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1. Sculpting the plasmonic responses of nanoparticles by directed electron beam irradiation

Author

Roccapriore, Kevin M., Cho, Shin-Hum, Lupini, Andrew R., Milliron, Delia J., and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Mesoscale and Nanoscale Physics, Physics - Optics
Abstract

Spatial confinement of matter in functional nanostructures has propelled these systems to the forefront of nanoscience, both as a playground for exotic physics and quantum phenomena and in multiple applications including plasmonics, optoelectronics, and sensing. In parallel, the emergence of monochromated electron energy loss spectroscopy (EELS) has enabled exploration of local nanoplasmonic functionalities within single nanoparticles and the collective response of nanoparticle assemblies, providing deep insight into the associated mechanisms. However, modern synthesis processes for plasmonic nanostructures are often limited in the types of accessible geometry and materials, and even then, limited to spatial precisions on the order of tens of nm, precluding the direct exploration of critical aspects of the structure-property relationships. Here, we use the atomic-sized probe of the scanning transmission electron microscope (STEM) to perform precise sculpting and design of nanoparticle configurations. Furthermore, using low-loss (EELS), we provide dynamic analyses of evolution of the plasmonic response during the sculpting process. We show that within self-assembled systems of nanoparticles, individual nanoparticles can be selectively removed, reshaped, or arbitrarily patterned with nanometer-level resolution, effectively modifying the plasmonic response in both space and energy domains. This process significantly increases the scope for design possibilities and presents opportunities for arbitrary structure development, which are ultimately key for nanophotonic design. Nanosculpting introduces yet another capability to the electron microscope.

Published
2021

2. Predictability of localized plasmonic responses in nanoparticle assemblies

Author

Roccapriore, Kevin M., Ziatdinov, Maxim, Cho, Shin Hum, Hachtel, Jordan A., and Kalinin, Sergei V.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks, Condensed Matter - Mesoscale and Nanoscale Physics
Abstract

Design of nanoscale structures with desired nanophotonic properties are key tasks for nanooptics and nanophotonics. Here, the correlative relationship between local nanoparticle geometries and their plasmonic responses is established using encoder-decoder neural networks. In the im2spec network, the correlative relationship between local particle geometries and local spectra is established via encoding the observed geometries to a small number of latent variables and subsequently decoding into plasmonic spectra; in the spec2im network, the relationship is reversed. Surprisingly, these reduced descriptions allow high-veracity predictions of the local responses based on geometries for fixed compositions and chemical states of the surface. The analysis of the latent space distributions and the corresponding decoded and closest (in latent space) encoded images yields insight into the generative mechanisms of plasmonic interactions in the nanoparticle arrays. Ultimately, this approach creates a path toward determining configurations that can yield the spectrum closest to the desired one, paving the way for stochastic design of nanoplasmonic structures.

Published
2020
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3. Separating physically distinct mechanisms in complex infrared plasmonic nanostructures via machine learning enhanced electron energy loss spectroscopy

Author

Kalinin, Sergei V., Roccapriore, Kevin M., Cho, Shin Hum, Milliron, Delia J., Vasudevan, Rama, Ziatdinov, Maxim, and Hachtel, Jordan A.

Subjects
Condensed Matter - Materials Science, Condensed Matter - Disordered Systems and Neural Networks, Electrical Engineering and Systems Science - Image and Video Processing
Abstract

Low-loss electron energy loss spectroscopy (EELS) has emerged as a technique of choice for exploring the localization of plasmonic phenomena at the nanometer level, necessitating analysis of physical behaviors from 3D spectral data sets. For systems with high localization, linear unmixing methods provide an excellent basis for exploratory analysis, while in more complex systems large numbers of components are needed to accurately capture the true plasmonic response and the physical interpretability of the components becomes uncertain. Here, we explore machine learning based analysis of low-loss EELS data on heterogeneous self-assembled monolayer films of doped-semiconductor nanoparticles, which support infrared resonances. We propose a pathway for supervised analysis of EELS datasets that separate and classify regions of the films with physically distinct spectral responses. The classifications are shown to be robust, to accurately capture the common spatiospectral tropes of the complex nanostructures, and to be transferable between different datasets to allow high-throughput analysis of large areas of the sample. As such, it can be used as a basis for automated experiment workflows based on Bayesian optimization, as demonstrated on the ex situ data. We further demonstrate the use of non-linear autoencoders (AE) combined with clustering in the latent space of the AE yields highly reduced representations of the system response that yield insight into the relevant physics that do not depend on operator input and bias. The combination of these supervised and unsupervised tools provides complementary insight into the nanoscale plasmonic phenomena.

