Colloidal Cu2−x(SySe1−y) alloy nanocrystals with controllable crystal phase: synthesis, plasmonic properties, cation exchange and electrochemical lithiation

Dilena, Enrico; Dorfs, Dirk; George, Chandramohan; Miszta, Karol; Povia, Mauro; Genovese, Alessandro; Casu, Alberto; Prato, Mirko; Manna, Liberato

doi:10.1039/c2jm30788j

Cited by 73 publications

(82 citation statements)

References 76 publications

(61 reference statements)

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“…To that end, our results are complementary to recent work by Gamelin and Mayer to advance the understanding of lightdriven redox chemistry of ZnO nanocrystals in organic media as it relates to their infrared plasmonic properties, [20][21][22][23][24][25][26] as well as work by Manna and Tassone, [27][28][29][30][31][32] Talapin and Feldmann, [ 33 ] and Jain and Alivisatos [ 34 ] investigating chemically induced NIR plasmon shifts in substrate-bound Cu 2− x E nanostructures, where E = S, Se, or Te. Our use here of plasmonic-doped metal oxides is expected to overcome the experimental challenges in using noble metal NCs to detect optically one or a few redox events per nanocrystal, owing to the signifi cantly higher carrier concentrations typifi ed by Au and Ag nanostructures.…”

Section: Introductionsupporting

confidence: 74%

Dispersible Plasmonic Doped Metal Oxide Nanocrystal Sensors that Optically Track Redox Reactions in Aqueous Media with Single‐Electron Sensitivity

Mendelsberg

McBride

Duong

et al. 2015

Advanced Optical Materials

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chemical, biochemical, and even biological species ( Figure 1 ). Furthermore, their distinctive near-infrared (NIR) optical response can be quantitatively interpreted [ 14,15 ] so that these redox processes can be tracked with single-electron sensitivity. To demonstrate their exciting new properties in interrogating complex redox systems, we use them to quantify chemically driven charge transfer across the electrifi ed cell membranes of Shewanella oneidensis MR-1, requiring only a simple optical readout and absent any external electrodes. Results and DiscussionRecently, it was shown that the characteristic wavelength and intensity of the NIR plasmon resonance absorption of tin-doped indium oxide (ITO) nanocrystals bound to an electrode can be strongly modulated in a reversible manner using a directional voltage bias. [ 9,16 ] These changes arise from the dependence of the Electron transfer in complex aqueous systems can be observed remotely with single-electron sensitivity using locally dispersed nanostructures conferred with electronic charge concentration-dependent plasmonic properties. When introduced to a system out of redox equilibrium, tin-doped indium oxide nanocrystals undergo rapid multielectron transfer until redox equilibrium is reached; this modulates their free carrier concentration and plasmonic optical properties in the spectrally isolated near-infrared. This capability is harnessed here to noninvasively track, model, and quantify electron transfer events reversibly for organic, inorganic, biogenic, and even living cells.Adv. Optical Mater. 2015, 3, 1293-1300 www.MaterialsViews.com www.advopticalmat.de Figure 1. Plasmonic doped metal oxide nanocrystals reversibly exchange electrons with redox-active small molecules, biomacromolecules, and live bacteria. These multi-electron exchanges modulate their free-carrier concentration, thus changing their plasmonic optical properties. This redoxresponsive plasmon absorbance can be modeled to provide quantitative analysis of electron transfer in systems out of redox equilibrium. wileyonlinelibrary.com

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Section: Introductionsupporting

confidence: 74%

Dispersible Plasmonic Doped Metal Oxide Nanocrystal Sensors that Optically Track Redox Reactions in Aqueous Media with Single‐Electron Sensitivity

Mendelsberg

McBride

Duong

et al. 2015

Advanced Optical Materials

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“…Also, the relative extent of the formation of soluble discharged products (such as polysulfides) with both morphologies can affect their electrochemical activities in terms of voltage plateaus. We then performed electrochemical impedance spectroscopy (EIS) measurements to probe the CuS electrode/electrolyte interface; this can reveal information concerning charge‐transfer resistance for Li ions and various electrochemical processes contributing to the total impedance of electrodes . Figure reports the EIS data (in the range of 100 kHz–10 mHz with an AC amplitude of 10 mV s −1 ) recorded on cells after the first twenty charge/discharge cycles.…”

