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001 9780429022210
003 FlBoTFG
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006 m d
007 cr |||||||||||
008 190322s2019 si o 000 0 eng d
040 _aOCoLC-P
_beng
_erda
_epn
_cOCoLC-P
020 _a9780429663871
_q(ePub ebook) :
020 _a0429663870
020 _a9780429666599
_q(PDF ebook) :
020 _a0429666594
020 _a9780429661150
_q(Mobipocket ebook) :
020 _a0429661150
020 _a9780429022210
_q(ebook) :
020 _a0429022212
020 _z9789814800365 (hbk.)
020 _z9814800368
024 8 _a10.1201/9780429022210
_2doi
035 _a(OCoLC)1110437180
_z(OCoLC)1109795261
_z(OCoLC)1109836592
_z(OCoLC)1109972631
_z(OCoLC)1109996103
035 _a(OCoLC-P)1110437180
050 4 _aTA455.G65
072 7 _aSCI
_x086000
_2bisacsh
072 7 _aTEC
_x008000
_2bisacsh
072 7 _aTEC
_x027000
_2bisacsh
072 7 _aTJFD
_2bicssc
082 0 4 _a621.3815
_223
100 1 _aBanadaki, Yaser M.,
_eauthor.
_914900
245 1 0 _aGraphene nanostructures :
_bmodeling, simulation, and applications in electronics and photonics /
_cYaser M. Banadaki, Safura Sharifi.
250 _a1st.
264 1 _aSingapore :
_bPan Stanford Publishing,
_c2019.
300 _a1 online resource
336 _atext
_2rdacontent
337 _acomputer
_2rdamedia
338 _aonline resource
_2rdacarrier
500 _a<P>Introduction to Graphene. Graphene for Integrated Circuits. Computational Carrier Transport Model of GNRFET. Scaling Effects on Performance of GNRFETs. Width-dependent Performance of GNRFETs. A Spice Physics-based Circuit Model of GNRFET. Graphene-based Circuits Design. Graphene Sensing and Energy Recovery. Graphene Photonic Properties and Applications. Graphene-based Thermal Emitter. </P>
505 0 _aCover; Half Title; Title Page; Copyright Page; Contents; Preface; 1. Introduction to Graphene; 1.1 Physical Geometry and Properties; 1.2 Graphene Nanoribbon; 2. Graphene for Integrated Circuits; 2.1 Introduction; 2.2 Scaling Challenges of Silicon Electronics; 2.3 Graphene-Based Field-Effect Transistors; 2.4 Graphene-Based Integrated Circuits; 3. Computational Carrier Transport Model of GNRFET; 3.1 Introduction; 3.2 Quantum Transport Model; 3.3 Quantum Capacitance in GNRFET; 3.4 Computational Time; 3.5 Summary; 4. Scaling Effects on Performance of GNRFETs; 4.1 Introduction
505 8 _a4.2 Device Structure4.3 Transfer Characteristics of GNRFETs; 4.4 Scaling Effects on Static Metric of GNRFETs; 4.4.1 OFF-Current; 4.4.2 I[sub(ON)]/I[sub(OFF)] Ratio; 4.4.3 Subthreshold Swing; 4.4.4 Drain-Induced Barrier Lowering; 4.4.5 Voltage Transfer Characteristic; 4.5 Scaling Effects on Switching Attributes of GNRFETs; 4.5.1 Intrinsic Gate Capacitance; 4.5.2 Intrinsic Cut-off Frequency; 4.5.3 Intrinsic Gate-Delay Time; 4.5.4 Power-Delay Product; 4.6 Summary; 5. Width-Dependent Performance of GNRFETs; 5.1 Introduction; 5.2 Device Structure; 5.3 GNR Sub-bands
505 8 _a5.4 Width-Dependent Static Metrics of GNRFETs5.4.1 OFF-Current; 5.4.2 I[sub(ON)]/I[sub(OFF)] Ratio; 5.4.3 Subthreshold Swing; 5.5 Width-Dependent Switching Attribute of GNRFETs; 5.5.1 Threshold Voltage; 5.5.2 Transconductance; 5.5.3 Intrinsic Gate Capacitance; 5.5.4 Intrinsic Cut-off Frequency; 5.5.5 Intrinsic Gate-Delay Time; 5.6 Summary; 6. A SPICE Physics-Based Circuit Model of GNRFETs; 6.1 Introduction; 6.2 GNRFET Structure; 6.3 GNRFET Model; 6.3.1 Computing GNR Sub-bands; 6.3.2 Finding Channel Surface Potential; 6.3.2.1 Computing channel charge
