Seeded Growth Combined with Cation Exchange for the Synthesis of Anisotropic Cu2–xS/ZnS, Cu2–xS, and CuInS2 Nanorods

Xia, Chenghui; Pedrazo‐Tardajos, Adrián; Wang, Da; Meeldijk, Johannes D.; Gerritsen, Hans C.; Bals, Sara; Donegá, Celso de Mello

doi:10.1021/acs.chemmater.0c02817

Cited by 16 publications

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“…It is, however, possible that the Cu 2 –x S seed NCs undergo a structural reconstruction after the cation-exchange step and prior to the onset of the epitaxial growth of CuInS 2 , similar to previous observations on the heteroepitaxial growth of wurtzite ZnS on high-chalcocite Cu 2 S seed NCs. 30 Therefore, the unambiguous identification of the crystallographic nature of the facets where the CuInS 2 formation starts ( i.e ., those where the initial Cu + for In 3+ cation exchange occurs) would require advanced high-resolution TEM studies of the early stage samples (such as those shown in Figure 2 ). This is, however, precluded by the high electron beam sensitivity of these samples, which contain higher amounts of unreacted precursors that were not completely eliminated by the washing procedures (see discussion above).…”

Section: Results and Discussionmentioning

confidence: 99%

“…Copper chalcogenide-based HNCs with different compositions ( viz . Cu 2 –x S/ZnS, 25 − 30 Cu 2 –x S/MnS, 31 Cu 2 –x S/CdS, 32 Cu 2 –x S/PbS, 33 Cu 2 –x S/In 2 S 3 , 34 , 35 Cu 2 –x S/CuInS 2 , 36 − 46 CuInS 2 /ZnS, 47 , 48 CuInSe 2 /CuInS 2 49 ) have been obtained by several synthetic strategies, but the degree of control over these nanomaterials is still lagging behind that achieved for the prototypical Cd- and Pb-containing HNCs, despite many important advances in recent years. Owing to the high mobility and low-charge of Cu + , postsynthetic cation exchange reactions have been extensively used to successfully obtain a variety of copper chalcogenide-based (H)NCs.…”

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confidence: 99%

“…Nevertheless, the synthesis of Janus-type Cu 2 –x S/CuInS 2 heteronanorods by partial Cu + for In 3+ cation exchange is particularly challenging due to the low energy barriers for Cu + –In 3+ interdiffusion, the high miscibility of Cu 2 –x S and In y S z phases, and the pronounced tolerance of nanoscale copper indium sulfide to stoichiometry deviations, 16 , 50 which often favor the conversion of the Cu 2 –x S template NCs into homogeneous Cu x In y S 2 NCs rather than HNCs. 16 , 30 , 49 − 52 , 54 Additionally, even when suitable conditions are identified to induce the formation of hetero-NCs, 42 − 44 , 53 it remains difficult to precisely control the location of the CuInS 2 segment since the cation exchange may start simultaneously at different points, yielding distinct heterostructured NCs within the same sample ( e.g ., single-tip Cu 2 –x S/CuInS 2 and central band Cu 2 –x S/CuInS 2 /Cu 2 –x S heteronanorods). 53 …”

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confidence: 99%

“…Multistage seeded injection synthesis strategies are highly versatile and have been successfully used to obtain Cd-chalcogenide based-HNCs of various heteroarchitectures. 9 − 13 , 55 − 57 This approach has recently been extended to Cu-chalcogenide based-HNCs, such as Cu 2– x S/MS (M = Zn, Cd, Mn) HNCs, 30 , 58 CuInS 2 /ZnS core/shell and dot-in-rod HNCs, 47 , 48 and CuInS 2 /CdS tetrapod HNCs. 59 , 60 The most important advantage of the multistage seeded injection approach over the one-pot approach is that radically different physical–chemical conditions can be used to synthesize the seed NCs and the HNCs grown from them.…”

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Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

et al. 2021

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Colloidal heteronanocrystals allow for the synergistic combination of properties of different materials. For example, spatial separation of the photogenerated electron and hole can be achieved by coupling different semiconductors with suitable band offsets in one single nanocrystal, which is beneficial for improving the efficiency of photocatalysts and photovoltaic devices. From this perspective, axially segmented semiconductor heteronanorods with a type-II band alignment are particularly attractive since they ensure the accessibility of both photogenerated charge carriers. Here, a two-step synthesis route to Cu 2 –x S/CuInS 2 Janus-type heteronanorods is presented. The heteronanorods are formed by injection of a solution of preformed Cu 2 –x S seed nanocrystals in 1-dodecanethiol into a solution of indium oleate in oleic acid at 240 °C. By varying the reaction time, Janus-type heteronanocrystals with different sizes, shapes, and compositions are obtained. A mechanism for the formation of the heteronanocrystals is proposed. The first step of this mechanism consists of a thiolate-mediated topotactic, partial Cu + for In 3+ cation exchange that converts one of the facets of the seed nanocrystals into CuInS 2 . This is followed by homoepitaxial anisotropic growth of wurtzite CuInS 2 . The Cu 2 –x S seed nanocrystals also act as sacrificial Cu + sources, and therefore, single composition CuInS 2 nanorods are eventually obtained if the reaction is allowed to proceed to completion. The two-stage seeded growth method developed in this work contributes to the rational synthesis of Cu 2 –x S/CuInS 2 heteronanocrystals with targeted architectures by allowing one to exploit the size and faceting of premade Cu 2 –x S seed nanocrystals to direct the growth of the CuInS 2 segment.