Published
2020
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4. Universal Gelation of Metal Oxide Nanocrystals via Depletion Attractions

Author

Cabezas, Camila A. Saez, Sherman, Zachary M., Howard, Michael P., Dominguez, Manuel N., Cho, Shin Hum, Ong, Gary K., Green, Allison, Truskett, Thomas M., and Milliron, Delia J.

Subjects
Condensed Matter - Soft Condensed Matter
Abstract

Nanocrystal gelation provides a powerful framework to translate nanoscale properties into bulk materials and to engineer emergent properties through the assembled microstructure. However, many established gelation strategies rely on chemical reactions and specific interactions, e.g., stabilizing ligands or ions on the surface of the nanocrystals, and are therefore not easily transferrable. Here, we report a general gelation strategy via non-specific and purely entropic depletion attractions applied to three types of metal oxide nanocrystals. The gelation thresholds of two compositionally distinct spherical nanocrystals agree quantitatively, demonstrating the adaptability of the approach for different chemistries. Consistent with theoretical phase behavior predictions, nanocrystal cubes form gels at a lower polymer concentration than nanocrystal spheres, allowing shape to serve as a handle to control gelation. These results suggest that the fundamental underpinnings of depletion-driven assembly, traditionally associated with larger colloidal particles, are also applicable at the nanoscale.

Published
2020
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7. Metallic Degenerately Doped Free-Electron-Confined Plasmonic Nanocrystal and Infrared Extinction Response.

Author

Park, Do-Yoon and Cho, Shin-Hum

Subjects
SURFACE plasmon resonance, INDIUM tin oxide, SEMICONDUCTOR materials, N-type semiconductors, EXTINCTION (Psychology), INFRARED absorption
Abstract

In this paper, synthetically scaled-up degenerately n-type doped indium tin oxide (Sn:In2O3) nanocrystals are described as highly transparent conductive materials possessing both optoelectronic and crystalline properties. With tin dopants serving as n-type semiconductor materials, they can generate free-electron carriers. These free electrons, vibrating in resonance with infrared radiation, induce strong localized surface plasmon resonance (LSPR), resulting in efficient infrared absorption. To commercialize products featuring Sn:In2O3 with localized surface plasmon resonance, a scaled-up synthetic process is essential. To reduce the cost of raw materials during synthesis, we aim to proceed with synthesis in a large reactor using industrial raw materials. Sn:In2O3 can be formulated into ink dispersed in solvents. Infrared-absorbing ink formulations can capitalize on their infrared absorption properties to render opaque in the infrared spectrum while remaining transparent in the visible light spectrum. The ink can serve as a security ink material visible only through infrared cameras and as a paint absorbing infrared light. We verified the transparency and infrared absorption properties of the ink produced in this study, demonstrating consistent characteristics in scaled-up synthesis. Due to potential applications requiring infrared absorption properties, it holds significant promise as a robust platform material in various fields. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Electromagnetically Porous Infrared Plasmonic F,Sn-Doped In2O3 Semiconductor Nanocrystals for Infrared Optoelectronic Sensors.

Author

Cho, Shin Hum, Park, Do Yoon, Park, Gi Yong, and Roccapriore, Kevin M.

Abstract

We report dopant-induced complex hierarchical shell growth in metal oxide nanocrystal cubes, leading to a high-density infrared near-field localized surface plasmonic resonance (LSPR) response per film area with an interparticle 41.25% film porosity. We synthesize electromagnetically porous infrared plasmonic nanocrystals via hierarchical cube-on-cube surface growth in highly aliovalently doped semiconductor nanocrystals. In indium oxide colloidal nanocrystal systems, under low Sn dopant, we observe uniform Frank–van der Merwe type shelling. While exceeding 4% Sn atomic dopant, excessive Sn on (400) nanocrystalline achieves a Volmer–Weber island formation-type growth. Through surface XPS analysis, we exclude Stranski–Krastanov-type growth, an intermediary between uniform and island surface growth. Through complex hierarchical shapes in infrared plasmonic semiconductor nanocrystal surfaces, infrared range optical extinction is observed around the 2500 nm wavelength. Direct electromagnetic near-field was imaged through the infrared STEM-EELS electron microscopy technique in single nanocrystals. Due to the intrinsic interparticle gap under monolayer film architecture, electromagnetically dense near-field plasmonic response was directly observed via STEM-EELS. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Enhancing hyperspectral EELS analysis of complex plasmonic nanostructures with pan-sharpening.

