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Multiphonon Process in Mn-Doped ZnO Nanowires

2022-07-11

 

Author(s): Lai, JM (Lai, Jia-Min); Farooq, MU (Farooq, Muhammad Umair); Sun, YJ (Sun, Yu-Jia); Tan, PH (Tan, Ping-Heng); Zhang, J (Zhang, Jun)

Source: NANO LETTERS DOI: 10.1021/acs.nanolett.2c01428 Early Access Date: JUN 2022

Abstract: The multiphonon process plays an essential role in understanding electron???phonon coupling, which significantly influ-ences the optical and transport properties of solids. Multiphonon processes have been observed in many materials, but how to distinguish them directly by their spectral characteristics remains controversial. Here, we report high-order Raman scattering up to 10 orders and hot luminescence involving 11 orders of phonons in Mn-doped ZnO nanowires by selecting the excitation energy. Our results show that the intensity distribution of high-order Raman scattering obeys an exponential decrease as the order number increases, while hot luminescence is fitted with a Poisson distribution with a resonance factor. Their linewidth and frequency can be well explained by two different transition models. Our work provides a paradigm for understanding the multiphonon-involved decay process of an excited state and may inspire studies of the statistical characteristics of excited state decay.

Accession Number: WOS:000818755400001

PubMed ID: 35748677

Author Identifiers:

Author        Web of Science ResearcherID        ORCID Number

TAN, Ping-Heng         D-1137-2009         0000-0001-6575-1516

ISSN: 1530-6984

eISSN: 1530-6992

Full Text: https://pubs.acs.org/doi/10.1021/acs.nanolett.2c01428



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