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1. Atomistic insights into the nucleation and growth of platinum on palladium nanocrystals

Author

Wenpei Gao, Ahmed O. Elnabawy, Zachary D. Hood, Yifeng Shi, Xue Wang, Luke T. Roling, Xiaoqing Pan, Manos Mavrikakis, Younan Xia, and Miaofang Chi

Subjects
Science
Abstract

Creating predictable, controllable nanoparticles relies on a mechanistic understanding of their synthesis. Here, through integrated in situ liquid microscopy and first-principles calculations, the authors elucidate the atomistic details involved in the formation of colloidal core-shell nanoparticles.

Published
2021
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2. Towards first-principles molecular design of liquid crystal-based chemoresponsive systems

Author

Luke T. Roling, Jessica Scaranto, Jeffrey A. Herron, Huaizhe Yu, Sangwook Choi, Nicholas L. Abbott, and Manos Mavrikakis

Subjects
Science
Abstract

Nematic liquid crystals have potential as sensors for various molecules. Here, the authors present a computational chemistry model for describing the detection of a warfare agent by liquid crystals, opening the door for the atomic-scale design of sensitive and selective chemoresponsive systems.

Published
2016
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3. Colloidally Engineered Pd and Pt Catalysts Distinguish Surface- and Vapor-Mediated Deactivation Mechanisms

Author

Jinwon Oh, Arik Beck, Emmett D. Goodman, Luke T. Roling, Anthony Boucly, Luca Artiglia, Frank Abild-Pedersen, Jeroen A. van Bokhoven, and Matteo Cargnello

Subjects
General Chemistry, sintering, Ostwald ripening, deactivation, supported catalysts, colloidal nanocrystal, Catalysis
Abstract

Noble metal-based catalysts are ubiquitous because of their high activity and stability. However, they irreversibly deteriorate over time especially in high-temperature applications. In these conditions, sintering is the main reason for deactivation, and understanding how sintering occurs gives the opportunity to mitigate these detrimental processes. Previous studies successfully distinguished between two fundamental sintering modes, namely, particle migration and coalescence (PMC) and Ostwald ripening (OR). However, differentiation between surface- and vapor-mediated Ostwald ripening processes has not been demonstrated yet, even though it is crucial information to tune metal/support interactions and stabilize catalysts. Here, we demonstrate that surface- and vapor-mediated ripening occur in two distinct regimes of temperature with some overlap using Pt and Pd catalysts prepared from colloidal nanocrystals as precursors. By either co-impregnating the two metal nanocrystals on the same grain of alumina support or by physically mixing powders of the two distinct metal catalysts, we tune the intermetal particle distance between nanometers and micrometers. We then use methane complete oxidation as a reporter reaction that occurs at higher rates on pure Pd and lower rates on alloyed Pd/Pt catalysts to trace the movement of Pt in the system. Aging the catalysts at different temperatures allows us to reveal that Pt initially sinters by surface-mediated ripening until ∼750 °C, but at temperatures above 800 °C, vapor-mediated ripening by PtO2 becomes the main sintering mechanism. This work demonstrates how colloidal catalysts allow unique insights into the working and deactivation mechanisms of supported systems. ISSN:2155-5435

Published
2023
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9. Local Structural Disorder in Metavanadates MV2O6 (M = Zn and Cu) Synthesized by the Deep Eutectic Solvent Route: Photoactive Oxides with Oxygen Vacancies

Author

Ye Cheng, Emily A. Smith, Sangki Hong, Julia V. Zaikina, Sadie J. Burkhow, Bradley J. Ryan, Luke T. Roling, Frank E. Osterloh, Matthew G. Panthani, Rachel M. Doughty, and Aishwarya Mantravadi

Subjects
Materials science, Hydrogen bond, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Oxygen, Acceptor, 0104 chemical sciences, Deep eutectic solvent, Metal, chemistry.chemical_compound, chemistry, visual_art, Materials Chemistry, visual_art.visual_art_medium, 0210 nano-technology, Dissolution
Abstract

Metavanadates MV2O6−δ (M = Zn and Cu) are synthesized by using a deep eutectic solvent (DES), a mixture of hydrogen bond donor and acceptor, as a reaction medium. Dissolution of stable binary metal...

Published
2021
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10. Revealing the structure of a catalytic combustion active-site ensemble combining uniform nanocrystal catalysts and theory insights

Author

Cody J. Wrasman, Ansgar Schäfer, Roel S. Sánchez-Carrera, Emmett D. Goodman, Frank Abild-Pedersen, Yuejin Li, Hassan Aljama, Luke T. Roling, Verena Streibel, An-Chih Yang, Simon R. Bare, Tej S. Choksi, Matteo Cargnello, and Dionne Thomas

Subjects
Multidisciplinary, Materials science, biology, Interface and colloid science, Active site, Nanoparticle, Catalytic combustion, Combustion, Catalysis, Propene, chemistry.chemical_compound, Nanocrystal, chemistry, Chemical physics, Physical Sciences, biology.protein
Abstract

