Presentation is loading. Please wait.

Presentation is loading. Please wait.

Figure 19.1. Molecular structures of several conjugated polymers. (From Ref. 1 by permission of American Physical Society.)

Published byIris Robinson Modified over 9 years ago

Similar presentations

Presentation on theme: "Figure 19.1. Molecular structures of several conjugated polymers. (From Ref. 1 by permission of American Physical Society.)"— Presentation transcript:

1 Figure 19.1. Molecular structures of several conjugated polymers. (From Ref. 1 by permission of American Physical Society.)

2 Figure 19.2. Device structure of an organic light-emitting diode.

3 Figure 19.3. Layer-by-layer chemisorptive self-assembly of siloxane dielectric layers on an ITO anode. (From Ref. 8 by permission of American Chemical Society.)

4 Figure 19.4. a) External quantum efficiency and b) luminous efficiency as a function of the number of self-assembled siloxane layers. (From Ref. 8 by permission of American Chemical Society.)

5 Figure 19.5. Schematic energy level diagram of an ITO/PPV/Al LED indicating the electron affinity (EA), ionization potential (IP), workfunction (  ), and injection barriers  E. (From Ref. 10 by permission of Macmillan Magazines Ltd.)

6 Figure 19.6. Schematic of the electronic density of states across a graded interlayer fabricated using electrostatic layer-by-layer assembly. (From Ref. 13 by permission of Macmillan Magazines Ltd.)

7 Figure 19.7. Typical current-voltage characteristics of a solar cell under illumination. The identified quantities are discussed in the text.

8 Figure 19.8. Schematic illustration of photoinduced charge transfer in blends of MEH-PPV and C 60 derivatives. Also illustrated are the phase separation into a bicontinuous network and the general configuration of polymer photovoltaic device. (From Ref. 17 by permission of American Association for the Advancement of Science.)

9 Figure 19.9. I-V characteristics of a (A) Ca/MEH-PPV:[6,6]PCBM/ITO device and (B) Ca/MEH-PPV/ITO device in the dark (open circles) and under 20 mW/cm 2 illumination at 430 nm (solid circles). (From Ref. 17 by permission of American Association for the Advancement of Science.)

10 Figure 19.10. Photoluminescence of an unheated MEH-PPV/C 60 bilayer device (solid) and two heated MEH-PPV/C 60 devices (5 minutes at 150 o C (dotted) and 5 minutes at 250 o C (dashed)). (From Ref. 21 by permission of American Institute of Physics.)

11 Figure 19.11. Photoresponsivity of a MEH-PPV device (squares, magnified by 5x), an unheated MEH-PPV/C 60 bilayer device (circles), a MEH-PPV/C 60 bilayer device that was heated at 150 o C for 5 minutes (triangles) and a MEH- PPV/C 60 bilayer device that was heated at 250 o C for 5 minutes (diamonds). (From Ref. 21 by permission of American Institute of Physics.)

12 Figure 19.12. TEM images of 20 wt % (A) 7 nm by 7 nm and (B) 7 nm by 60 nm CdSe nanocrystals in P3HT and cross-section TEMs of (C) a 110 nm thick film of 60 wt% 10 nm by 10 nm nanocrystals and (d) a 100 nm thick film of 40 wt % 7 nm by 60 nm nanorods in P3HT. (From Ref. 23 by permission of American Association for the Advancement of Science.)

13 Figure 19.13. Mach-Zehnder waveguide modulator. Through  (2), the electrical input modulates the optical output.

14 Figure 19.14. Schematic illustration of polar, self- assembled multilayers grown with Zr phosphate-phosphonate interlayers. (From Ref. 28 by permission of American Association for the Advancement of Science.)

15 Figure 19.15. Schematic cross-section of an electro-optic modulator waveguide with an active organic self-assembled superlattice (SAS). (From Ref. 32 by permission of American Institute of Physics.)

16 Figure 19.16. Schematic illustration of polar order in a film fabricated by the layer-by-layer electrostatic deposition process. The NLO chromophores are represented by the arrows.

17 Figure 19.17. Absorbance at 500 nm and square root of the SHG intensity as a function of the number of bilayers for films made by layer-by-layer polyelectrolyte deposition. (From Ref. 38 by permission of American Institute of Physics.)

18 Figure 19.18. Schematic illustration of a hybrid covalent/electrostaic deposition process for fabricating polar self-assembled multilayers. (From Ref. 40 by permission of WILEY-VCH Verlag GmbH & Co.)

Download ppt "Figure 19.1. Molecular structures of several conjugated polymers. (From Ref. 1 by permission of American Physical Society.)"

Similar presentations

Juan Bisquert Nanostructured Energy Devices: Equilibrium Concepts and Kinetics CRC Press 1 1Introduction 2Electrostatic and thermodynamic potentials of.

Juan Bisquert Nanostructured Energy Devices: Equilibrium Concepts and Kinetics CRC Press 1 1Introduction 2Electrostatic and thermodynamic potentials of.
Asymptotic analysis of double-carrier, space-charge- limited transport in organic light-emitting diodes by Sarah E. Feicht, Ory Schnitzer, and Aditya S.

