Journal article
CdSe Magic-Size Clusters Deviate from Nanocrystal-Size Scalings for Ultrafast Intraband Relaxation and Auger Recombination
Nano letters, v 25(50), pp 17325-17331
02 Dec 2025
PMID: 41329080
Abstract
The cluster regime of colloidal semiconductor quantum dots (QDs) occupies an interesting space on the continuum from molecule to bulk material and allows for the study of QD properties at extreme quantum confinement limits. For typical QDs, several size-dependent trends are well-established, including intraband relaxation rates and the universal scaling of Auger recombination with particle volume. Advances in synthesis now allow isolation of atomically precise semiconductor magic-size clusters (MCs), which offer experimental insight regarding how the electronic structure changes with the particle size in the ultrasmall limit. We report intraband cooling and Auger recombination for several stable CdSe MCs as a function of the particle size and observe deviation from the QD response in the cluster regime. We additionally present optical signatures ascribed to transient disordering that appear in the single-exciton regime for MCs, which point to complexities regarding the implementation of MCs in optoelectronic devices.
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Details
- Title
- CdSe Magic-Size Clusters Deviate from Nanocrystal-Size Scalings for Ultrafast Intraband Relaxation and Auger Recombination
- Creators
- Evan H Oriel - Northwestern UniversityNatalie Saenz - Columbia UniversityAhhyun Jeong - University of ChicagoAlexandra Brumberg - Northwestern UniversityDmitri V Talapin - Argonne National LaboratoryJonathan S Owen - Columbia UniversityLin X Chen - Argonne National LaboratoryRichard D Schaller - Argonne National Laboratory
- Publication Details
- Nano letters, v 25(50), pp 17325-17331
- Publisher
- ACS Publications
- Number of pages
- 7
- Grant note
- Division of Chemistry: CHE-2305121 International Institute for Nanotechnology, Northwestern University: NA National Science Foundation Graduate Research Fellowship Program: DGE-1842165 Basic Energy Sciences: DE-AC02-06CH11357 3M: NA Kwanjeong Educational Foundation: NA
E.H.O., L.X.C., and R.D.S. acknowledge support from the Ultrafast Initiative of the U.S. Department of Energy, Office of Science, Office of Basic Energy Sciences, through Argonne National Laboratory under Contract DE-AC02-06CH11357. The authors acknowledge support of the National Science Foundation MSN under Award CHE-2305121. This material is based on work supported by the National Science Foundation Graduate Research Fellowship Program under Grant DGE-1842165 (to A.B.). A.B. gratefully acknowledges support from a 3M Graduate Research Fellowship, the Ryan Fellowship, and the International Institute for Nanotechnology at Northwestern University. A.J. is partially supported by a graduate fellowship from Kwanjeong Educational Foundation. J.S.O. acknowledges support from the NSF Center Integration of Modern Optoelectronic Materials on Demand (IMOD), NSF Grant DMR-2019444. Work performed at the Center for Nanoscale Materials, a U.S. Department of Energy Office of Science User Facility, was supported by the U.S. DOE, Office of Basic Energy Sciences, under Contract DE-AC02-06CH11357. The authors thank Thomas S. Ie for software assistance and Alexander L. Efros for helpful discussions.
- Resource Type
- Journal article
- Language
- English
- Academic Unit
- Chemistry
- Web of Science ID
- WOS:001629362300001
- Scopus ID
- 2-s2.0-105024884319
- Other Identifier
- 991022138673804721
InCites Highlights
Data related to this publication, from InCites Benchmarking & Analytics tool:
- Collaboration types
- Domestic collaboration
- Web of Science research areas
- Chemistry, Multidisciplinary
- Chemistry, Physical
- Materials Science, Multidisciplinary
- Nanoscience & Nanotechnology
- Physics, Applied
- Physics, Condensed Matter