Supported metal catalysts are extensively used in industrial and environmental applications. To improve their performance, it is crucial to identify the most active sites. This identification is, however, made challenging by the presence of a large number of potential surface structures that complicate such an assignment. Often, the active site is formed by an ensemble of atoms, thus introducing further complications in its identification. Being able to produce uniform structures and identify the ones that are responsible for the catalyst performance is a crucial goal. In this work, we utilize a combination of uniform Pd/Pt nanocrystal catalysts and theory to reveal the catalytic active-site ensemble in highly active propene combustion materials. Using colloidal chemistry to exquisitely control nanoparticle size, we find that intrinsic rates for propene combustion in the presence of water increase monotonically with particle size on Pt-rich catalysts, suggesting that the reaction is structure dependent. We also reveal that water has a near-zero or mildly positive reaction rate order over Pd/Pt catalysts. Theory insights allow us to determine that the interaction of water with extended terraces present in large particles leads to the formation of step sites on metallic surfaces. These specific step-edge sites are responsible for the efficient combustion of propene at low temperature. This work reveals an elusive geometric ensemble, thus clearly identifying the active site in alkene combustion catalysts. These insights demonstrate how the combination of uniform catalysts and theory can provide a much deeper understanding of active-site geometry for many applications.

Published
2020
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11. Intermetallic Nanocatalyst for Highly Active Heterogeneous Hydroformylation

Author

Claudio W Ordonez, Luke T. Roling, Andrew R Lamkins, Biying Zhang, Minda Chen, Charles J Ward, Wenyu Huang, Celia A Abolafia, and Geet Gupta

Subjects
chemistry.chemical_classification, Olefin fiber, Chemistry, General Chemistry, Reaction intermediate, Heterogeneous catalysis, Biochemistry, Aldehyde, Combinatorial chemistry, Catalysis, Colloid and Surface Chemistry, Chemoselectivity, Selectivity, Hydroformylation
Abstract

Hydroformylation is an imperative chemical process traditionally catalyzed by homogeneous catalysts. Designing a heterogeneous catalyst with high activity and selectivity in hydroformylation is challenging but essential to allow the convenient separation and recycling of precious catalysts. Here, we report the development of an outstanding catalyst for efficient heterogeneous hydroformylation, RhZn intermetallic nanoparticles. In the hydroformylation of styrene, it shows three times higher turnover frequency (3090 h-1) compared to the benchmark homogeneous Wilkinson's catalyst (966 h-1), as well as a high chemoselectivity toward aldehyde products. RhZn is active for a variety of olefin substrates and can be recycled without a significant loss of activity. Density functional theory calculations show that the RhZn surfaces reduce the binding strength of reaction intermediates and have lower hydroformylation activation energy barriers compared to pure Rh(111), leading to more favorable reaction energetics on RhZn. The calculations also predict potential catalyst design strategies to achieve high regioselectivity.

Published
2021

12. Anisotropic Disorder and Thermal Stability of Silicane

Author

Bradley J. Ryan, Matthew G. Panthani, and Luke T. Roling

Subjects
Amorphous silicon, Photoluminescence, Materials science, Silicon, business.industry, Scanning electron microscope, General Engineering, General Physics and Astronomy, Infrared spectroscopy, chemistry.chemical_element, Characterization (materials science), chemistry.chemical_compound, chemistry, X-ray photoelectron spectroscopy, Optoelectronics, General Materials Science, Photonics, business
Abstract

Atomically thin silicon nanosheets (SiNSs), such as silicane, have potential for next-generation computing paradigms, such as integrated photonics, owing to their efficient photoluminescence emission and complementary-metal-oxide-semiconductor (CMOS) compatibility. To be considered as a viable material for next-generation photonics, the SiNSs must retain their structural and optical properties at operating temperatures. However, the intersheet disorder of SiNSs and their nanoscale structure makes structural characterization difficult. Here, we use synchrotron X-ray diffraction and atomic pair distribution function (PDF) analysis to characterize the anisotropic disorder within SiNSs, demonstrating they exhibit disorder within the intersheet spacing, but have little translational or rotational disorder among adjacent SiNSs. Furthermore, we identify changes in their structural, chemical, and optical properties after being heated in an inert atmosphere up to 475 °C. We characterized changes of the annealed SiNSs using synchrotron-based total X-ray scattering, infrared spectroscopy, X-ray photoelectron spectroscopy, scanning electron microscopy, electron paramagnetic resonance, absorbance, photoluminescence, and excited-state lifetime. We find that the silicon framework is robust, with an onset of amorphization at ∼300 °C, which is well above the required operating temperatures of photonic devices. Above ∼300 °C, we demonstrate that the SiNSs begin to coalesce while keeping their translational alignment to yield amorphous silicon nanosheets. In addition, our DFT results provide information on the structure, energetics, band structures, and vibrational properties of 11 distinct oxygen-containing SiNSs. Overall, these results provide critical information for the implementation of atomically thin silicon nanosheets in next-generation CMOS-compatible integrated photonic devices.