Asymptotic analysis of double-carrier, space-charge- limited transport in organic light-emitting diodes by Sarah E. Feicht, Ory Schnitzer, and Aditya S.
Substantially Conductive Polymers Part 02. Usually, soliton is served as the charge carrier for a degenerated conducting polymer (e.g. PA) whereas.

Substantially Conductive Polymers Part 02. Usually, soliton is served as the charge carrier for a degenerated conducting polymer (e.g. PA) whereas.
Coupled optoelectronic simulation of organic bulk-heterojunction solar cells: Parameter extraction and sensitivity analysis R. Häusermann,1,a E. Knapp,1.

Coupled optoelectronic simulation of organic bulk-heterojunction solar cells: Parameter extraction and sensitivity analysis R. Häusermann,1,a E. Knapp,1.
1 Air Force Research Laboratory Dr. Michael F. Durstock, 937-255-9208, Device Architectures.. Aluminum ITO Glass V Electron.

1 Air Force Research Laboratory Dr. Michael F. Durstock, , Device Architectures.. Aluminum ITO Glass V Electron.
Collaborators R. Norwood, J. Thomas, M. Eralp, S. Tay, G. Li, College of Optical Sciences, S. Marder, Georgia Tech. M. Yamamoto, NDT Corp. N. Peyghambarian.

Collaborators R. Norwood, J. Thomas, M. Eralp, S. Tay, G. Li, College of Optical Sciences, S. Marder, Georgia Tech. M. Yamamoto, NDT Corp. N. Peyghambarian.
Fei Yu and Vikram Kuppa School of Energy, Environmental, Biological and Medical Engineering College of Engineering and Applied Science University of Cincinnati.

Fei Yu and Vikram Kuppa School of Energy, Environmental, Biological and Medical Engineering College of Engineering and Applied Science University of Cincinnati.
The Effect of Carbon Nanotubes in Polymer Photovoltaic Cells May 13, 2010 JESUS GUARDADO, LEAH NATION, HUY NGUYEN, TINA RO.

The Effect of Carbon Nanotubes in Polymer Photovoltaic Cells May 13, 2010 JESUS GUARDADO, LEAH NATION, HUY NGUYEN, TINA RO.
Kiarash Kiantaj EEC235/Spring 2008

Kiarash Kiantaj EEC235/Spring 2008
Quantum Electronic Effects on Growth and Structure of Thin Films P. Czoschke, Hawoong Hong, L. Basile, C.-M. Wei, M. Y. Chou, M. Holt, Z. Wu, H. Chen and.

Quantum Electronic Effects on Growth and Structure of Thin Films P. Czoschke, Hawoong Hong, L. Basile, C.-M. Wei, M. Y. Chou, M. Holt, Z. Wu, H. Chen and.
Chapter 4 Photonic Sources.

Chapter 4 Photonic Sources.
© Imperial College London 1 Photovoltaics: Research at Imperial College Jenny Nelson Department of Physics Imperial College London Grantham Climate Change.

© Imperial College London 1 Photovoltaics: Research at Imperial College Jenny Nelson Department of Physics Imperial College London Grantham Climate Change.
Current through electronic device. Dynamics of electronic carriers J = nev d = ne 2 F  /m* J =  F (lei de Ohm)  = ne 2  /m* = ne  v d =  F  =

Current through electronic device. Dynamics of electronic carriers J = nev d = ne 2 F  /m* J =  F (lei de Ohm)  = ne 2  /m* = ne  v d =  F  =
Science and Technology of Nano Materials

Science and Technology of Nano Materials
Nathan Duderstadt, Chemical Engineering, University of Cincinnati Stoney Sutton, Electrical Engineering, University of Cincinnati Kate Yoshino, Engineering.

Nathan Duderstadt, Chemical Engineering, University of Cincinnati Stoney Sutton, Electrical Engineering, University of Cincinnati Kate Yoshino, Engineering.
Institute of Materials Research and Engineering 3 Research Link, Singapore 117602 Website: Tel:

Institute of Materials Research and Engineering 3 Research Link, Singapore Website: Tel:
The CdSe Nanocrystalline Growth in solutions

The CdSe Nanocrystalline Growth in solutions
Ch.4: Polymer Solar Cells: Photoinduced Charge Transfer ▪ Photoinduced Electron Transfer between Conjugated Polymer and Fullerene N. S. Sariciftci & A.

Ch.4: Polymer Solar Cells: Photoinduced Charge Transfer ▪ Photoinduced Electron Transfer between Conjugated Polymer and Fullerene N. S. Sariciftci & A.
Figure 20.1. Schematic illustrations of 1D, 2D, and 3D photonic crystals patterned from two different types of dielectric materials.

Figure Schematic illustrations of 1D, 2D, and 3D photonic crystals patterned from two different types of dielectric materials.
Organic Materials of Intermediate Dimensions for Optoelectronic Technologies Guillermo C. Bazan (UCSB), DMR-0087611 Chemical Synthesis provides for the.

Organic Materials of Intermediate Dimensions for Optoelectronic Technologies Guillermo C. Bazan (UCSB), DMR Chemical Synthesis provides for the.

Similar presentations

Ads by Google