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Intelligent nanomaterials : processes, properties, and applications / / edited by Ashutosh Tiwari ... [et al.]
Intelligent nanomaterials : processes, properties, and applications / / edited by Ashutosh Tiwari ... [et al.]
Edizione [1st ed.]
Pubbl/distr/stampa Hoboken, NJ, : John Wiley & Sons
Descrizione fisica 1 online resource (866 p.)
Disciplina 620.1/15
Altri autori (Persone) TiwariAshutosh <1978->
Soggetto topico Nanostructured materials
Smart materials
ISBN 1-280-67478-4
9786613651716
1-118-31196-5
1-61344-891-0
1-118-31197-3
1-118-31194-9
Classificazione TEC021000
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Intelligent Nanomaterials: Processes, Properties, and Applications; Contents; Preface; PART I Inorganic Materials; 1. Synthesis, Characterization, and Self-assembly of Colloidal Quantum Dots; 1.1 Introduction; 1.2 Size-dependent Optical Properties of Quantum Dots; 1.2.1 Band Gap Energies; 1.2.2 Absorption Spectra; 1.3 Procedures for Synthesis of Colloidal Quantum Dots; 1.3.1 Synthesis of Quantum Dots in Reverse Micelles; 1.3.2 Synthesis of Quantum Dots in Aqueous Media; 1.3.3 Hot-matrix Synthesis of Quantum Dots; 1.4 Types of Semiconductor Quantum Dots; 1.4.1 Binary Quantum Dots
1.4.2 Alloyed Quantum Dots1.4.3 Core/shell Quantum Dots: ""Type-I""; 1.4.4 Core/shell Quantum Dots: ""Type-II""; 1.4.5 Quantum Dot/quantum Well Nanocrystals; 1.4.6 Transition-element-doped Quantum Dots; 1.5 Surface Functionalization of Quantum Dots; 1.5.1 Self-assembly of Colloidal Quantum Dots; 1.6 Conclusions; References; 2. One-dimensional Semiconducting Metal Oxides: Synthesis, Characterization and Gas Sensors Application; 2.1 Introduction; 2.2 Synthesis of 1-D Metal Oxide; 2.2.1 Vapor Phase Growth; 2.2.2 Vapor-liquid-solid Mechanism; 2.2.3 Vapor Solid Mechanism; 2.3 Solution Phase Growth
2.3.1 Template Assisted Synthesis2.3.2 Template Free Synthesis; 2.4 Gas Sensor Applications; 2.4.1 SnO2 NWs Based Gas Sensors; 2.4.2 WO3 NWs Based Gas Sensors; 2.4.3 ZnO NWs Based Gas Sensors; 2.4.4 TiO2 NWs Based Gas Sensor; 2.4.5 CuO NWs Based Gas Sensors; 2.4.6 In2O3 NWs Based Gas Sensors; 2.5 Conclusions; Acknowledgement; References; 3. Rare-earth Based Insulating Nanocrystals: Improved Luminescent Nanophosphors for Plasma Display Panels; 3.1 What is Plasma Display Panel? An Introduction and Overview; 3.2 History of Plasma Display Panel; 3.3 Working of Plasma Display Panel
3.3.1 Advantages of Plasma Display Panel3.3.2 Disadvantages of Plasma Display Panel; 3.4 Nanophosphors for Plasma Display Panel; 3.4.1 Blue Nanophosphors; 3.5 Synthesis of BAM:Eu2+ Nanophosphors by Sol-gel Method; 3.5.1 Chemicals Used; 3.5.2 Methodology; 3.5.3 Characterization of Prepared Nanophosphors; 3.5.4 Results and Discussion; 3.6 Time Evolution Studies and Decay Time Determination; 3.7 Synthesis of BAM:Eu2+ Nanophosphors by Solution Combustion Method; 3.7.1 Chemicals Used; 3.7.2 Methodology; 3.7.3 Characterization of Prepared Nanophosphors; 3.7.4 Results and Discussion
3.8 Green Nanophosphors3.8.1 Yttrium Aluminum Garnet Y3Al5O12:Tb3+ (YAG:Tb3+) Nanophosphors; 3.8.2 Synthesis of Y3Al5O12:Tb3+ (YAG:Tb3+) Nanophosphors by Sol-gel Method; 3.8.3 Chemicals Used; 3.8.4 Methodology; 3.8.5 Characterization of Prepared Y3Al5O12:Tb3+ (YAG:Tb3+) Nanophosphors; 3.8.6 Results and Discussion; 3.9 Terbium Doped Yttrium Ortho-borate (YBO3:Tb3+) Nanophosphors; 3.9.1 Synthesis of Terbium Doped Yttrium Ortho-borate (YBO3:Tb3+) Nanophosphors; 3.9.2 Chemicals Used; 3.9.3 Methodology; 3.9.4 Characterizations Used; 3.9.5 Result and Discussion
3.10 Red Nanophosphors: Yttrium Aluminum Garnet Y3AlO12:Eu3+ (YAG:Eu3+) Nanophosphors
Record Nr. UNINA-9910810303203321
Hoboken, NJ, : John Wiley & Sons
Materiale a stampa
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Intelligent stimuli-responsive materials : from well-defined nanostructures to applications / / edited by Quan Li
Intelligent stimuli-responsive materials : from well-defined nanostructures to applications / / edited by Quan Li
Pubbl/distr/stampa Hoboken, New Jersey : , : Wiley, , [2013]
Descrizione fisica 1 online resource (499 p.)
