Spectral fingerprints of individual Mn2+impurities and Mn2+pairs in magic-sized nanoclusters

Jan Bieniek; Woonhyuk Baek; Taeghwan Hyeon; Gerd Bacher; Rachel Fainblat

doi:10.1063/5.0144867

Spectral fingerprints of individual Mn²⁺impurities and Mn²⁺pairs in magic-sized nanoclusters

Jan Bieniek
, Woonhyuk Baek
, Taeghwan Hyeon
, Gerd Bacher
, Rachel Fainblat^*

^*Corresponding author for this work

Department of Semiconductor Science and Technology

University of Duisburg-Essen
Seoul National University
Korea Basic Science Institute

Research output: Contribution to journal › Journal article › peer-review

6 Scopus citations

Abstract

The chemical synthesis of (CdSe)13 magic-sized clusters (MSCs) allows the replacement of host atoms by individual transition metals such as Mn. By analyzing the spectral fingerprints of the Mn2+ photoluminescence (PL) in MSCs with different dopant concentrations, we are able to distinguish between single Mn2+ ions and coupled Mn2+ pairs. In case of Mn2+ pair emission, temperature-dependent studies show a pronounced red shift, followed by a distinct blue shift of the PL energy upon heating. This is related to a spin ladder formation of the ground and excited states due to Mn2+-Mn2+ exchange interaction at cryogenic temperatures, which is assumed to vanish at higher temperatures. In contrast, single Mn2+ ion PL exhibits a unique redshift with increasing temperature, which can be attributed to a particularly strong coupling to vibronic modes due to the ultimate small size of the MSCs.

Original language	English
Article number	224308
Journal	Journal of Chemical Physics
Volume	158
Issue number	22
DOIs	https://doi.org/10.1063/5.0144867
State	Published - 2023.06.14

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title = "Spectral fingerprints of individual Mn2+impurities and Mn2+pairs in magic-sized nanoclusters",

abstract = "The chemical synthesis of (CdSe)13 magic-sized clusters (MSCs) allows the replacement of host atoms by individual transition metals such as Mn. By analyzing the spectral fingerprints of the Mn2+ photoluminescence (PL) in MSCs with different dopant concentrations, we are able to distinguish between single Mn2+ ions and coupled Mn2+ pairs. In case of Mn2+ pair emission, temperature-dependent studies show a pronounced red shift, followed by a distinct blue shift of the PL energy upon heating. This is related to a spin ladder formation of the ground and excited states due to Mn2+-Mn2+ exchange interaction at cryogenic temperatures, which is assumed to vanish at higher temperatures. In contrast, single Mn2+ ion PL exhibits a unique redshift with increasing temperature, which can be attributed to a particularly strong coupling to vibronic modes due to the ultimate small size of the MSCs.",

author = "Jan Bieniek and Woonhyuk Baek and Taeghwan Hyeon and Gerd Bacher and Rachel Fainblat",

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T1 - Spectral fingerprints of individual Mn2+impurities and Mn2+pairs in magic-sized nanoclusters

AU - Bieniek, Jan

AU - Baek, Woonhyuk

AU - Hyeon, Taeghwan

AU - Bacher, Gerd

AU - Fainblat, Rachel

PY - 2023/6/14

Y1 - 2023/6/14

N2 - The chemical synthesis of (CdSe)13 magic-sized clusters (MSCs) allows the replacement of host atoms by individual transition metals such as Mn. By analyzing the spectral fingerprints of the Mn2+ photoluminescence (PL) in MSCs with different dopant concentrations, we are able to distinguish between single Mn2+ ions and coupled Mn2+ pairs. In case of Mn2+ pair emission, temperature-dependent studies show a pronounced red shift, followed by a distinct blue shift of the PL energy upon heating. This is related to a spin ladder formation of the ground and excited states due to Mn2+-Mn2+ exchange interaction at cryogenic temperatures, which is assumed to vanish at higher temperatures. In contrast, single Mn2+ ion PL exhibits a unique redshift with increasing temperature, which can be attributed to a particularly strong coupling to vibronic modes due to the ultimate small size of the MSCs.

AB - The chemical synthesis of (CdSe)13 magic-sized clusters (MSCs) allows the replacement of host atoms by individual transition metals such as Mn. By analyzing the spectral fingerprints of the Mn2+ photoluminescence (PL) in MSCs with different dopant concentrations, we are able to distinguish between single Mn2+ ions and coupled Mn2+ pairs. In case of Mn2+ pair emission, temperature-dependent studies show a pronounced red shift, followed by a distinct blue shift of the PL energy upon heating. This is related to a spin ladder formation of the ground and excited states due to Mn2+-Mn2+ exchange interaction at cryogenic temperatures, which is assumed to vanish at higher temperatures. In contrast, single Mn2+ ion PL exhibits a unique redshift with increasing temperature, which can be attributed to a particularly strong coupling to vibronic modes due to the ultimate small size of the MSCs.

UR - https://www.scopus.com/pages/publications/85161899125

U2 - 10.1063/5.0144867

DO - 10.1063/5.0144867

M3 - Journal article

C2 - 37314036

AN - SCOPUS:85161899125

SN - 0021-9606

VL - 158

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

IS - 22

M1 - 224308

ER -

Spectral fingerprints of individual Mn²⁺impurities and Mn²⁺pairs in magic-sized nanoclusters

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