- 7.4 Results and Discussions -- 7.5 Conclusion -- References -- Chapter 8 Silicon Nanowire Field Effect Transistor and Its Applications -- 8.1 Introduction -- 8.2 Multi-Gate Device -- 8.3 Advanced GAAFET Technology -- 8.4 Triple-Gate Optimization Junctionless Cylindrical SiNWFET-Based Uricase and ChOx Biosensor Device -- 8.5 Results and Discussion of Advanced Triple SiNW GAAFET Device -- 8.6 Conclusion -- References -- Chapter 9 Impact of Material and Structural Engineering in Double-Gate Junction Underlap Dual-Gate FinFETs -- 9.1 Background -- 9.2 Structure and Simulation of a 2D FinFET -- 9.3 Setup of the Simulation -- 9.4 Submicron Effects -- 9.5 Impact of Different Oxide Materials -- 9.6 Structural Engineering -- 9.7 Applications of Double-Gate FinFETs Based on Design Variations -- 9.8 Summary -- References -- Chapter 10 Nanoelectronic System Design for RF Energy Harvesting -- 10.1 Introduction -- 10.2 RF Energy Harvesting: Basic Design Perspectives.
327   $a10.3 Design of Microelectronic Systems for RF Energy Harvesting -- 10.3.1 Rectifier Design Perspectives -- 10.3.2 Power Management Unit: Aspects of Design -- 10.4 Nanoelectronic Systems for RFEH -- 10.4.1 Nanomaterials for RFEH: Design of Devices and Detectors -- 10.4.2 Nano-EH: The Future of RF Energy Harvesting -- 10.5 Conclusion -- References -- Chapter 11 Fin Field-Effect Transistor-Based Digital Logic Circuits Using 7-nm Regime -- 11.1 Introduction -- 11.1.1 Fin-FET Device: Scaling -- 11.2 Literature Overview -- 11.3 Fin-FET-Based Digital Circuits -- 11.4 Conclusion -- 11.5 Summary of Chapter -- References -- Chapter 12 MEMS Sensors and Its Applications -- 12.1 Introduction and Scope -- 12.2 MEMS Sensor Development and Fabrication Process -- 12.3 Applications -- 12.4 Market Analysis and Key Players -- 12.5 MEMS Sensor's Working Principle -- 12.6 MEMS Sensors-Principle, Structural Design, and Applications -- 12.7 Packaging Challenges in MEMS Sensors -- 12.8 Future Scope -- 12.9 Summary -- Acknowledgments -- References -- Chapter 13 Investigation of MEMS Sensors and Applications -- 13.1 Introduction -- 13.2 Classification of MEMS Sensors -- 13.3 MEMS Thermoelectric Infrared Sensors -- 13.4 MEMS Humidity Sensor -- 13.5 MEMS Electrochemical Vibration Sensor -- 13.6 MEMS Pressure Sensors -- 13.7 MEMS Sun Sensor -- 13.8 MEMS Technology for Sensing High-Voltage DC Artificial Electric Fields in Air -- 13.9 A Sensor for Hematology Analyzer Using MEMS Technology -- 13.10 Microelectromechanical System Gas Sensor Utilizing Carbon Nanotubes for Ionization -- 13.11 Uniform Mass Sensitivity in MEMS Vibrational Mass Sensors -- 13.12 Temperature Sensor Using MEMS-Based Platinum Film on an Alumina Substrate -- 13.13 Conclusion -- References -- Chapter 14 Piezoelectric MEMS Sensors and its Applications -- 14.1 Introduction.
327   $a14.2 Fundamentals of Piezoelectric MEMS Sensors -- 14.3 Development of Piezoelectric Materials -- 14.4 Sensing Performance Criteria -- 14.5 Applications of Piezoelectric MEMS Gas Sensors -- 14.6 Challenges -- 14.7 Conclusion and Future Perspectives -- References -- Chapter 15 Design Exploration of PVT-Tolerant Pre-Amplifiers for Seizure Monitoring -- 15.1 Introduction -- 15.2 Methodology -- 15.3 Design Implementation Technique -- 15.4 Simulation Results -- 15.5 Conclusion -- References -- Chapter 16 Advanced Electroencephalography and Its Influence on Neuroscience Applications -- 16.1 Introduction -- 16.2 Comprehending Neurological Activities -- 16.3 Methodology -- 16.4 Circuit Diagram and Description -- 16.5 Design Specifications -- 16.6 Simulation and Results -- 16.7 Output Waveforms -- 16.8 Conclusion -- References -- Chapter 17 Bridging Memory and Computation: Reimagining Digital Logics through Memristor Technology -- 17.1 Introduction -- 17.2 IMPLY and FALSE -- 17.3 MAGIC -- 17.4 Ternary Logic -- 17.5 Decision Tree -- 17.6 Conclusion -- References -- Chapter 18 Nanowire Synapse for Accelerating Neuromorphic Computing -- 18.1 Introduction -- 18.1.1 Neuromorphic Computing -- 18.1.2 Nanowire-FETs -- 18.2 Literature Review -- 18.3 Methodology -- 18.4 Challenges and Opportunities -- 18.5 Result and Discussion -- 18.6 Conclusion -- References -- About the Editors -- Index -- Also of Interest -- EULA.
330   $aUnlock the future of nanotechnology with this essential guide, which provides an exhaustive exploration of solutions to overcome the physical limits of silicon and optimize the performance of next-generation nanoscale semiconductor devices.
700   $aRaj$b Balwinder$01841729
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9911066119903321
996   $aMicroelectronics$94547544
997   $aUNINA