Disciplina 620.1/1
Altri autori (Persone) LiQuan <1965->
Soggetto topico Smart materials
ISBN 1-118-68046-4
1-118-68051-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto INTELLIGENT STIMULI-RESPONSIVE MATERIALS; CONTENTS; PREFACE; CONTRIBUTORS; 1 NATURE-INSPIRED STIMULI-RESPONSIVE SELF-FOLDING MATERIALS; 1.1 INTRODUCTION; 1.2 DESIGN OF SELF-FOLDING FILMS; 1.3 MECHANISM OF FOLDING; 1.4 FABRICATION OF SELF-FOLDING FILMS; 1.5 STIMULI-RESPONSIVE PROPERTIES OF SELF-FOLDING FILMS; 1.5.1 pH Responsive; 1.5.2 Thermoresponsive; 1.5.3 Light Responsive; 1.5.4 Solvent Responsive; 1.5.5 Other Stimuli; 1.6 PROPERTIES AND APPLICATIONS OF SELF-FOLDING FILMS; 1.7 CONCLUSIONS AND OUTLOOK; REFERENCES
2 STIMULI-RESPONSIVE NANOSTRUCTURES FROM SELF-ASSEMBLY OF RIGID-FLEXIBLE BLOCK MOLECULES2.1 INTRODUCTION; 2.2 THERMAL-RESPONSIVE NANOSTRUCTURES; 2.2.1 Pulsating Tubules from Non-Covalent Macrocycles; 2.2.2 Stimuli-Responsive Gels from T-Shaped Molecules; 2.2.3 Supramolecular Springs; 2.2.4 Structural Changes of Nanorings and Porous Nanostructures; 2.2.5 Aqueous Nanofibers with Switchable Chirality; 2.2.6 Switching between Helical Coils and Straight Rods; 2.2.7 Dynamic Nanostructures from Laterally Grafted Rod Amphiphiles
2.2.8 Responsive Nematic Gels from the Self-assembly of Aqueous Nanofibers2.3 GUEST MOLECULE-RESPONSIVE NANOSTRUCTURE; 2.3.1 Reversible Conformational Changes in Helical Structures; 2.3.2 Reversible Interconversion of Helical Fibers into Nanocapsules; 2.3.3 Transformation of Single Nanofibers to Flat Ribbons; 2.3.4 Interconversion between Toroid and Stacked Helical Structure; 2.3.5 Reversible Relation of Supramolecular Nanocylinders; 2.3.6 Carbohydrate-Coated Nanostructures; 2.4 OTHER STIMULI-RESPONSIVE NANOSTRUCTURES; 2.5 CONCLUSION; REFERENCES
3 STIMULI-DIRECTED ALIGNMENT CONTROL OF SEMICONDUCTING DISCOTIC LIQUID CRYSTALLINE NANOSTRUCTURES3.1 INTRODUCTION; 3.2 ALIGNMENT OF DISCOTIC LIQUID CRYSTALS; 3.3 ALIGNMENT OF DISCOTIC NEMATIC LIQUID CRYSTAL PHASE; 3.4 ALIGNMENT CONTROL OF COLUMNAR PHASE WITH DIFFERENT STIMULI; 3.4.1 Thermal Alignment; 3.4.2 Zone Casting; 3.4.3 Zone Melting; 3.4.4 Langmuir-Blodgett Technique; 3.4.5 Magnetic-Field-Induced Alignment; 3.4.6 Electric-Field-Induced Alignment; 3.4.7 Photoalignment by Infrared Irradiation; 3.4.8 Chemical Structure Modifications for Alignment
3.4.9 Polytetrafluoroethylene Alignment Layer3.4.10 Use of Chemically Modified Surfaces and Dewetting; 3.4.11 Use of Sacrificial Layer; 3.4.12 Dip Coating and Solvent Vapor Annealing; 3.4.13 Other Alignment Techniques; 3.4.14 Alignment in Nanopores and Nanogrooves; 3.5 CONCLUSIONS AND OUTLOOK; ACKNOWLEDGMENTS; REFERENCES; 4 ANION-DRIVEN SUPRAMOLECULAR SELF-ASSEMBLED MATERIALS; 4.1 INTRODUCTION; 4.2 ANION-DRIVEN FORMATION OF SUPRAMOLECULAR GELS; 4.3 SUPRAMOLECULAR GELS BASED ON PLANAR-CHARGED SPECIES; 4.4 MESOPHASES COMPRISING PLANAR-CHARGED SPECIES; 4.5 SUMMARY; REFERENCES
5 PHOTORESPONSIVE CHOLESTERIC LIQUID CRYSTALS
Record Nr. UNINA-9910139022503321
Hoboken, New Jersey : , : Wiley, , [2013]
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Intelligent stimuli-responsive materials : from well-defined nanostructures to applications / / edited by Quan Li
Intelligent stimuli-responsive materials : from well-defined nanostructures to applications / / edited by Quan Li
Pubbl/distr/stampa Hoboken, New Jersey : , : Wiley, , [2013]
Descrizione fisica 1 online resource (499 p.)