Author

Borodinov, Nikolay, Banerjee, Progna, Cho, Shin Hum, Milliron, Delia J., Ovchinnikova, Olga S., Vasudevan, Rama K., and Hachtel, Jordan A.

Subjects
EELS, NANOSTRUCTURES, ELECTRON energy loss spectroscopy
Abstract

Nanoscale hyperspectral techniques—such as electron energy loss spectroscopy (EELS)—are critical to understand the optical response in plasmonic nanostructures, but as systems become increasingly complex, the required sampling density and acquisition times become prohibitive for instrumental and specimen stability. As a result, there has been a recent push for new experimental methodologies that can provide comprehensive information about a complex system, while significantly reducing the duration of the experiment. Here, we present a pan-sharpening approach to hyperspectral EELS analysis, where we acquire two datasets from the same region (one with high spatial resolution and one with high spectral fidelity) and combine them to achieve a single dataset with the beneficial properties of both. This work outlines a straightforward, reproducible pathway to reduced experiment times and higher signal-to-noise ratios, while retaining the relevant physical parameters of the plasmonic response, and is generally applicable to a wide range of spectroscopy modalities. [ABSTRACT FROM AUTHOR]

Published
2021
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11. Functionalization of Fluorine on the Surface of SnO 2 –Mg Nanocomposite as an Efficient Photocatalyst for Toxic Dye Degradation.

Author

Velmurugan, G., Ganapathi Raman, R., Sivaprakash, P., Viji, A., Cho, Shin Hum, and Kim, Ikhyun

Subjects
STANNIC oxide, DYES & dyeing, FLUORINE, PHOTOCATALYSTS, NANOCOMPOSITE materials, ULTRAVIOLET-visible spectroscopy
Abstract

This work reports on the photocatalytic activity of tin oxide (SnO2)-doped magnesium (Mg) and fluorine (F) nanoparticles for methyl orange and safranin dye degradation under sunlight irradiation. Nanocatalysis-induced dye degradation was examined using UV–visible spectroscopy and a pseudo-first-order kinetics model. The results indicate that the prepared nanoparticles exhibit superior photocatalytic activity, and the degradation of methyl orange (MO) dye is approximately 82%. In contrast, the degradation of safranin dye is 96% in the same time interval of 105 min. The calculated crystallite size of the SnO2–Mg–F nanocomposite is 29.5 nm, which respects the particle size found in the DLS analysis with a tetragonal structure and spherical morphology affirmed. The optical characteristics were assessed, and their respective bandgap energies were determined to be 3.6 eV. The influence of F in Mg and SnO2 is recognized with the XRD and FT-IR spectra of the prepared particles. [ABSTRACT FROM AUTHOR]

Published
2023
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14. Spectrally tunable infrared plasmonic F,Sn:In2O3 nanocrystal cubes.

Author

Cho, Shin Hum, Roccapriore, Kevin M., Dass, Chandriker Kavir, Ghosh, Sandeep, Choi, Junho, Noh, Jungchul, Reimnitz, Lauren C., Heo, Sungyeon, Kim, Kihoon, Xie, Karen, Korgel, Brian A., Li, Xiaoqin, Hendrickson, Joshua R., Hachtel, Jordan A., and Milliron, Delia J.

Subjects
*ELECTRON energy loss spectroscopy, *SURFACE plasmon resonance, *NANOCRYSTALS, *EXCITON theory, *PRECIOUS metals, *METALLIC oxides, *INDIUM tin oxide, *CUBES
Abstract

