Lectures related to Organic Electronic Materials

Intramolecular Electron Delocalization

Explores intramolecular electron delocalization in organic electronics, covering history, challenges, charge transport, device preparation, and advanced topics.

Organic Electronic Devices

Explores the history, challenges, and quantum mechanics behind organic electronics, focusing on intramolecular electron delocalization and semiconductor materials preparation.

Introduction to Organic Electronic Materials and Devices

Introduces organic electronic materials, covering their properties, challenges, and applications in sustainable engineering and device fabrication.

Organic Electronics: Devices & Materials

Explores organic electronics, focusing on devices like transistors and photovoltaic cells, and the preparation of semiconductor materials.

Organic Electronics: Electronic Perturbations and Semiconductor Devices

Explores challenges and advancements in organic electronics, covering transport, semiconductor devices, and quantum harmonic oscillators.

Charge Carriers in Organic Electronics: Solitons and Polarons

Discusses charge carriers in organic materials, focusing on solitons, polarons, and their implications for charge transport and device performance.

Charge Transport in Organic Materials

Explores charge transport in organic materials, covering intramolecular electron delocalization, different transport regimes, and advanced topics.

Organic Electronics: Electronic Perturbations

Explores electronic perturbations in organic materials, covering vibronic coupling, charge formation, transport mechanisms, and advanced topics.

Organic Electronic Materials: Field-Effect Transistors

Explores organic electronic materials, focusing on organic field-effect transistors (OFETs) and their operation, characterization, and real-world applications.

Semiconductor Devices II: Defects Engineering

Covers the analysis of measurements and defects engineering in semiconductor devices, including density of states and defect probing.

Organic Electronic Devices: Field-Effect Transistors

Explores organic field-effect transistors, covering their fabrication, working principles, and real device examples.

Semiconductor Devices II: Contact Resistance Modeling

Explores contact resistance modeling in semiconductor devices, focusing on gate voltage calculation and defect analysis.

Electronic Perturbations: Vibronic Coupling and Light-Matter Interaction

Covers vibronic coupling, light-matter interaction, charge transport, and exciton formation in organic electronics.

Simulation of 2D Field Effect Transistors

Covers the simulation of 2D Field Effect Transistors and the advantages of using Green's Function.

Organic and Printed Electronics: Applications, Markets, Roadmaps

Explores organic and printed electronics, focusing on innovation, market perspectives, and roadmaps in the field.

PN Junctions and Heterostructures: Principles and Applications

Discusses the principles of pn junctions and heterostructures in semiconductor physics, focusing on their electrical characteristics and practical applications.

Organic Electronics: Fundamentals and Applications

Explores the fundamentals and applications of organic electronics, covering intramolecular electron delocalization, charge formation, challenges, and sustainability.

Strain and Heteroepitaxy

Explores the impact of strain on semiconductor band structures, epitaxy, critical thickness, and defect formation, emphasizing the role of Hooke's law and elasticity theory.

Defects in Electronic Materials

Delves into the impact of defects in electronic materials, exploring band tails, XPS analysis, and defect creation mechanisms.

Intrinsic Semiconductors: Thermal Generation and Carrier Concentration

Covers intrinsic semiconductors, focusing on thermal generation and carrier concentration calculations.