Disciplina 620.1/1
Altri autori (Persone) LiQuan <1965->
Soggetto topico Smart materials
ISBN 1-118-68046-4
1-118-68051-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto INTELLIGENT STIMULI-RESPONSIVE MATERIALS; CONTENTS; PREFACE; CONTRIBUTORS; 1 NATURE-INSPIRED STIMULI-RESPONSIVE SELF-FOLDING MATERIALS; 1.1 INTRODUCTION; 1.2 DESIGN OF SELF-FOLDING FILMS; 1.3 MECHANISM OF FOLDING; 1.4 FABRICATION OF SELF-FOLDING FILMS; 1.5 STIMULI-RESPONSIVE PROPERTIES OF SELF-FOLDING FILMS; 1.5.1 pH Responsive; 1.5.2 Thermoresponsive; 1.5.3 Light Responsive; 1.5.4 Solvent Responsive; 1.5.5 Other Stimuli; 1.6 PROPERTIES AND APPLICATIONS OF SELF-FOLDING FILMS; 1.7 CONCLUSIONS AND OUTLOOK; REFERENCES
2 STIMULI-RESPONSIVE NANOSTRUCTURES FROM SELF-ASSEMBLY OF RIGID-FLEXIBLE BLOCK MOLECULES2.1 INTRODUCTION; 2.2 THERMAL-RESPONSIVE NANOSTRUCTURES; 2.2.1 Pulsating Tubules from Non-Covalent Macrocycles; 2.2.2 Stimuli-Responsive Gels from T-Shaped Molecules; 2.2.3 Supramolecular Springs; 2.2.4 Structural Changes of Nanorings and Porous Nanostructures; 2.2.5 Aqueous Nanofibers with Switchable Chirality; 2.2.6 Switching between Helical Coils and Straight Rods; 2.2.7 Dynamic Nanostructures from Laterally Grafted Rod Amphiphiles
2.2.8 Responsive Nematic Gels from the Self-assembly of Aqueous Nanofibers2.3 GUEST MOLECULE-RESPONSIVE NANOSTRUCTURE; 2.3.1 Reversible Conformational Changes in Helical Structures; 2.3.2 Reversible Interconversion of Helical Fibers into Nanocapsules; 2.3.3 Transformation of Single Nanofibers to Flat Ribbons; 2.3.4 Interconversion between Toroid and Stacked Helical Structure; 2.3.5 Reversible Relation of Supramolecular Nanocylinders; 2.3.6 Carbohydrate-Coated Nanostructures; 2.4 OTHER STIMULI-RESPONSIVE NANOSTRUCTURES; 2.5 CONCLUSION; REFERENCES
3 STIMULI-DIRECTED ALIGNMENT CONTROL OF SEMICONDUCTING DISCOTIC LIQUID CRYSTALLINE NANOSTRUCTURES3.1 INTRODUCTION; 3.2 ALIGNMENT OF DISCOTIC LIQUID CRYSTALS; 3.3 ALIGNMENT OF DISCOTIC NEMATIC LIQUID CRYSTAL PHASE; 3.4 ALIGNMENT CONTROL OF COLUMNAR PHASE WITH DIFFERENT STIMULI; 3.4.1 Thermal Alignment; 3.4.2 Zone Casting; 3.4.3 Zone Melting; 3.4.4 Langmuir-Blodgett Technique; 3.4.5 Magnetic-Field-Induced Alignment; 3.4.6 Electric-Field-Induced Alignment; 3.4.7 Photoalignment by Infrared Irradiation; 3.4.8 Chemical Structure Modifications for Alignment
3.4.9 Polytetrafluoroethylene Alignment Layer3.4.10 Use of Chemically Modified Surfaces and Dewetting; 3.4.11 Use of Sacrificial Layer; 3.4.12 Dip Coating and Solvent Vapor Annealing; 3.4.13 Other Alignment Techniques; 3.4.14 Alignment in Nanopores and Nanogrooves; 3.5 CONCLUSIONS AND OUTLOOK; ACKNOWLEDGMENTS; REFERENCES; 4 ANION-DRIVEN SUPRAMOLECULAR SELF-ASSEMBLED MATERIALS; 4.1 INTRODUCTION; 4.2 ANION-DRIVEN FORMATION OF SUPRAMOLECULAR GELS; 4.3 SUPRAMOLECULAR GELS BASED ON PLANAR-CHARGED SPECIES; 4.4 MESOPHASES COMPRISING PLANAR-CHARGED SPECIES; 4.5 SUMMARY; REFERENCES
5 PHOTORESPONSIVE CHOLESTERIC LIQUID CRYSTALS
Record Nr. UNINA-9910816798903321
Hoboken, New Jersey : , : Wiley, , [2013]
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Intelligent Surfaces Empowered 6G Wireless Network / / edited by Qingqing Wu [and four others]
Intelligent Surfaces Empowered 6G Wireless Network / / edited by Qingqing Wu [and four others]
Edizione [First edition.]