505 8 _a6.3.2.2 Computing transient capacitance charge6.3.3 Current Modeling; 6.3.3.1 Computing thermionic current; 6.3.3.2 BTBT current and charge; 6.3.4 Non-ballistic Transport; 6.3.5 Extracting Fitting Parameters; 6.4 Model Validation; 6.4.1 Comparing with Computational NEGF Formalism; 6.4.2 Comparing with Many-Body Problem; 6.5 Effect of Edge Roughness on Device Characteristic; 6.5.1 Transfer Characteristics of GNRFETs; 6.5.2 OFF-State Characteristics of GNRFETs; 6.6 Summary; 7. Graphene-Based Circuit Design; 7.1 Introduction; 7.2 All-Graphene Circuits; 7.3 Graphene Inverter
505 8 _a7.4 Power and Delay of GNRFET Circuits7.5 GNRFET-Based Energy Recovery Logic Design; 7.6 Summary; 8. Graphene Sensing and Energy Recovery; 8.1 Introduction; 8.2 GNRFET-Based Temperature Sensors; 8.3 GNRFET for Energy Harvesting; 8.3.1 Thermoelectric Model; 8.3.2 Electrical Conductivity; 8.3.3 Seebeck Coefficient; 8.3.4 Electrical Thermal Conductivity; 8.3.5 Power Factor; 8.3.6 Thermoelectric Figure-of-Merit ZT; 8.4 Summary; 9. Graphene Photonic Properties and Applications; 9.1 Introduction; 9.2 Photonic Properties; 9.3 Graphene Photonic Applications
520 _aTremendous innovations in electronics and photonics over the past few decades have resulted in the downsizing of transistors in integrated circuits, which are now approaching atomic scales. This will soon result in the creation of a growing knowledge gap between the underlying technology and state-of-the-art electronic device modeling and simulations. This book bridges the gap by presenting cutting-edge research in the computational analysis and mathematical modeling of graphene nanostructures as well as the recent progress on graphene transistors for nanoscale circuits. It inspires and educates fellow circuit designers and students in the field of emerging low-power and high-performance circuit designs based on graphene. While most of the books focus on the synthesis, fabrication, and characterization of graphene, this book shines a light on graphene models and their circuit simulations and applications in photonics. It will serve as a textbook for graduate-level courses in nanoscale electronics and photonics design and appeal to anyone involved in electrical engineering, applied physics, materials science, or nanotechnology research.
588 _aOCLC-licensed vendor bibliographic record.
650 0 _aGraphene.
_96450
650 0 _aNanostructures.
_95928
650 0 _aNanoelectromechanical systems.
_913758
650 7 _aSCIENCE / Life Sciences / General
_2bisacsh
_914901
650 7 _aTECHNOLOGY / Electronics / General
_2bisacsh
_910793
650 7 _aTECHNOLOGY / Nanotechnology
_2bisacsh
_912200
700 1 _aSharifi, Safura,
_eauthor.
_914902
856 4 0 _3Taylor & Francis
_uhttps://www.taylorfrancis.com/books/9780429022210
856 4 2 _3OCLC metadata license agreement
_uhttp://www.oclc.org/content/dam/oclc/forms/terms/vbrl-201703.pdf
942 _cEBK
999 _c70826
_d70826