Synthesis and Characterization of CuZnSe<sub>2</sub> Nanocrystals in Wurtzite, Zinc Blende, and Core–Shell Polytypes

Ren, Haixia; Wang, Miao; Li, Zhe; Laffir, Fathima; Brennan, Grace; Sun, Yuanwei; Stokes, Killian; Geaney, Hugh; O’Reilly, Emmet J.; Gao, Peng; Liu, Ning; McCarthy, Conor T.; Ryan, Kevin M.

doi:10.1021/acs.chemmater.9b03063

Cited by 10 publications

(12 citation statements)

References 83 publications

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“…Instead of depositing binary ZnS or ZnSe shells on CISe NCs, ternary CuInS 2 (CIS) shells were also constructed via multistep cation exchange reactions, starting from CdSe/CdS core/shell nanostructures. , The growth of ternary copper-based compounds on CISe NCs may provide a chance to further improve PLQY because of the similar metal elements in the core and the shell. Very recently, ternary CIS or CuZnSe 2 shells with wurtzite (WZ) crystal structure were deposited on cubic CIS or CuZnSe 2 core NCs, respectively, forming core/shell NCs consisting of the same compound but with a different crystal structure. Those polytypic CIS core/shell NCs showed the optical behavior typical for type-II core/shell structures, and the PLQY of the heterophased CIS NCs was only around 2% .…”

Section: Introductionmentioning

confidence: 99%

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

et al. 2020

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A range of different copper-based sulfide shells, such as CuInS 2 , CuInZnS 2 , CuInS 2-x Se x , and CuInZnS 2-x Se x , have been grown on CuInSe 2 (CISe) nanocrystals (NCs) in order to improve their photoluminescence quantum yield (PLQY). Starting from initial CISe core NCs with PLQY of 0.4%, the deposition of the CuInS 2 shell has increased the PLQY to 4.5%, while introducing Zn or Se elements into the CuInS 2 shell to form cation-alloyed CuInZnS 2 or anion-alloyed CuInS 2-x Se x shells improved their PLQYs to 8% and 11%, respectively. Limitations on PLQY for the mentioned shell materials were related to the lattice mismatch with the CISe core material, and the band gap alignment in the core/shell NCs for quasi type-II nanostructures. This could be mitigated by growing a multinary CuInZnS 2-x Se x shell on the CISe core NCs, which resulted in further improvement of their PLQY to 20% for the emission centered at 920 nm. This study offers guidance for the rational selection of copper-based sulfide shell materials that are able to significantly improve the PLQY of heavy-metal free CISe NCs in the near-infrared spectral range of 834−1028 nm, which is relevant for biological labeling, optoelectronics, and sensing.

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Section: Introductionmentioning

confidence: 99%

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

et al. 2020

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“…CdSe/CdS core/shell NCs with cubic zinc-blende (ZB) core and hexagonal wurtzite (WZ) shells were separately reported by Mahler and Ghosh. , Compared to CdSe/CdS core/shell NCs with identical crystal structure for both core and shell, in polytypic CdSe/CdS core/shell NCs a thick WZ CdS shell could efficiently suppress fluorescence blinking . Very recently, polytypic copper-based ternary compounds were reported, such as CIS and CuZnSe 2 (CZSe) NCs. After formation of a CIS or CZSe core with a cubic chalcopyrite (CP) or ZB crystal structure, the same material with a different crystal structure was further grown to form cubic CP/hexagonal WZ CIS NCs or cubic ZB/hexagonal WZ CZSe core/shell NCs.…”