Pubbl/distr/stampa Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2024]
Descrizione fisica 1 online resource (365 pages)
Disciplina 621.38456
Soggetto topico 6G mobile communication systems
Smart materials
Surfaces (Technology)
ISBN 1-119-91310-1
1-119-91312-8
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Cover -- Title Page -- Copyright -- Contents -- About the Editors -- List of Contributors -- Preface -- Acknowledgement -- Part I Fundamentals of IRS -- Chapter 1 Introduction to Intelligent Surfaces -- 1.1 Background -- 1.2 Concept of Intelligent Surfaces -- 1.3 Advantages of Intelligence Surface -- 1.4 Potential Applications -- 1.5 Conclusion -- Bibliography -- Chapter 2 IRS Architecture and Hardware Design -- 2.1 Metamaterials: Basics of IRS -- 2.2 Programmable Metasurfaces -- 2.3 IRS Hardware Design -- 2.3.1 IRS System Architecture -- 2.3.2 IRS Element Design -- 2.3.3 IRS Array Design -- 2.3.4 IRS Controller Design -- 2.3.5 Full‐Wave Simulation and Field Test -- 2.4 State‐of‐the‐Art IRS Prototype -- 2.4.1 Passive IRS Prototype by Tsinghua -- 2.4.2 Active IRS Prototype by Tsinghua -- 2.4.3 IRS Modulation Prototype by SEU -- 2.4.3.1 Transmitter Design -- 2.4.3.2 Frame Structure Design -- 2.4.3.3 Receiver Design -- 2.4.3.4 System Design -- 2.4.4 Transmissive IRS Prototype by MIT -- 2.4.5 IRS Prototype by China Mobile -- 2.4.6 IRS Prototype by DOCOMO -- Bibliography -- Chapter 3 On Path Loss and Channel Reciprocity of RIS‐Assisted Wireless Communications -- 3.1 Introduction -- 3.2 Path Loss Modeling and Channel Reciprocity Analysis -- 3.2.1 System Description -- 3.2.2 General Path Loss Model -- 3.2.3 Path Loss Models for Typical Scenarios -- 3.2.4 Discussion on RIS Path Loss and Channel Reciprocity -- 3.3 Path Loss Measurement and Channel Reciprocity Validation -- 3.3.1 Two Fabricated RISs -- 3.3.2 Two Measurement Systems -- 3.3.3 Validation of RIS Path Loss Models -- 3.3.4 Validation of RIS Channel Reciprocity -- 3.4 Conclusion -- 3.A Appendix -- 3.A.1 Proof of Theorem 3.1 -- Bibliography -- Chapter 4 Intelligent Surface Communication Design: Main Challenges and Solutions -- 4.1 Introduction -- 4.2 Channel Estimation.
4.2.1 Problem Description and Challenges -- 4.2.2 Semi‐Passive IRS Channel Estimation -- 4.2.3 Fully‐Passive IRS Channel Estimation -- 4.3 Passive Beamforming Optimization -- 4.3.1 IRS‐aided SISO System: Passive Beamforming Basics and Power Scaling Order -- 4.3.2 IRS‐aided MISO System: Joint Active and Passive Beamforming -- 4.3.3 IRS‐Aided MIMO System -- 4.3.4 IRS‐Aided OFDM System -- 4.3.5 Passive Beamforming with Discrete Reflection Amplitude and Phase Shift -- 4.3.6 Other Related Works and Future Directions -- 4.4 IRS Deployment -- 4.4.1 IRS Deployment Optimization at the Link Level -- 4.4.1.1 Optimal Deployment of Single IRS -- 4.4.1.2 Single IRS versus Multiple Cooperative IRSs -- 4.4.1.3 LoS versus Non‐LoS (NLoS) -- 4.4.2 IRS Deployment at the Network Level: Distributed or Centralized? -- 4.4.3 Other Related Work and Future Direction -- 4.5 Conclusion -- Bibliography -- Part II IRS for 6G Wireless Systems -- Chapter 5 Overview of IRS for 6G and Industry Advance -- 5.1 IRS for 6G -- 5.1.1 Potential Use Cases -- 5.1.1.1 Indoor Use Cases -- 5.1.1.2 Outdoor Use Cases -- 5.1.2 Deployment Scenarios -- 5.2 Industrial Progresses -- 5.2.1 Funded Projects -- 5.2.2 White Papers -- 5.2.3 Prototyping and Testing -- 5.2.4 Standardization Progress -- Bibliography -- Chapter 6 RIS‐Aided Massive MIMO Antennas* -- 6.1 Introduction -- 6.1.0 Notation -- 6.2 System Model -- 6.2.1 Channel Model -- 6.2.2 Active Antenna Configuration -- 6.3 Uplink/Downlink Signal Processing -- 6.3.1 Uplink Channel Estimation -- 6.3.2 Downlink Data Transmission -- 6.4 Performance Measures -- 6.4.1 SINR and Spectral Efficiency under Perfect Channel State Information (CSI) -- 6.4.2 SINR and Spectral Efficiency under Imperfect Channel State Information (CSI) -- 6.4.2.1 The Upper‐Bound (UB) to the System Performance -- 6.4.2.2 The Hardening Lower‐Bound (LB) to System Performance.
