Helping semiconductors find a cooler way to relax

This simple idea defines a semiconductor's optical properties. The energy from any absorbed light is transferred to the material's electrons. Most of the free electrons in a semiconductor have energy near the top of the bandgap. But the absorption of photons with energy much larger than the bandgap creates, in turn, much higher energy electrons that are also called hot electrons.

Understanding the process by which these so-called hot electrons relax to energy nearer the top of the bandgap is essential for understanding the operation of light-harvesting devices. For example, the efficiency of a solar cell is reduced if this huge excess energy is lost as heat. "However, it was extremely difficult, if not impossible, to sufficiently utilize these hot electrons in real light-conversion applications due to their very short lifetimes," says material scientist Omar Mohammed.

Mohammed and his colleagues used to interface and bandgap engineering to delay hot carrier's (electrons and holes) relaxation and to significantly increase their lifetimes.

The team studied a semiconductor known as a lead halide perovskite. They designed and fabricated architectures made up of multiple quantum wells: a thin layer of semiconductor sandwiched between light-absorber layers of larger bandgap material. They compared the optical properties of structures in which the wells were all the same thickness and asymmetric structures in which the good widths varied. They used a technique called femtosecond (1 femtosecond = 10-15seconds) transient absorption spectroscopy combined with theoretical calculations to determine the timescale of the hot electron relaxation.

They found the cooling rate had a strong dependence on the quantum well thickness in the asymmetric sample and that the relaxation of the hot carriers in the asymmetric multiple quantum wells was 12.5-fold slower compared to that of the symmetric multiple quantum wells.

This new finding provides a unique strategy on how to significantly slow down the hot carriers cooling in semiconducting materials for their better utilization in solar cells applications.

Journal Information: Partha Maity et al, Cascade Electron Transfer Induces Slow Hot Carrier Relaxation in CsPbBr3 Asymmetric Quantum Wells, ACS Energy Letters (2021). DOI: 10.1021/acsenergylett.1c01142