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confidence: 99%

Phase-Controlled Growth of CuInS₂ Shells to Realize Colloidal CuInSe₂/CuInS₂ Core/Shell Nanostructures

et al. 2020

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Synthetic routes to deposit CuInS2 (CIS) shells with either a cubic chalcopyrite (CP) or a hexagonal wurtzite (WZ) phase on trigonal pyramidal-shaped CuInSe2 (CISe) core nanocrystals (NCs) with a cubic CP crystal structure have been developed and governed by tuning the amount of the sulfur precursor tert-dodecanethiol. During the synthesis of CP-CIS/CP-CISe core/shell NCs, the CP-CIS shell initially starts to grow epitaxially in a uniform way, while the further addition of the CIS precursor induces islandlike growth, and finally a branched CIS shell is formed. In a stark contrast, when a WZ-CIS shell is deposited, it initially grows on a portion of each of the facets of the trigonal pyramidal-shaped CISe cores to form a monolayer, which then continues to increase in thickness and forms a multilayered WZ-CIS shell. Both CP-CISe/CP-CIS core/shell NCs and CP-CISe/WZ-CISe core/shell NCs exhibit rather low photoluminescence quantum yields (<10%), even with a smaller-sized CISe core, which calls for further refinements of the shell growth methods. Synthetic methods for the growth of CIS shells as described here allow for direct deposition of cadmium-free ternary compounds as shell materials and provide important insights into the different modes of growth of heterostructured NCs, ranging from epitaxial to island- and branched-like, as well to the facet-specific multilayer deposition.

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“…CZS NCs were synthesized using a colloidal chemical approach. The methodology adopted here is essentially similar to the one adopted for the synthesis of copper–cadmium–zinc selenide materials , and relies on rapid kinetics to avoid the formation of undesirable copper sulfide phases. The synthetic details are given in Supporting Information (section 1).…”

Section: Experimental Methodsmentioning

confidence: 99%

Optical Properties and Electronic Structure of Copper Zinc Sulfide Nanocrystals

et al. 2021

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Continued efforts to transition toward renewable energy sources have spurred tremendous research into the discovery of near-infrared gap semiconductors. Here we describe the optical properties and electronic structure of copper zinc sulfide nanocrystals, with copper mole fractions as high as x Cu = 0.18. Copper zinc sulfide is shown to be a near-infrared gap semiconductor that exists in both zinc blende and wurtzite forms, similar to ZnS. The bandgap is shown to vary over 3.45–2.15 eV as the copper mole fraction is changed from 0.01 to 0.18. We find that the valence band of CuZnS nanocrystals has a significant tendency for hole localization, similar to other highly mismatched alloys. Further, our ultrafast studies are consistent with rapid (450 ± 60 fs) removal of conduction band electrons and subsequent defect emission over 4.3 ns.

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Synthesis and Characterization of CuZnSe₂ Nanocrystals in Wurtzite, Zinc Blende, and Core–Shell Polytypes

Cited by 10 publications

References 83 publications

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Phase-Controlled Growth of CuInS₂ Shells to Realize Colloidal CuInSe₂/CuInS₂ Core/Shell Nanostructures

Optical Properties and Electronic Structure of Copper Zinc Sulfide Nanocrystals

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Synthesis and Characterization of CuZnSe2 Nanocrystals in Wurtzite, Zinc Blende, and Core–Shell Polytypes

Cited by 10 publications

References 83 publications

Growth of Multinary Copper-Based Sulfide Shells on CuInSe2 Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Growth of Multinary Copper-Based Sulfide Shells on CuInSe2 Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Phase-Controlled Growth of CuInS2 Shells to Realize Colloidal CuInSe2/CuInS2 Core/Shell Nanostructures

Optical Properties and Electronic Structure of Copper Zinc Sulfide Nanocrystals

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Synthesis and Characterization of CuZnSe₂ Nanocrystals in Wurtzite, Zinc Blende, and Core–Shell Polytypes

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Growth of Multinary Copper-Based Sulfide Shells on CuInSe₂ Nanocrystals for Significant Improvement of Their Near-Infrared Emission

Phase-Controlled Growth of CuInS₂ Shells to Realize Colloidal CuInSe₂/CuInS₂ Core/Shell Nanostructures