6.5 Optimization of the RIS Phase Shifts -- 6.6 Numerical Results -- 6.7 Conclusions -- 6.A Appendix -- Bibliography -- Chapter 7 Localization, Sensing, and Their Integration with RISs -- 7.1 Introduction -- 7.1.1 Localization in 5G -- 7.1.2 RIS Key Advantages -- 7.1.2.1 Localization -- 7.1.2.2 Sensing -- 7.2 RIS Types and Channel Modeling -- 7.2.1 RIS Hardware Architectures -- 7.2.2 RIS‐Parameterized Channel Models -- 7.2.2.1 Geometric Channel Model -- 7.2.2.2 Stochastic Channel Modeling -- 7.3 Localization with RISs -- 7.3.1 Fundamentals on Localization -- 7.3.2 Localization with Reflective RISs -- 7.3.3 Localization with a Single STAR‐RIS -- 7.3.4 Localization with Multiple Receiving RISs -- 7.4 Sensing with RISs -- 7.4.1 Link Budget Analysis -- 7.4.1.1 Monostatic Radar Sensing -- 7.4.1.2 Bistatic Radar Sensing -- 7.4.2 Joint Sensing and Localization with a Single RIS -- 7.4.2.0 UE and Landmark Estimates -- 7.5 Conclusion and Open Challenges -- Bibliography -- Chapter 8 IRS‐Aided THz Communications -- 8.1 IRS‐Aided THz MIMO System Model -- 8.2 Beam Training Protocol -- 8.3 IRS Prototyping -- 8.3.1 Active Beam Steering at THz transceivers -- 8.3.2 Passive Beam Steering on THz IRS -- 8.3.3 Codebook Design for Beam Scanning -- 8.3.4 Beam‐Scanning Reflectarray -- 8.4 IRS‐THz Communication Applications -- 8.4.1 High Speed Fronthaul/Backhaul -- 8.4.2 Cellular Connected Drones -- 8.4.3 Wireless Data Center -- 8.4.4 Enhanced Indoor Coverage -- 8.4.5 Vehicular Communications -- 8.4.6 Physical‐Layer Security -- Bibliography -- Chapter 9 Joint Design of Beamforming, Phase Shifting, and Power Allocation in a Multi‐cluster IRS‐NOMA Network -- 9.1 Introduction -- 9.1.1 Previous Works -- 9.1.2 Motivation and Challenge -- 9.2 System Model and Problem Formulation -- 9.2.1 System Model -- 9.2.2 Problem Formulation -- 9.3 Alternating Algorithm.
9.3.1 Beamforming Optimization -- 9.3.2 Phase‐Shift Feasibility -- 9.3.3 Algorithm Design -- 9.4 Simulation Result -- 9.5 Conclusion -- Bibliography -- Chapter 10 IRS‐Aided Mobile Edge Computing: From Optimization to Learning -- 10.1 Introduction -- 10.2 System Model and Objective -- 10.3 Optimization‐Based Approaches to IRS‐Aided MEC -- 10.3.1 IRS Reflecting Coefficients Design -- 10.3.2 Receive Beamforming Design -- 10.3.3 Energy Partition Optimization -- 10.3.4 Convergence and Complexity -- 10.4 Deep Learning Approaches to IRS‐Aided MEC -- 10.4.1 CSI‐Based Learning Architecture -- 10.4.2 Location‐Only Learning Architecture -- 10.4.3 Input Feature Uncertainty -- 10.4.4 Comparison Between the CSI‐Based and CSI‐Free Learning Architectures -- 10.4.5 Complexity Reduction via Learning -- 10.5 Comparative Evaluation Results -- 10.5.1 Scenario Without LoS Direct Links -- 10.5.2 Scenario with Strong LoS Direct Links -- 10.6 Conclusions -- Bibliography -- Chapter 11 Interference Nulling Using Reconfigurable Intelligent Surface -- 11.1 Introduction -- 11.2 System Model -- 11.3 Interference Nulling via RIS -- 11.3.1 Feasibility of Interference Nulling -- 11.3.2 Alternating Projection Algorithm -- 11.3.3 Simulation Results -- 11.4 Learning to Minimize Interference -- 11.4.1 Learning to Initialize -- 11.4.2 Simulation Results -- 11.5 Conclusions -- Bibliography -- Chapter 12 Blind Beamforming for IRS Without Channel Estimation -- 12.1 Introduction -- 12.2 System Model -- 12.3 Random‐Max Sampling (RMS) -- 12.4 Conditional Sample Mean (CSM) -- 12.5 Some Comments on CSM -- 12.5.1 Connection to Closest Point Projection -- 12.5.2 Connection to Phase Retrieval -- 12.5.3 CSM for General Utility Functions -- 12.6 Field Tests -- 12.7 Conclusion -- Bibliography -- Chapter 13 RIS in Wireless Information and Power Transfer -- 13.1 Introduction -- 13.1.1 WPT and WIPT.