A synthetic challenge in faceted metal oxide nanocrystals (NCs) is realizing tunable localized surface plasmon resonance (LSPR) near-field response in the infrared (IR). Cube-shaped nanoparticles of noble metals exhibit LSPR spectral tunability limited to visible spectral range. Here, we describe the colloidal synthesis of fluorine, tin codoped indium oxide (F,Sn:In2O3) NC cubes with tunable IR range LSPR for around 10 nm particle sizes. Free carrier concentration is tuned through controlled Sn dopant incorporation, where Sn is an aliovalent n-type dopant in the In2O3 lattice. F shapes the NC morphology into cubes by functioning as a surfactant on the {100} crystallographic facets. Cube shaped F,Sn:In2O3 NCs exhibit narrow, shape-dependent multimodal LSPR due to corner, edge, and face centered modes. Monolayer NC arrays are fabricated through a liquid-air interface assembly, further demonstrating tunable LSPR response as NC film nanocavities that can heighten near-field enhancement (NFE). The tunable F,Sn:In2O3 NC near-field is coupled with PbS quantum dots, via the Purcell effect. The detuning frequency between the nanocavity and exciton is varied, resulting in IR near-field dependent enhanced exciton lifetime decay. LSPR near-field tunability is directly visualized through IR range scanning transmission electron microscopy-electron energy loss spectroscopy (STEM-EELS). STEM-EELS mapping of the spatially confined near-field in the F,Sn:In2O3 NC array interparticle gap demonstrates elevated NFE tunability in the arrays. [ABSTRACT FROM AUTHOR]

Published
2020
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19. Infrared plasmonic doped metal oxide nanocubes

Author

Cho, Shin Hum

Subjects
Plasmonics, Nanocrystals
Abstract

Localized surface plasmon resonance (LSPR) in semiconductor nanocrystals (NCs) that results in resonant absorption, scattering, and near field enhancement around the NC can be tuned across a wide optical spectral range from visible to far-infrared by synthetically varying doping level. Cube-shaped NCs of conventional metals like gold and silver generally exhibit LSPR in the visible region with spectral modes determined by their faceted shapes. However, faceted NCs exhibiting LSPR response in the infrared (IR) region are relatively rare. We describe the colloidal synthesis of nanoscale fluorine-doped indium oxide (F:In₂O₃) cubes with LSPR response in the IR region, wherein fluorine was found to both direct the cubic morphology and act as an aliovalent dopant. The presence of fluorine was found to impart higher stabilization to the (100) facets, suggesting that the cubic morphology results from surface binding of F-atoms. In addition, fluorine acts as an anionic aliovalent dopant in the cubic bixbyite lattice of In₂O₃, introducing a high concentration of free electrons leading to LSPR. The cubes exhibit narrow, shape-dependent multimodal LSPR extinction peaks due to corner- and edge-centered modes. The spatial origin of these different contributions to the spectral response are directly visualized by electron energy loss spectroscopy (EELS) in a scanning transmission electron microscope (STEM). A synthetic challenge in faceted metal oxide NCs is realizing tunable LSPR near-field response in the IR. We expand to colloidal synthesis of fluorine, tin co-doped indium oxide (F,Sn:In₂O₃) NC cubes with tunable IR range LSPR. Free carrier concentration is tuned through controlled Sn dopant incorporation, where Sn is an aliovalent n-type dopant in the In₂O₃ lattice. Monolayer NC arrays are fabricated through liquid-air interface assembly, NC film nanocavities with heightened near-field enhancement (NFE). The tunable F,Sn:In₂O₃ NC near-field is coupled with PbS quantum dots, via the Purcell effect. The detuning frequency between the nanocavity and exciton is varied, resulting in IR near-field dependent enhanced exciton lifetime decay

Published
2020
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22. Assembly of Linked Nanocrystal Colloids by Reversible Covalent Bonds

Author

Dominguez, Manuel N., primary, Howard, Michael P., additional, Maier, Josef M., additional, Valenzuela, Stephanie A., additional, Sherman, Zachary M., additional, Reuther, James F., additional, Reimnitz, Lauren C., additional, Kang, Jiho, additional, Cho, Shin Hum, additional, Gibbs, Stephen L., additional, Menta, Arjun K., additional, Zhuang, Deborah L., additional, van der Stok, Aevi, additional, Kline, Sarah J., additional, Anslyn, Eric V., additional, Truskett, Thomas M., additional, and Milliron, Delia J., additional

Published
2020
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23. Assembly of Linked Nanocrystal Colloids by Reversible Covalent Bonds

