多激子产生
激子
材料科学
量子点
交换互动
凝聚态物理
自旋(空气动力学)
分子物理学
化学物理
化学
物理
光电子学
铁磁性
热力学
作者
Ho Jin,Clément Livache,Whi Dong Kim,Benjamin T. Diroll,Richard D. Schaller,Victor I. Klimov
出处
期刊:Nature Materials
[Nature Portfolio]
日期:2023-07-13
卷期号:22 (8): 1013-1021
被引量:51
标识
DOI:10.1038/s41563-023-01598-x
摘要
Carrier multiplication is a process whereby a kinetic energy of a carrier relaxes via generation of additional electron-hole pairs (excitons). This effect has been extensively studied in the context of advanced photoconversion as it could boost the yield of generated excitons. Carrier multiplication is driven by carrier-carrier interactions that lead to excitation of a valence-band electron to the conduction band. Normally, the rate of phonon-assisted relaxation exceeds that of Coulombic collisions, which limits the carrier multiplication yield. Here we show that this limitation can be overcome by exploiting not 'direct' but 'spin-exchange' Coulomb interactions in manganese-doped core/shell PbSe/CdSe quantum dots. In these structures, carrier multiplication occurs via two spin-exchange steps. First, an exciton generated in the CdSe shell is rapidly transferred to a Mn dopant. Then, the excited Mn ion undergoes spin-flip relaxation via a spin-conserving pathway, which creates two excitons in the PbSe core. Due to the extremely fast, subpicosecond timescales of spin-exchange interactions, the Mn-doped quantum dots exhibit an up-to-threefold enhancement of the multiexciton yield versus the undoped samples, which points towards the considerable potential of spin-exchange carrier multiplication in advanced photoconversion.
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