13.1.2 RIS -- 13.1.3 RIS in WPT and WIPT -- 13.2 RIS‐Aided WPT -- 13.2.1 WPT Architecture -- 13.2.2 Waveform and Beamforming -- 13.2.3 Channel Acquisition -- 13.2.3.1 Direct Channel -- 13.2.3.2 RIS‐Related Channels -- 13.2.4 Prototype and Experiments -- 13.3 RIS‐Aided WIPT -- 13.3.1 WIPT Categories -- 13.3.2 RIS‐Aided SWIPT -- 13.3.2.1 SWIPT Architecture -- 13.3.2.2 Waveform and Beamforming -- 13.3.2.3 Channel Acquisition -- 13.3.3 RIS‐Aided WPCN and WPBC -- 13.4 Conclusion -- Bibliography -- Chapter 14 Beamforming Design for Self‐Sustainable IRS‐Assisted MISO Downlink Systems -- 14.1 Introduction -- 14.2 System Model -- 14.2.1 Self‐Sustainable IRS Model -- 14.2.2 Channel and Signal Models -- 14.2.3 Power Harvesting Model at the IRS -- 14.3 Problem Formulation -- 14.4 Solution -- 14.4.1 Problem Transformation -- 14.4.2 Address the Coupling Variables and Binary Variables -- 14.4.3 Successive Convex Approximation -- 14.5 Numerical Results -- 14.6 Summary -- 14.7 Further Extension -- Bibliography -- Chapter 15 Optical Intelligent Reflecting Surfaces -- 15.1 Introduction -- 15.2 System and Channel Model -- 15.2.1 IRS Model -- 15.2.2 Transmitter and Receiver Model -- 15.2.3 Channel Model -- 15.3 Communication Theoretical Modeling of Optical IRSs -- 15.3.1 Scattering Theory -- 15.3.1.1 Incident Beam on the IRS -- 15.3.1.2 Huygens-Fresnel Principle -- 15.3.1.3 Intermediate‐Field Versus Far‐Field -- 15.3.1.4 Received Power Density -- 15.3.2 Geometric Optics -- 15.3.2.1 Equivalent Mirror‐Assisted Analysis -- 15.3.2.2 Received Power Density -- 15.4 Design of Optical IRSs for FSO Systems -- 15.4.1 IRS‐Assisted Point‐to‐Point System -- 15.4.1.1 IRS Phase‐Shift Profile Φ(r,rt) -- 15.4.1.2 IRS Efficiency ζ -- 15.4.2 IRS‐Assisted Multi‐Link System -- 15.4.2.1 Time Division Protocol -- 15.4.2.2 IRS Division Protocol -- 15.4.2.3 IRS Homogenization Protocol.
15.5 Simulation Results.
Record Nr. UNINA-9910830726203321
Hoboken, New Jersey : , : John Wiley & Sons, Inc., , [2024]
Materiale a stampa
Lo trovi qui: Univ. Federico II
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Intelligent surfaces in biotechnology [[electronic resource] ] : scientific and engineering concepts, enabling technologies, and translation to bio-oriented applications / / edited by Marcus Textor, H. Michelle Grandin
Intelligent surfaces in biotechnology [[electronic resource] ] : scientific and engineering concepts, enabling technologies, and translation to bio-oriented applications / / edited by Marcus Textor, H. Michelle Grandin
Pubbl/distr/stampa Hoboken, N.J., : John Wiley & Sons, c2012
Descrizione fisica 1 online resource (428 p.)
Disciplina 610.28/4
Altri autori (Persone) TextorMarcus
GrandinH. Michelle
Soggetto topico Biomedical materials
Biotechnology - Materials
Smart materials
Surfaces (Technology)
ISBN 1-280-59096-3
9786613620798
1-118-18123-9
1-118-18124-7
1-118-18121-2
Classificazione TEC021000
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Machine generated contents note: Chapter 1. Stimulus Responsive Polymers as Intelligent Coatings for Biosensors: Architectures, Response Mechanisms, and Applications Vinalia Tjong, Jianming Zhang, Ashutosh Chilkoti and Stefan Zauscher 1.1 Introduction 1.2 SRP Architectures for Biosensor Applications 1.3 Mechanisms of Response 1.4 Sensing and Transduction Mechanisms 1.5 Limitations and Challenges 1.6 Conclusion and Outlook Chapter 2. Smart Surfaces for Point-of-Care Diagnostics Michael A. Nash, Allison L. Golden, John M. Hoffman, James L. Lai, and Patrick S. Stayton 2.1 Introduction 2.2 Standard Methods for Biomarker Purification, Enrichment, and Detection 2.3 Smart Reagents for Biomarker Purification and Processing 2.4 Sample-Processing Modules for Smart Conjugate Bioassays 2.5 Devices for use in Smart Conjugate Bioassays 2.6 Conclusions Chapter 3. Design of intelligent surface modifications and optimal liquid handling for nanoscale bioanalytical sensors Laurent Feuz, Fredrik Höök and Erik Reimhult 3.1 Introduction 3.2 Orthogonal small (nano) scale surface modification using molecular self-assembly 3.3 Alternative surface patterning strategies 3.4 The challenge of analytic transport 3.5 Concluding remarks Chapter 4. Intelligent Surfaces for Field Effect Transistor Based Nano-biosensing Akira Matsumoto, Yuji Miyahara Kazunori Kataoka 4.1 Introduction 4.2 Field effect transistor based biosensors 4.3 Intelligent surfaces for signal transduction and amplification of Bio-FETs 4.4 New targets of Bio-FETs 4.5 Future Perspective Chapter 5. Supported lipid bilayers: intelligent surfaces for ion channel recordings Andreas Janshoff and Claudia Steinem 5.1 Introduction 5.2 Supported lipid bilayers 5.3 Characterizatics of SSMs 5.4 Ion channels in SSMs 5.5 Future perspective: Ion channels in micropatterned membranes Chapter 6. Antimicrobial and anti-inflammatory intelligent surfaces Hans J. Griesser, Heike Hall. A. Toby , A. Jenkins, Stegani S. Griesser, Krasimir Vasilev 6.1 Introduction 6.2 Antibacterial strategies 6.3 Bioactive antibacterial surfaces 6.4 Stimulus-responsive antibacterial coatings for wound dressings 6.5 Anti-inflammatory surfaces 6.6 Conclusions and Outlook Chapter 7. Intelligent Polymer Thin Films and Coatings for Drug Delivery Alexander N. Zelikin, Brigitte Stadler 7.1 Introduction 7.2 Surface Mediated Drug Delivery 7.3 Drug Delivery Vehicles With Functional Polymer Coatings 7.4 Outlook Chapter 8. Micro- and Nanopatterning of Active Biomolecules and Cells Daniel Aydin, Vera C. Hirschfeld-Warmeken, Ilia Louban and Joachim P. Spatz 8.1 Introduction 8.2 Chemical Approaches for Protein Immobilization 8.3 Biomolecule patterning by "top-down" techniques 8.4 Biomolecule Nanoarrays bu Block Copolymer Nanolithography 8.5 Application of Nanostructured Surfaces to Study Cell Adhesion 8.6 Conclusion Chapter 9. Responsive polymer coatings for smart applications in chromatography, drug delivery systems and cell sheet engineering Rogerio P. Pirraco, Masayuki Yamato, Yoshikatsu, Kenichi Nagase, Masamichi Nakayama, Alexandra P. Marques, Rui L. Reis and Teruo Okano 9.1 Introduction 9.2 Temperature-responsive chromatography 9.3 Temperature-responsive polymer micelle 9.4 Temperature-responsive culture surfaces 9.5 Cell sheet Engineering 9.6 Conclusions.
