Defects by design: synthesis of palladium nanoparticles with extended twin defects and corrugated surfaces

King, Melissa E.; Personick, Michelle L.

doi:10.1039/c7nr06969c

Cited by 23 publications

(38 citation statements)

References 41 publications

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“…We used this method to directly replicate on an electrode surface and in the absence of a chemical reducing agenta previously reported colloidal synthesis from our group for corrugated Pd nanoparticles. 39 This electrochemical method was further applied to understand the effects of changing the growth solution conditions in the electrochemical environment. Modification of most growth solution components showed similar effects to what is observed in the colloidal reaction, but the differencessuch as a limited effect of changing surfactant concentration and independence from pH effectsare explored.…”

Section: Introductionmentioning

confidence: 99%

An Integrated Electrochemistry Approach to the Design and Synthesis of Polyhedral Noble Metal Nanoparticles

et al. 2020

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The synthesis of shaped metal nanoparticles to meet the precise needs of emerging applications requires intentional synthetic design directed by fundamental chemical principles. We report an integrated electrochemistry approach to nanoparticle synthetic design that couples current-driven growth of metal nanoparticles on an electrode surfacein close analogy to standard colloidal synthesiswith electrochemical measurements of both electrochemical and colloidal nanoparticle growth. A simple chronopotentiometry method was used to translate an existing colloidal synthesis for corrugated palladium (Pd) nanoparticles to electrochemical growth on a glassy carbon electrode, with minimal modification to the growth solution. The electrochemical synthesis method was then utilized to produce large Pd icosahedra, a shape whose synthesis is challenging in a colloidal growth environment. This electrochemical synthesis for Pd icosahedra was used to develop a corresponding colloidal growth solution by tailoring a weak reducing agent to the measured potential profile of the electrochemical synthesis. Finally, measurements of colloidal syntheses were employed as guides for the directed design of electrochemical syntheses for Pd cubes and octahedra. Together, this work provides a cyclical approach to shaped nanoparticle design that allows for the optimization of nanoparticles grown via a colloidal approach with a chemical reducing agent or synthesized with an applied current on an electrode surface as well as subsequent bidirectional translation between the two methods. The enhanced chemical flexibility and direct tunability of this electrochemical method relative to combinatorial design of colloidal syntheses have the potential to accelerate the synthetic design process for noble metal nanoparticles with targeted morphologies.

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Section: Introductionmentioning

confidence: 99%

An Integrated Electrochemistry Approach to the Design and Synthesis of Polyhedral Noble Metal Nanoparticles

et al. 2020

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“…synthesized shaped palladium nanoparticles via a seeded method by directly applying a current – rather than a voltage – in a chemical growth environment that closely mimicked that of the colloidal nanoparticle syntheses [24] . The authors specifically designed electrochemical synthesis conditions for multiply twinned corrugated palladium nanoparticles in which the composition of the growth solution mirrored a published colloidal synthesis [40] with the exception of the chemical reducing agent. The multiply twinned corrugated particles were produced beginning with palladium seeds synthesized via a standard colloidal synthesis in a cetyltrimethylammonium bromide (CTAB) surfactant using sodium borohydride (NaBH 4 ) as a strong reducing agent [24] .…”

Section: Syntheses Of Shaped Monometallic Nanoparticlesmentioning

confidence: 99%

Potential‐Controlled (R)Evolution: Electrochemical Synthesis of Nanoparticles with Well‐Defined Shapes

McDarby

Personick

2021

ChemNanoMat

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To enable the rational design of synthetic approaches for producing precisely defined nanomaterials, a detailed mechanistic understanding needs to be established. Colloidal approaches to nanoparticle growth have been used to produce many novel shape‐ and composition‐controlled nanoparticles with various important target applications. Concurrently, electrochemical approaches to nanoparticle synthesis have also been developed, though at present this field is less expansive than colloidal synthesis. This review covers recent progress in the synthesis of shaped metal, metal oxide, and alloyed nanoparticles via electrochemical methods that use specific control of potential or current in combination with tailoring of the chemical growth solution environment. These approaches have produced nanoparticles with compositions and architectures that were inaccessible via standard colloidal approaches. Importantly, electrochemical nanoparticle synthesis can also serve as a powerful tool for understanding fundamental mechanisms of colloidal nanoparticle growth. We highlight multiple promising opportunities in this growing research area.

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“…The shape attributes of a metal nanoparticle (mNP) determine many of its physical, chemical, and functional properties, including plasmonic behavior, − catalytic efficiency, − and biological activity. , Significant research effort has focused on developing methods for the shape-controlled synthesis of mNPs, and an accurate and efficient method for their characterization has been indispensable for the success achieved by these studies. − To date, transmission electron microscopy (TEM) remains the most reliable and widely used method for characterizing the morphology of NPs, for which rapid advancement in automated high-throughput electron microscopy has drastically increased both the acquisition rate and the quality of TEM data. − Increased efficiency in TEM data acquisition now enables the scale of NP shape characterization to increase from tens or hundreds of particles to orders of magnitude more, extracting information at the level of more informative statistical distributions . The information from TEM data at such a scale far exceeds the capability of a human analyst, and hence, the development of automated methods for TEM image analysis is imperative.…”

Section: Introductionmentioning

confidence: 99%

AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles

Wang

et al. 2021

JACS Au

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The synthesis quality of artificial inorganic nanocrystals is most often assessed by transmission electron microscopy (TEM) for which high-throughput advances have dramatically increased both the quantity and information richness of metal nanoparticle (mNP) characterization. Existing automated data analysis algorithms of TEM mNP images generally adopt a supervised approach, requiring a significant effort in human preparation of labeled data that reduces objectivity, efficiency, and generalizability. We have developed an unsupervised algorithm AutoDetect-mNP for automated analysis of TEM images that objectively extracts morphological information on convex mNPs from TEM images based on their shape attributes, requiring little to no human input in the process. The performance of AutoDetect-mNP is tested on two data sets of bright field TEM images of Au nanoparticles with different shapes and further extended to palladium nanocubes and cadmium selenide quantum dots, demonstrating that the algorithm is quantitatively reliable and can thus serve as a generalizable measure of the morphology distributions of any mNP synthesis. The AutoDetect-mNP algorithm will aid in future developments of high-throughput characterization of mNPs and the future advent of time-resolved TEM studies that can investigate reaction mechanisms of mNP synthesis and reactivity.

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Defects by design: synthesis of palladium nanoparticles with extended twin defects and corrugated surfaces

Cited by 23 publications

References 41 publications

An Integrated Electrochemistry Approach to the Design and Synthesis of Polyhedral Noble Metal Nanoparticles

An Integrated Electrochemistry Approach to the Design and Synthesis of Polyhedral Noble Metal Nanoparticles

Potential‐Controlled (R)Evolution: Electrochemical Synthesis of Nanoparticles with Well‐Defined Shapes

AutoDetect-mNP: An Unsupervised Machine Learning Algorithm for Automated Analysis of Transmission Electron Microscope Images of Metal Nanoparticles

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