Organic Disordered Semiconductors as Networks Embedded in Space and Energy

Abstract: Organic disordered semiconductors have a growing importance because of their low cost, mechanical flexibility, and multiple applications in thermoelectric devices, biosensors, and optoelectronic devices. Carrier transport consists of variable-range hopping between localized quantum states, which are disordered in both space and energy within the Gaussian disorder model. In this paper, we model an organic disordered semiconductor system as a network embedded in both space and energy so that a node represents a … Show more

“…While NS has been extensively applied to a wide variety of “macroscopic systems”, it has been used to a much lesser extent to explore “nano-systems”. The recent work [ 116 ] studies HT in organic disordered semiconductors as networks embedded in space and energy, on which carrier transport is modeled using continuous-time random walks (CTRW) [ 117 ]. Any localized quantum state is represented by a node, while carrier hopping between nodes is encoded by a link.…”

Carrier Transport in Colloidal Quantum Dot Intermediate Band Solar Cell Materials Using Network Science

“…While NS has been extensively applied to a wide variety of “macroscopic systems”, it has been used to a much lesser extent to explore “nano-systems”. The recent work [ 116 ] studies HT in organic disordered semiconductors as networks embedded in space and energy, on which carrier transport is modeled using continuous-time random walks (CTRW) [ 117 ]. Any localized quantum state is represented by a node, while carrier hopping between nodes is encoded by a link.…”

Carrier Transport in Colloidal Quantum Dot Intermediate Band Solar Cell Materials Using Network Science

Connecting continuous models of quantum systems to complex networks: Application to electron transport in real-world one dimensional van der Waals materials