Author

Dominguez, Manuel, primary, Howard, Michael, primary, Maier, Josef, primary, Valenzuela, Stephanie, primary, Sherman, Zachary, primary, Reimnitz, Lauren, primary, Kang, Jiho, primary, Cho, Shin Hum, primary, Gibbs, Stephen, primary, Menta, Arjun, primary, Zhuang, Deborah, primary, van der Stok, Aevi, primary, Kline, Sarah, primary, Anslyn, Eric, primary, Truskett, Thomas, primary, and Milliron, Delia, primary

Published
2020
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30. Syntheses of Colloidal F:In2O3 Cubes: Fluorine-Induced Faceting and Infrared Plasmonic Response

Author

Cho, Shin Hum, primary, Ghosh, Sandeep, additional, Berkson, Zachariah J., additional, Hachtel, Jordan A., additional, Shi, Jianjian, additional, Zhao, Xunhua, additional, Reimnitz, Lauren C., additional, Dahlman, Clayton J., additional, Ho, Yujing, additional, Yang, Anni, additional, Liu, Yuanyue, additional, Idrobo, Juan-Carlos, additional, Chmelka, Bradley F., additional, and Milliron, Delia J., additional

Published
2019
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31. Deliquescent Chromism of Nickel(II) Iodide Thin Films

Author

Siegler, Timothy D., primary, Reimnitz, Lauren C., additional, Suri, Mokshin, additional, Cho, Shin Hum, additional, Bergerud, Amy J., additional, Abney, Michael K., additional, Milliron, Delia J., additional, and Korgel, Brian A., additional

Published
2019
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33. Syntheses of Colloidal F:In2O3 Cubes: Fluorine-Induced Faceting and Infrared Plasmonic Response

Author

Cho, Shin Hum, primary, Ghosh, Sandeep, primary, Berkson, Zachariah J., primary, Hachtel, Jordan A., primary, Shi, Jianjian, primary, Zhao, Xunhua, primary, Reimnitz, Lauren C., primary, Dahlman, Clayton J., primary, Ho, Yujing, primary, Yang, Anni, primary, Liu, Yuanyue, primary, Idrobo, Juan-Carlos, primary, Chmelka, Bradley F., primary, and Milliron, Delia J., primary

Published
2018
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39. Colloidal ReO3Nanocrystals: Extra Re d-Electron Instigating a Plasmonic Response

Author

Ghosh, Sandeep, Lu, Hsin-Che, Cho, Shin Hum, Maruvada, Thejaswi, Price, Murphie C., and Milliron, Delia J.

Abstract

Rhenium (+6) oxide (ReO3) is metallic in nature, which means it can sustain localized surface plasmon resonance (LSPR) in its nanocrystalline form. Herein, we describe the colloidal synthesis of nanocrystals (NCs) of this compound, through a hot-injection route entailing the reduction of rhenium (+7) oxide with a long chain ether. This synthetic protocol is fundamentally different from the more widely employed nucleophilic lysing of metal alkylcarboxylates for other metal oxide NCs. Owing to this difference, the NC surfaces are populated by ether molecules through an L-type coordination along with covalently bound (X-type) hydroxyl moieties, which enables easy switching from nonpolar to polar solvents without resorting to cumbersome ligand exchange procedures. These as-synthesized NCs exhibit absorption bands at around 590 nm (∼2.1 eV) and 410 nm (∼3 eV), which were respectively ascribed to their LSPR and interband absorptions by Mie theory simulations and Drude modeling. The LSPR response arises from the oscillation of free electron density created by the extra Re d-electron per ReO3unit in the NC lattice, which resides in the conduction band. Further, the LSPR contribution facilitates the observation of dynamic optical modulation of the NC films as they undergo progressive electrochemical charging via ion (de)insertion. Ion (de)insertion leads to distinct dynamic optical signatures, and these changes are reversible in a wide potential range depending on the choice of the ion (lithium or tetrabutylammonium). Nanostructuring in ReO3and the description of the associated plasmonic properties of these NCs made this optical modulation feasible, which were hitherto not reported for the bulk material. We envisage that the synthetic protocol described here will facilitate further exploration of such applications and fundamental studies of these plasmonic NCs.

Published
2019
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40. Syntheses of Colloidal F:In2O3Cubes: Fluorine-Induced Faceting and Infrared Plasmonic Response

Author

Cho, Shin Hum, Ghosh, Sandeep, Berkson, Zachariah J., Hachtel, Jordan A., Shi, Jianjian, Zhao, Xunhua, Reimnitz, Lauren C., Dahlman, Clayton J., Ho, Yujing, Yang, Anni, Liu, Yuanyue, Idrobo, Juan-Carlos, Chmelka, Bradley F., and Milliron, Delia J.