Record Nr. UNINA-9910139704103321
Hoboken, N.J., : John Wiley & Sons, c2012
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Intelligent surfaces in biotechnology : scientific and engineering concepts, enabling technologies, and translation to bio-oriented applications / / edited by Marcus Textor, H. Michelle Grandin
Intelligent surfaces in biotechnology : scientific and engineering concepts, enabling technologies, and translation to bio-oriented applications / / edited by Marcus Textor, H. Michelle Grandin
Edizione [1st ed.]
Pubbl/distr/stampa Hoboken, N.J., : John Wiley & Sons, c2012
Descrizione fisica 1 online resource (428 p.)
Disciplina 610.28/4
Altri autori (Persone) TextorMarcus
GrandinH. Michelle
Soggetto topico Biomedical materials
Biotechnology - Materials
Smart materials
Surfaces (Technology)
ISBN 1-280-59096-3
9786613620798
1-118-18123-9
1-118-18124-7
1-118-18121-2
Classificazione TEC021000
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Machine generated contents note: Chapter 1. Stimulus Responsive Polymers as Intelligent Coatings for Biosensors: Architectures, Response Mechanisms, and Applications Vinalia Tjong, Jianming Zhang, Ashutosh Chilkoti and Stefan Zauscher 1.1 Introduction 1.2 SRP Architectures for Biosensor Applications 1.3 Mechanisms of Response 1.4 Sensing and Transduction Mechanisms 1.5 Limitations and Challenges 1.6 Conclusion and Outlook Chapter 2. Smart Surfaces for Point-of-Care Diagnostics Michael A. Nash, Allison L. Golden, John M. Hoffman, James L. Lai, and Patrick S. Stayton 2.1 Introduction 2.2 Standard Methods for Biomarker Purification, Enrichment, and Detection 2.3 Smart Reagents for Biomarker Purification and Processing 2.4 Sample-Processing Modules for Smart Conjugate Bioassays 2.5 Devices for use in Smart Conjugate Bioassays 2.6 Conclusions Chapter 3. Design of intelligent surface modifications and optimal liquid handling for nanoscale bioanalytical sensors Laurent Feuz, Fredrik Höök and Erik Reimhult 3.1 Introduction 3.2 Orthogonal small (nano) scale surface modification using molecular self-assembly 3.3 Alternative surface patterning strategies 3.4 The challenge of analytic transport 3.5 Concluding remarks Chapter 4. Intelligent Surfaces for Field Effect Transistor Based Nano-biosensing Akira Matsumoto, Yuji Miyahara Kazunori Kataoka 4.1 Introduction 4.2 Field effect transistor based biosensors 4.3 Intelligent surfaces for signal transduction and amplification of Bio-FETs 4.4 New targets of Bio-FETs 4.5 Future Perspective Chapter 5. Supported lipid bilayers: intelligent surfaces for ion channel recordings Andreas Janshoff and Claudia Steinem 5.1 Introduction 5.2 Supported lipid bilayers 5.3 Characterizatics of SSMs 5.4 Ion channels in SSMs 5.5 Future perspective: Ion channels in micropatterned membranes Chapter 6. Antimicrobial and anti-inflammatory intelligent surfaces Hans J. Griesser, Heike Hall. A. Toby , A. Jenkins, Stegani S. Griesser, Krasimir Vasilev 6.1 Introduction 6.2 Antibacterial strategies 6.3 Bioactive antibacterial surfaces 6.4 Stimulus-responsive antibacterial coatings for wound dressings 6.5 Anti-inflammatory surfaces 6.6 Conclusions and Outlook Chapter 7. Intelligent Polymer Thin Films and Coatings for Drug Delivery Alexander N. Zelikin, Brigitte Stadler 7.1 Introduction 7.2 Surface Mediated Drug Delivery 7.3 Drug Delivery Vehicles With Functional Polymer Coatings 7.4 Outlook Chapter 8. Micro- and Nanopatterning of Active Biomolecules and Cells Daniel Aydin, Vera C. Hirschfeld-Warmeken, Ilia Louban and Joachim P. Spatz 8.1 Introduction 8.2 Chemical Approaches for Protein Immobilization 8.3 Biomolecule patterning by "top-down" techniques 8.4 Biomolecule Nanoarrays bu Block Copolymer Nanolithography 8.5 Application of Nanostructured Surfaces to Study Cell Adhesion 8.6 Conclusion Chapter 9. Responsive polymer coatings for smart applications in chromatography, drug delivery systems and cell sheet engineering Rogerio P. Pirraco, Masayuki Yamato, Yoshikatsu, Kenichi Nagase, Masamichi Nakayama, Alexandra P. Marques, Rui L. Reis and Teruo Okano 9.1 Introduction 9.2 Temperature-responsive chromatography 9.3 Temperature-responsive polymer micelle 9.4 Temperature-responsive culture surfaces 9.5 Cell sheet Engineering 9.6 Conclusions.
