Difference between revisions of "Main Page"
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<big>'''Center for Materials and Devices for Information Technology Research'''</big> | <big>'''Center for Materials and Devices for Information Technology Research'''</big> | ||
A) | A) Overview of STC - 1 or 2 lectures (Include how Thrust 1 ties to Thrust 2) (Reid & Armstrong) | ||
B) Basics of | B) Basics of light and fields – 90 minutes (Perry and Kippelen) | ||
*Free space concepts | |||
*Propagation in lossless, non dispersive dielectrics | |||
*Propagation in anistropic media | |||
C) | C) Radiometry, Photometry and Color – 60 minutes (Kippelen) | ||
• | • fundamentals of radiometry, definitions | ||
• | • luminance | ||
• | • radiative transfer equation | ||
• | • photometric units | ||
• | • point and extended sources | ||
• Additive and | • CIE chromaticity diagram | ||
• Additive and substractive color mixing | |||
D) Molecular Orbitals – (Marder & JLB) | D) Molecular Orbitals – 150 minutes (Marder & JLB) | ||
• | • Carbon valency | ||
• | • Nodes | ||
• Sigma and pi orbitals | • Sigma and pi orbitals | ||
• Donors and acceptors | • Donors and acceptors | ||
• Functional groups | |||
• Ionization potential and electron affinity | |||
• Definition of HOMO and LUMO | |||
• Distinction between an orbital and state | |||
E | E) Absorption and Emission of Light – 2 lectures (Perry) – SETH AND JLB ??? | ||
• Jablonski diagram | • Jablonski diagram | ||
• Absorption | • Absorption and chemical structure | ||
• | • fluorescence, ISC, phosphorescence, nonradiative decay | ||
• | • Transition dipole moment, oscillator strength, extinction coefficient | ||
• | • Stokes shift | ||
• | • Energy transfers | ||
F) Electronic Processes and Materials – 150 Minutes (Kippelen ) | |||
• | • Current, conductors, and organic semiconductors | ||
• | • Classical electron theory of charge transport | ||
• | • Charge mobility, resistivity, sheet resistance, transparent conducting oxides | ||
• | • Dielectrics and capacitors, energy and potential | ||
• | • Charge transport in amorphous solids, disorder formalism | ||
• | • Time-of-flight experiments | ||
• | • Metal organic semiconductor contacts, Ohmic and Schottky contacts | ||
• | • Space-charge limited currents | ||
• Electroluminescence | |||
• Photogeneration of carriers | |||
• Photodetectors | |||
G) Introduction to Liquid Crystals – 100 Minutes (Marder, Kippelen) | |||
• | • Liquid crystals | ||
• Director – Classification of LCs | |||
• Director – | |||
• Alignment | • Alignment | ||
• Freederickz | • Alignment layers | ||
• | • Birefringence | ||
• Freederickz transition | |||
• Characterization of liquid crystals | |||
• Dielectric anisotropy | |||
• Viscoelastic properties of LCs | |||
I) OLEDs | H) Liquid Crystal Displays – 80 Minutes (Kippelen, Marder) | ||
• Polarized light | |||
• Twisted nematic cell | |||
• Active and passive matrix displays | |||
• Pixel driver circuits | |||
I) OLEDs - 4 lectures. (Armstrong) | |||
Currently in 9 sections + preface: | |||
• Preface | • Preface | ||
• | • Sections 1,2 Light Emitting Electrochemical Processes | ||
• Section 3 What is a light emitting diode? | |||
• What is a | • Section 4 The first OLEDs | ||
• The first OLEDs | • Section 5 O/O’ Heterojunctions in OLEDs (include small molecules and materials section) | ||
• | • Section 7 Organic Heterojunctions Revisited | ||
• | • Sections 8,9 Enhancing OLED Efficiency with added fluorescent/phosphorescent dopants | ||
• | |||
J) Introduction to Organic Solar Cells | |||
• | • Overview of crystalline silicon and thin-film photovoltaic technologies | ||
• Donor/acceptor heterojunctions | |||
• Exciton generation, diffusion and dissociation | |||
• Solar spectrum | |||
• Power conversion efficiency, external quantum efficiency | |||
• Equivalent circuit and modeling, diode parameters | |||
• Examples of multilayer and bulk heterojunction organic solar cells | |||
• Electrochemical solar cells. | |||
K) Recent results of “state-of-the-art” STC research (Armstrong, Kippelen and others) | |||
Revision as of 14:14, 20 January 2009
Center for Materials and Devices for Information Technology Research A) Overview of STC - 1 or 2 lectures (Include how Thrust 1 ties to Thrust 2) (Reid & Armstrong)
B) Basics of light and fields – 90 minutes (Perry and Kippelen)
- Free space concepts
- Propagation in lossless, non dispersive dielectrics
- Propagation in anistropic media
C) Radiometry, Photometry and Color – 60 minutes (Kippelen) • fundamentals of radiometry, definitions • luminance • radiative transfer equation • photometric units • point and extended sources • CIE chromaticity diagram • Additive and substractive color mixing
D) Molecular Orbitals – 150 minutes (Marder & JLB) • Carbon valency • Nodes • Sigma and pi orbitals • Donors and acceptors • Functional groups • Ionization potential and electron affinity • Definition of HOMO and LUMO • Distinction between an orbital and state
E) Absorption and Emission of Light – 2 lectures (Perry) – SETH AND JLB ??? • Jablonski diagram • Absorption and chemical structure • fluorescence, ISC, phosphorescence, nonradiative decay • Transition dipole moment, oscillator strength, extinction coefficient • Stokes shift • Energy transfers
F) Electronic Processes and Materials – 150 Minutes (Kippelen ) • Current, conductors, and organic semiconductors • Classical electron theory of charge transport • Charge mobility, resistivity, sheet resistance, transparent conducting oxides • Dielectrics and capacitors, energy and potential • Charge transport in amorphous solids, disorder formalism • Time-of-flight experiments • Metal organic semiconductor contacts, Ohmic and Schottky contacts • Space-charge limited currents • Electroluminescence • Photogeneration of carriers • Photodetectors
G) Introduction to Liquid Crystals – 100 Minutes (Marder, Kippelen) • Liquid crystals • Director – Classification of LCs • Alignment • Alignment layers • Birefringence • Freederickz transition • Characterization of liquid crystals • Dielectric anisotropy • Viscoelastic properties of LCs
H) Liquid Crystal Displays – 80 Minutes (Kippelen, Marder) • Polarized light • Twisted nematic cell • Active and passive matrix displays • Pixel driver circuits
I) OLEDs - 4 lectures. (Armstrong) Currently in 9 sections + preface: • Preface • Sections 1,2 Light Emitting Electrochemical Processes • Section 3 What is a light emitting diode? • Section 4 The first OLEDs • Section 5 O/O’ Heterojunctions in OLEDs (include small molecules and materials section) • Section 7 Organic Heterojunctions Revisited • Sections 8,9 Enhancing OLED Efficiency with added fluorescent/phosphorescent dopants
J) Introduction to Organic Solar Cells • Overview of crystalline silicon and thin-film photovoltaic technologies • Donor/acceptor heterojunctions • Exciton generation, diffusion and dissociation • Solar spectrum • Power conversion efficiency, external quantum efficiency • Equivalent circuit and modeling, diode parameters • Examples of multilayer and bulk heterojunction organic solar cells • Electrochemical solar cells.
K) Recent results of “state-of-the-art” STC research (Armstrong, Kippelen and others)