Organic semiconductors have a range of potential applications in various electronic devices, including:
: Utilize charge accumulation at dielectric interfaces for switching. Comparison: Organic vs. Inorganic Semiconductors Introduction to the physics of organic semiconductors physics of organic semiconductors pdf
Instead of Valence and Conduction bands, we speak of HOMO (Highest Occupied Molecular Orbital) and LUMO (Lowest Unoccupied Molecular Orbital). The energy gap between these two determines the material's optical and electrical properties. The energy gap between these two determines the
For decades, the world of electronics was dominated by the rigid, crystalline lattice of inorganic materials like silicon and gallium arsenide. However, a quiet revolution has been underway in laboratories around the globe. Organic semiconductors—carbon-based polymers and small molecules—have emerged as a viable, and in many cases superior, alternative for next-generation optoelectronic devices. and in many cases superior
When an OSC absorbs a photon, it creates an exciton—a bound electron-hole pair. In inorganic semiconductors, the high dielectric constant ($\varepsilon_r$) screens the Coulomb attraction, resulting in Wannier-Mott excitons with large radii and low binding energy ($\sim$ meV), which dissociate easily at room temperature.