Section: Resultsmentioning

confidence: 99%

Morphology‐Dependent Electrochemical Properties of CuS Hierarchical Superstructures

et al. 2015

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Hierarchical superstructures formed by self-assembled nanoparticles exhibit interesting electrochemical properties that can potentially be exploited in Li-ion batteries (LIBs) as possible electrode materials. In this work, we tested two different morphologies of CuS superstructures for electrodes, namely, tubular dandelion-like and ball-like assemblies, both of which are composed of similar small covellite nanoparticles. These two CuS morphologies are characterized by their markedly different electrochemical performances, suggesting that their complex structures/morphologies influence the electrochemical properties. At 1.12 A g(-1), the cells made with CuS tubular structures delivered about 420 mAh g(-1), and at 0.56 A g(-1), the capacity was as high as about 500 mAh g(-1) with good capacity retention. Their ease of preparation and processing, together with good electrochemical performance, make CuS tubular dandelion-like clusters attractive for developing low-cost LIBs based on conversion reactions.

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“…The use of cation exchange to modify the optical properties of metal chalcogenides nanocrystals remains a novel field of inquiry. Dilena et al 29 investigated the plasmonic properties of Cu 2−x (S y Se 1−y ) nanocrystals converted to Cd(S y Se 1−y ) upon reacting with Cd ions; however, heterostructure formation was not reported. Huang et al 30 studied the plasmonic absorbance spectra of Cu 1.94 S-ZnS "sandwich-like" heterostructure nanocrystals.…”

Section: Introductionmentioning

confidence: 99%

Analytical modeling of localized surface plasmon resonance in heterostructure copper sulfide nanocrystals

Caldwell

Ding

et al. 2014

The Journal of Chemical Physics

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Localized surface plasmon resonance (LSPR) in semiconductor nanocrystals is a relatively new field of investigation that promises greater tunability of plasmonic properties compared to metal nanoparticles. A novel process by which the LSPR in semiconductor nanocrystals can be altered is through heterostructure formation arising from solution-based cation exchange. Herein, we describe the development of an analytical model of LSPR in heterostructure copper sulfide-zinc sulfide nanocrystals synthesized via a cation exchange reaction between copper sulfide (Cu(1.81)S) nanocrystals and Zn ions. The cation exchange reaction produces dual-interface, heterostructure nanocrystals in which the geometry of the copper sulfide phase can be tuned from a sphere to a thin disk separating symmetrically-grown sulfide (ZnS) grains. Drude model electronic conduction and Mie-Gans theory are applied to describe how the LSPR wavelength changes during cation exchange, taking into account the morphology evolution and changes to the local permittivity. The results of the modeling indicate that the presence of the ZnS grains has a significant effect on the out-of-plane LSPR mode. By comparing the results of the model to previous studies on solid-solid phase transformations of copper sulfide in these nanocrystals during cation exchange, we show that the carrier concentration is independent of the copper vacancy concentration dictated by its atomic phase. The evolution of the effective carrier concentration calculated from the model suggests that the out-of-plane resonance mode is dominant. The classical model was compared to a simplified quantum mechanical model which suggested that quantum mechanical effects become significant when the characteristic size is less than ~8 nm. Overall, we find that the analytical models are not accurate for these heterostructured semiconductor nanocrystals, indicating the need for new model development for this emerging field.

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Colloidal Cu2−x(SySe1−y) alloy nanocrystals with controllable crystal phase: synthesis, plasmonic properties, cation exchange and electrochemical lithiation

Cited by 73 publications

References 76 publications

Dispersible Plasmonic Doped Metal Oxide Nanocrystal Sensors that Optically Track Redox Reactions in Aqueous Media with Single‐Electron Sensitivity

Dispersible Plasmonic Doped Metal Oxide Nanocrystal Sensors that Optically Track Redox Reactions in Aqueous Media with Single‐Electron Sensitivity

Morphology‐Dependent Electrochemical Properties of CuS Hierarchical Superstructures

Analytical modeling of localized surface plasmon resonance in heterostructure copper sulfide nanocrystals

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