Inorganic flexible optoelectronics : materials and applications / edited by Zhenqiang Ma and Dong Liu.
Contributor(s): Ma, Zhenqiang [editor.]
| Liu, Dong [editor.].
Material type: 
BookPublisher: Weinheim, Germany : Wiley-VCH, [2019]Description: 1 online resource.Content type: text Media type: computer Carrier type: online resourceISBN: 9783527812967; 3527812962; 9783527813001; 3527813004.Subject(s): Optoelectronics | TECHNOLOGY & ENGINEERING -- Mechanical | OptoelectronicsGenre/Form: Electronic books. | Electronic books.Additional physical formats: Print version:: Inorganic flexible optoelectronics.DDC classification: 621.381045 Online resources: Wiley Online Library Includes bibliographical references and index.
Online resource; title from PDF title page (EBSCO, viewed May 6, 2019).
Cover; Title Page; Copyright; Contents; Preface; Chapter 1 Flexible Inorganic Light Emitting Diodes Enabled by New Materials and Designs, With Examples of Their Use in Neuroscience Research; 1.1 Introduction; 1.2 Flexible Micro-Inorganic LEDs ( -ILEDs); 1.3 Flexible Quantum Dot LEDs (QLEDs); 1.4 Flexible Perovskite LEDs (PeLEDs); 1.5 Flexible 2D Materials-Based LEDs; 1.6 Opportunities for Flexible Optoelectronic Systems in Neuroscience Research; 1.6.1 Miniaturized Flexible LEDs and Detectors for Injectable Neural Probes
1.6.2 Wireless, Flexible Optoelectronic Systems for Genetically Modified Recording and Stimulation1.6.3 Wireless, Battery-Free Optogenetic Stimulation Devices for Use in the Peripheral Nervous System; 1.7 Conclusion; References; Chapter 2 Flexible Light-Emitting Diodes Based on Inorganic Semiconductor Nanostructures: From Thin Films to Nanowires; 2.1 Introduction; 2.2 Flexible LEDs Based on Thin-Film Transfer; 2.2.1 Conventional Approaches for Lift-Off and Transfer of Thin Crystalline Films; 2.2.2 Thin Film Mechanical Transfer Using van der Waals Epitaxy on 2D Materials
2.3 Nanowire LEDs and Their Potential Advantages2.4 Flexible LEDs Based on Inorganic Bottom-Up Nanowires; 2.4.1 LEDs Using a Direct Nanowire Growth on Flexible Substrates; 2.4.1.1 ZnO Nanowire-Based Flexible LEDs; 2.4.1.2 Nitride Flexible LEDs on Metal Foils; 2.4.2 In-plane Transferred Nanowire LEDs; 2.4.3 Vertically Transferred Nanowire LEDs; 2.4.4 Novel Approaches for Nanostructure Lift-Off Using van der Waals Epitaxy; 2.5 Conclusions; References; Chapter 3 Flexible Photodetectors with Nanomembranes and Nanowires; 3.1 Introduction; 3.2 Flexible Photodetectors; 3.3 Performance Parameters
3.3.1 Responsivity3.3.2 Detectivity; 3.3.3 Photoconductive Gain (G); 3.3.4 Sensitivity (S); 3.3.5 Response Time; 3.3.6 Ion/Ioff Current Ratio; 3.4 Fabrication of Donor Substrates for Transferrable NMs; 3.4.1 Smart-Cut® Technique; 3.4.2 Epitaxial Growth Technique; 3.5 Transfer Printing of Single Crystalline Semiconductor NMs; 3.6 Semiconductor NM-Based Flexible Photodetectors; 3.6.1 Si NM-Based Flexible Photodetectors; 3.6.2 Ge NM-Based Flexible Photodetectors; 3.6.3 III-V NM-Based Flexible Photodetectors; 3.7 Fabrication of NW-Based Flexible Detectors; 3.7.1 Synthesis of Single Crystal Si NWs
3.7.2 Assembly of NW-TFTs3.8 Fabrication of Flexible Photodetectors Based on AgNWs/CdS NWs; 3.9 Results and Discussion; 3.9.1 I-V Curve Under Different Incident Light Densities; 3.9.2 I-T Plot Under ON/OFF Switching of Light Source; 3.9.3 Bending Performance; 3.9.4 Response and Recovery Time; 3.9.5 I-V Measurement Under Light and Dark Conditions; 3.9.6 Sensitivity; 3.9.7 UV Absorption of CdSe, P3HT, and Hybrid Photodetector; 3.9.8 Responsivity; 3.10 Conclusions and Outlook; References; Chapter 4 2-D Material-Based Photodetectors on Flexible Substrates; 4.1 Introduction
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