Organic Semiconductors: Chemistry and Conduction

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

Explores quantum mechanics from atomic to molecular orbitals, covering the Schrödinger equation, quantum numbers, and wavefunction interpretation.

Covers the fundamentals of chemical bonding, focusing on orbitals and resonance in organic chemistry.

Explores covalent bonding stability and orbital properties in molecules like H₂ and He.

Explores the symmetry analysis of a deuterated metal hydride complex and its molecular orbitals.

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

Explores organic semiconductor materials, including LEDs, lasers, and thin film transistors, along with key chemistry concepts.

Delves into ligand field theory, crystal field splitting, and molecular orbitals in transition metal complexes.

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