Abstract

Cube-shaped nanocrystals (NCs) of conventional metals like gold and silver generally exhibit localized surface plasmon resonance (LSPR) in the visible region with spectral modes determined by their faceted shapes. However, faceted NCs exhibiting LSPR response in the infrared (IR) region are relatively rare. Here, we describe the colloidal synthesis of nanoscale fluorine-doped indium oxide (F:In2O3) cubes with LSPR response in the IR region, wherein fluorine was found to both direct the cubic morphology and act as an aliovalent dopant. Single-crystalline 160 nm F:In2O3cubes terminated by (100) facets and concave cubes were synthesized using a colloidal heat-up method. The presence of fluorine was found to impart higher stabilization to the (100) facets through density functional theory calculations that evaluated the energetics of F-substitution at surface oxygen sites. These calculations suggest that the cubic morphology results from surface binding of F atoms. In addition, fluorine acts as an anionic aliovalent dopant in the cubic bixbyite lattice of In2O3, introducing a high concentration of free electrons leading to LSPR. We confirmed the presence of lattice fluorine dopants in these cubes using solid-state 19F and 115In nuclear magnetic resonance spectroscopy. The cubes exhibit narrow, shape-dependent multimodal LSPR extinction peaks due to corner- and edge-centered modes. The spatial origin of these different contributions to the spectral response is directly visualized by electron energy loss spectroscopy in a scanning transmission electron microscope.

Published
2019
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41. Bismuth Enhances the Stability of CH3NH3PbI3(MAPI) Perovskite under High Humidity

Author

Siegler, Timothy D., Houck, Daniel W., Cho, Shin Hum, Milliron, Delia J., and Korgel, Brian A.

Abstract

Methylammonium lead iodide (CH3NH3PbI3, MAPI) is a high-performance solar cell material but lacks stability in the presence of humidity. Addition of a few percent bismuth (Bi) as a trivalent cation substitute for Pb (i.e., MAP(Bi)I) leads to enhanced stability under high (90%) relative humidity (RH). At moderate humidity (60% RH), however, MAP(Bi)I degrades more rapidly than MAPI. Bi incorporation into MAPI either stabilizes or destabilizes the two hydration products, MAPI·H2O and PbI2, depending on the amount of humidity in the environment.

Published
2018
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42. Colloidal ReO 3 Nanocrystals: Extra Re d-Electron Instigating a Plasmonic Response.

Author

Ghosh S, Lu HC, Cho SH, Maruvada T, Price MC, and Milliron DJ

Abstract

Rhenium (+6) oxide (ReO 3 ) is metallic in nature, which means it can sustain localized surface plasmon resonance (LSPR) in its nanocrystalline form. Herein, we describe the colloidal synthesis of nanocrystals (NCs) of this compound, through a hot-injection route entailing the reduction of rhenium (+7) oxide with a long chain ether. This synthetic protocol is fundamentally different from the more widely employed nucleophilic lysing of metal alkylcarboxylates for other metal oxide NCs. Owing to this difference, the NC surfaces are populated by ether molecules through an L-type coordination along with covalently bound (X-type) hydroxyl moieties, which enables easy switching from nonpolar to polar solvents without resorting to cumbersome ligand exchange procedures. These as-synthesized NCs exhibit absorption bands at around 590 nm (∼2.1 eV) and 410 nm (∼3 eV), which were respectively ascribed to their LSPR and interband absorptions by Mie theory simulations and Drude modeling. The LSPR response arises from the oscillation of free electron density created by the extra Re d-electron per ReO 3 unit in the NC lattice, which resides in the conduction band. Further, the LSPR contribution facilitates the observation of dynamic optical modulation of the NC films as they undergo progressive electrochemical charging via ion (de)insertion. Ion (de)insertion leads to distinct dynamic optical signatures, and these changes are reversible in a wide potential range depending on the choice of the ion (lithium or tetrabutylammonium). Nanostructuring in ReO 3 and the description of the associated plasmonic properties of these NCs made this optical modulation feasible, which were hitherto not reported for the bulk material. We envisage that the synthetic protocol described here will facilitate further exploration of such applications and fundamental studies of these plasmonic NCs.

Published
2019
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