Record Nr. UNINA-9910810218303321
Hoboken, N.J., : John Wiley & Sons, c2012
Materiale a stampa
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Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Pubbl/distr/stampa Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Descrizione fisica 1 online resource (160 p.)
Disciplina 677.68
Altri autori (Persone) JayaramanSundaresan
KiekensPaul <1955->
GrancaricAna Marija
Collana NATO security through science series. D, Information and communication security
Soggetto topico Protective clothing
Smart materials
Soggetto genere / forma Electronic books.
ISBN 6610505284
1-280-50528-1
9786610505289
1-4237-9747-7
1-60750-166-X
600-00-0464-8
1-60129-145-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Title page; Preface; Content; Advanced Research Workshop on Intelligent Textiles for Personal Protection and Safety; Intelligent Textiles for Personal Protection and Safety: The Emerging Discipline; The Wearable Motherboard: The New Class of Adaptive and Responsive Textile Structures; New Textile Materials for Environmental Protection; Wearable Mechanosensing and Emerging Technologies in Fabric-Based Actuation; Flexible Displays on Textiles for Personal Protection; Conductivity Based Sensors for Protection and Healthcare; Optical Chemical Sensors and Personal Protection
Ergonomics of Protective Clothing Heat Strain and Fit; Author Index
Record Nr. UNINA-9910451030303321
Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Pubbl/distr/stampa Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Descrizione fisica 1 online resource (160 p.)
Disciplina 677.68
Altri autori (Persone) JayaramanSundaresan
KiekensPaul <1955->
GrancaricAna Marija
Collana NATO security through science series. D, Information and communication security
Soggetto topico Personal protective equipment
Smart materials
ISBN 6610505284
1-280-50528-1
9786610505289
1-4237-9747-7
1-60750-166-X
600-00-0464-8
1-60129-145-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Title page; Preface; Content; Advanced Research Workshop on Intelligent Textiles for Personal Protection and Safety; Intelligent Textiles for Personal Protection and Safety: The Emerging Discipline; The Wearable Motherboard: The New Class of Adaptive and Responsive Textile Structures; New Textile Materials for Environmental Protection; Wearable Mechanosensing and Emerging Technologies in Fabric-Based Actuation; Flexible Displays on Textiles for Personal Protection; Conductivity Based Sensors for Protection and Healthcare; Optical Chemical Sensors and Personal Protection
Ergonomics of Protective Clothing Heat Strain and Fit; Author Index
Record Nr. UNINA-9910784248803321
Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Materiale a stampa
Lo trovi qui: Univ. Federico II
Opac: Controlla la disponibilità qui
Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Intelligent textiles for personal protection and safety [[electronic resource] /] / edited by Sundaresan Jayaraman, Paul Kiekens and Ana Marija Grancaric
Edizione [1st ed.]
Pubbl/distr/stampa Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Descrizione fisica 1 online resource (160 p.)
Disciplina 677.68
Altri autori (Persone) JayaramanSundaresan
KiekensPaul <1955->
GrancaricAna Marija
Collana NATO security through science series. D, Information and communication security
Soggetto topico Personal protective equipment
Smart materials
ISBN 6610505284
1-280-50528-1
9786610505289
1-4237-9747-7
1-60750-166-X
600-00-0464-8
1-60129-145-0
Formato Materiale a stampa
Livello bibliografico Monografia
Lingua di pubblicazione eng
Nota di contenuto Title page; Preface; Content; Advanced Research Workshop on Intelligent Textiles for Personal Protection and Safety; Intelligent Textiles for Personal Protection and Safety: The Emerging Discipline; The Wearable Motherboard: The New Class of Adaptive and Responsive Textile Structures; New Textile Materials for Environmental Protection; Wearable Mechanosensing and Emerging Technologies in Fabric-Based Actuation; Flexible Displays on Textiles for Personal Protection; Conductivity Based Sensors for Protection and Healthcare; Optical Chemical Sensors and Personal Protection
Ergonomics of Protective Clothing Heat Strain and Fit; Author Index
Record Nr. UNINA-9910818719503321
Amsterdam ; ; Washington, D.C., : IOS Press, c2006
Materiale a stampa
Lo trovi qui: Univ. Federico II
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International journal of smart and nano materials
International journal of smart and nano materials
Pubbl/distr/stampa Abingdon, Oxfordshire, UK, : Taylor & Francis
Disciplina 620.1
Soggetto topico Smart materials
Nanotechnology
Nanociència
Materials
Soggetto genere / forma Periodicals.
Revistes electròniques.
Soggetto non controllato Materials Science
ISSN 1947-542X
Formato Materiale a stampa
Livello bibliografico Periodico
Lingua di pubblicazione eng
Altri titoli varianti IJSNM
Record Nr. UNISA-996320893103316
Abingdon, Oxfordshire, UK, : Taylor & Francis
Materiale a stampa
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