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Section: Results and Discussionmentioning

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Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

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“…Up to now, some commonly used surfactants include, polyvinylpyrrolidone (PVP), [46,110,111] cetrimonium bromide (CTAB), [112][113][114][115] polyStyrene (PS), [116,117] trimethoxyhexadecylsilane (C 18 TMS), [118] and trioctylphosphine (TOP). [119] For example, a chemical reduction method was previously used to synthesize hydrophilic Fe 3 O 4 -Au Janus nanoparticles, where PVP was used to regulate the assembly manner of Fe 3 O 4 and Au nanoparticles (Figure 6D). [120] This was because PVP had a strong affinity for precious metals such that Au NPs would preferentially nucleate on the surface of PVP-modified Fe 3 O 4 nanoparticles and form asymmetric morphology.…”

Section: Seed-mediated Growthmentioning

confidence: 99%

Shedding Light on Luminescent Janus Nanoparticles: From Synthesis to Photoluminescence and Applications

Yuan

Wang

Xiang

et al. 2022

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Luminescent Janus nanoparticles refer to a special category of Janus‐based nanomaterials that not only exhibit dual‐asymmetric surface nature but also attractive optical properties. The introduction of luminescence has endowed conventional Janus nanoparticles with many alluring light‐responsive functionalities and broadens their applications in imaging, sensing, nanomotors, photo‐based therapy, etc. The past few decades have witnessed significant achievements in this field. This review first summarizes well‐established strategies to design and prepare luminescent Janus nanoparticles and then discusses optical properties of luminescent Janus nanoparticles based on downconversion and upconversion photoluminescence mechanisms. Various emerging applications of luminescent Janus nanoparticles are also introduced. Finally, opportunities and future challenges are highlighted with respect to the development of next‐generation luminescent Janus nanoparticles with diverse applications.

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Removing Cadmium Impurities from Cation‐Exchange‐Derived CuInSe₂/CuInS₂ Nanorods for Enhanced Infrared Emission and Photodetection

Portniagin,

Sergeev,

Sergeeva

et al. 2024

Adv Funct Materials

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Metal chalcogenide nanocrystals with variable composition and shape can conveniently be produced using cation exchange synthesis; however, the presence of cation‐containing ligands inherited from the starting material often results in contamination of the final product. To address this issue, a two‐step ligand replacement strategy is developed to fabricate CuInSe2/CuInS2 nanorods from CdSe/CdS nanorods via removal of Cd‐phosphonates from an intermediate Cu2‐xSe/Cu2‐xS phase used in the cation exchange conversion. This synthetic approach furnishes CuInSe2/CuInS2 nanorods with cadmium content below 1 at.%, and high photoluminescence quantum yields reaching 40% in the near‐infrared spectral range. Transient absorption studies reveal that the band alignment in the CuInSe2/CuInS2 heterostructure features a quasi‐type II character, with an electron localized in the core and a hole wavefunction spread over the entire nanorod. The efficient passivation of the core and the reduced Cd content leads to excitonic emission with full width at half maximum down to 110 meV, superimposed with a broad emission band from copper‐induced defects. Field‐effect transistors based on cadmium‐free CuInSe2/CuInS2 nanorods show two orders of magnitude lower noise current density compared with the cadmium‐rich devices. The responsivity and specific detectivity of these devices reach 230 mA W−1 and 108 Jones, respectively, under near‐infrared excitation at room temperature.

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Seeded Growth Combined with Cation Exchange for the Synthesis of Anisotropic Cu_2–xS/ZnS, Cu_2–xS, and CuInS₂ Nanorods

Cited by 16 publications

References 100 publications

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

Shedding Light on Luminescent Janus Nanoparticles: From Synthesis to Photoluminescence and Applications

Removing Cadmium Impurities from Cation‐Exchange‐Derived CuInSe₂/CuInS₂ Nanorods for Enhanced Infrared Emission and Photodetection

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Seeded Growth Combined with Cation Exchange for the Synthesis of Anisotropic Cu2–xS/ZnS, Cu2–xS, and CuInS2 Nanorods

Cited by 16 publications

References 100 publications

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu2–xS/CuInS2 Heteronanorods via Seeded Injection

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu2–xS/CuInS2 Heteronanorods via Seeded Injection

Shedding Light on Luminescent Janus Nanoparticles: From Synthesis to Photoluminescence and Applications

Removing Cadmium Impurities from Cation‐Exchange‐Derived CuInSe2/CuInS2 Nanorods for Enhanced Infrared Emission and Photodetection

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Seeded Growth Combined with Cation Exchange for the Synthesis of Anisotropic Cu_2–xS/ZnS, Cu_2–xS, and CuInS₂ Nanorods

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

Synthesis and Formation Mechanism of Colloidal Janus-Type Cu_2–xS/CuInS₂ Heteronanorods via Seeded Injection

Removing Cadmium Impurities from Cation‐Exchange‐Derived CuInSe₂/CuInS₂ Nanorods for Enhanced Infrared Emission and Photodetection