Seven Excitons at a Cost of One: Redefining the Limits for Conversion Efficiency of Photons into Charge Carriers

Citations Over TimeTop 1% of 2006 papers

Abstract

The performance of photovoltaic and photochemical devices is directly linked to the efficiency with which absorbed photons are converted into electron-hole pairs (excitons). A usual assumption is that one photon produces a single exciton, while the photon energy in the excess of the material's energy gap (the gap that separates the conduction from the valence band) is wasted as heat. Here we experimentally demonstrate that using semiconductor nanocrystals we can reduce this energy loss to a nearly absolute minimum allowed by energy conservation by producing multiple excitons per single photon. Specifically, we generate seven excitons from a photon with an energy of 7.8 energy gaps, which corresponds to only approximately 10% energy loss, while in the normal scenario (one photon produces one exciton) approximately 90% of the photon energy would be dissipated as heat. Such large yields of charge carriers (photon-to-exciton conversion efficiency up to 700%) has the potential to dramatically increase the performance of photovoltaic cells and can greatly advance solar fuel producing technologies.

Related Papers

• → Sustained Biexciton Populations in Nanoshell Quantum Dots(2019)22 cited
• → Ultrafast red-shift of biexciton binding energy by multiple exciton generation in PbS quantum dots(2013)
• → Carrier multiplication and cooling in semiconductor quantum dots(2018)
• → Energy Absorption of an Exciton-Biexciton System in a Quantum Dot – Metal Nanoparticle Hybrid(2022)
• → Spatially indirect excitons and exciton quasimolecules in nanosystems with double quantum dots(2022)