Mid-Infrared Ultrafast Carrier Dynamics in Thin Film Black Phosphorus
Vasudevan Iyer, Peide Ye, and Xianfan Xu

TL;DR
This study uses ultrafast pump-probe spectroscopy in the mid-infrared range to investigate carrier relaxation dynamics in thin film black phosphorus, revealing key physical phenomena and anisotropic effects relevant for optoelectronic applications.
Contribution
It provides new insights into carrier relaxation processes, phonon interactions, and surface oxidation effects in black phosphorus using a comprehensive ultrafast spectroscopy approach.
Findings
Carrier relaxation times increase near the band gap.
Carrier-phonon scattering rates are similar along different crystal directions.
Oxidation induces surface charges affecting carrier dynamics.
Abstract
Black phosphorus is emerging as a promising semiconductor for electronic and optoelectronic applications. To study fundamental carrier properties, we performed ultrafast femtosecond pump-probe spectroscopy on thin film black phosphorus mechanically exfoliated on a glass substrate. Carriers (electrons and holes) were excited to high energy levels and the process of carrier relaxation through phonon emission and recombination was probed. We used a wide range of probing wavelengths up to and across the band gap to study the evolution of the relaxation dynamics at different energy levels. Our experiments revealed a plethora of important physical phenomena. The fast relaxation time constants, associated with carrier-phonon scattering, steadily increase as the energy of the probe beam approaches the band gap energy, which was determined to be 0.31 eV, and the carrier recombination rate was…
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Taxonomy
Topics2D Materials and Applications · Perovskite Materials and Applications · Thermal properties of materials
