Spatially Resolved Photogenerated Exciton and Charge Transport in Emerging Semiconductors

Abstract: We review recent advances in the characterization of electronic forms of energy transport in emerging semiconductors. The approaches described all temporally and spatially resolve the evolution of initially localized populations of photogenerated excitons or charge carriers. We first provide a comprehensive background for describing the physical origin and nature of electronic energy transport both microscopically and from the perspective of the observer. We introduce the new family of far-field, time-resolved… Show more

“…New experimental probes are required, such as bottom up construction of qE-like systems in liposomes or in membrane rafts. Developments in combining time and spatial resolution [82] hint at the possibility of observing the role of specific components of the antenna/supercomplex system in qE, along with the ability to directly measure the exciton diffusion length during qE. Ideally spatial resolution of less than 10 nm with single ps time resolution would be required.…”

Models and mechanisms of the rapidly reversible regulation of photosynthetic light harvesting

“…New experimental probes are required, such as bottom up construction of qE-like systems in liposomes or in membrane rafts. Developments in combining time and spatial resolution [82] hint at the possibility of observing the role of specific components of the antenna/supercomplex system in qE, along with the ability to directly measure the exciton diffusion length during qE. Ideally spatial resolution of less than 10 nm with single ps time resolution would be required.…”

Models and mechanisms of the rapidly reversible regulation of photosynthetic light harvesting

“…Considering that the diffusion coefficients ( D ) for hydroperoxide intermediates and L012 are 7 × 10 −6 cm 2 s −1 (ref. 42 ) and 6.6 × 10 −6 cm 2 s −1 , 43 respectively, the diffusion distance ( Δ ) in a time period ( t ) could be calculated according to the diffusion equation: 44 Δ = (2 Dt ) 0.5 …”

High-resolution imaging of catalytic activity of a single graphene sheet using electrochemiluminescence microscopy

“…5b ). Exciton diffusion is a common experimental observable extracted from non-linear microscopies 2 but is challenging to simulate on long length scales. 35–37 Using adHOPS, simulating exciton diffusion in a linear chain of 10 3 pigments is computationally tractable because for V = 100 cm −1 it requires, on average, less than 2 × 10 3 auxiliary wave functions and 20 pigment states.…”

“…The recent development of spatially-resolved non-linear spectroscopy provides a remarkable new lens by which to study exciton dynamics in heterogeneous materials. 1,2 Interpreting spatially-resolved spectroscopic signals, however, remains challenging due to the absence of corresponding simulations.…”

Formally exact simulations of mesoscale exciton dynamics in molecular materials