Published
2021

13. Unraveling the Pathways of Electrochemical Reduction of Furfural Via Tailoring Microenvironments

Author

Hengzhou Liu, Deep Patel, Yifu Chen, Jungkuk Lee, Luke T. Roling, and Wenzhen Li

Abstract

Electrochemical reduction of biomass-derived feedstocks holds great promise to produce value-added chemicals or fuels driven by renewable electricity. However, mechanistic understanding of the aldehyde reduction toward valuable products at the molecular level within the interfacial regions is still lacking. Herein, through tailoring the local environments, including H/D composition and local H3O+ and H2O content, we studied the furfural reduction on Pb electrodes in acid conditions and elucidated the detailed pathways toward three key products: furfuryl alcohol (FA), 2-methylfuran (MF), and hydrofuroin. By combining isotopic labeling and electrokinetic studies, we revealed the source of protons (H2O and H3O+) plays a critical but different role in the hydrogenation and hydrogenolysis pathways toward FA and MF, respectively. In particular, the product-selective kinetic isotopic effect of H/D and the surface property-dependent hydrogenation/deuteration pathway strongly impacted the generation of FA but not MF. This is because FA and MF are produced from Langmuir-Hinshelwood and Eley-Rideal pathways, respectively. Through modifying the double layer by cations with large radii, we further correlated the product selectivity (FA and MF) qualitatively and quantitively with interfacial environments (local H3O+ and H2O content, interfacial electric field, and differential capacitances). Experimental and computational investigations further suggested competitive pathways toward hydrofuroin and FA: Hydrofuroin is favorably produced through the self-coupling of ketyl radicals in the electrolyte, which are formed from the outer-sphere single-electron transfers, while FA is generated from hydrogenation of the adsorbed furfural/ketyl radical on the electrode surface.

Published
2022
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14. Atomistic insights into the nucleation and growth of platinum on palladium nanocrystals

Author

Younan Xia, Xue Wang, Manos Mavrikakis, Yifeng Shi, Wenpei Gao, Xiaoqing Pan, Ahmed O. Elnabawy, Miaofang Chi, Luke T. Roling, and Zachary D. Hood

Subjects
Materials science, Science, Diffusion, Nucleation, General Physics and Astronomy, chemistry.chemical_element, 02 engineering and technology, 010402 general chemistry, Characterization and analytical techniques, 01 natural sciences, Article, General Biochemistry, Genetics and Molecular Biology, Colloid, Bimetallic strip, Multidisciplinary, Synthesis and processing, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, chemistry, Nanocrystal, Chemical physics, Transmission electron microscopy, Nanoparticles, 0210 nano-technology, Platinum, Palladium
Abstract

Despite the large number of reports on colloidal nanocrystals, very little is known about the mechanistic details in terms of nucleation and growth at the atomistic level. Taking bimetallic core-shell nanocrystals as an example, here we integrate in situ liquid-cell transmission electron microscopy with first-principles calculations to shed light on the atomistic details involved in the nucleation and growth of Pt on Pd cubic seeds. We elucidate the roles played by key synthesis parameters, including capping agent and precursor concentration, in controlling the nucleation site, diffusion path, and growth pattern of the Pt atoms. When the faces of a cubic seed are capped by Br−, Pt atoms preferentially nucleate from corners and then diffuse to edges and faces for the creation of a uniform shell. The diffusion does not occur until the Pt deposited at the corner has reached a threshold thickness. At a high concentration of the precursor, self-nucleation takes place and the Pt clusters then randomly attach to the surface of a seed for the formation of a non-uniform shell. These atomistic insights offer a general guideline for the rational synthesis of nanocrystals with diverse compositions, structures, shapes, and related properties., Creating predictable, controllable nanoparticles relies on a mechanistic understanding of their synthesis. Here, through integrated in situ liquid microscopy and first-principles calculations, the authors elucidate the atomistic details involved in the formation of colloidal core-shell nanoparticles.

Published
2021
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15. Silicene, Siloxene, or Silicane? Revealing the Structure and Optical Properties of Silicon Nanosheets Derived from Calcium Disilicide

Author

Emily A. Smith, Zhaoyu Liu, Bevan Whitehead, Jigang Wang, Luke T. Roling, Rainie D. Nelson, Charles K. A. Nyamekye, Yujie Wang, Chuankun Huang, Bradley J. Ryan, Aaron J. Rossini, Matthew G. Panthani, Utkarsh Ramesh, and Michael P. Hanrahan

Subjects
Materials science, Silicon, Spintronics, Silicene, General Chemical Engineering, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, General Chemistry, Calcium, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, chemistry, Materials Chemistry, 0210 nano-technology
Abstract

Si-nanosheets (Si-NSs) have recently attracted considerable attention due to their potential as next-generation materials for electronic, optoelectronic, spintronic, and catalytic applications. Eve...

Published
2019
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16. A coordination-based model for transition metal alloy nanoparticles

Author

Tej S. Choksi, Luke T. Roling, and Frank Abild-Pedersen

Subjects
Materials science, Coordination number, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Heterogeneous catalysis, 01 natural sciences, 0104 chemical sciences, Metal, Adsorption, Transition metal, Chemical physics, visual_art, Atom, visual_art.visual_art_medium, General Materials Science, 0210 nano-technology, Bimetallic strip
Abstract

We present a simple approach for predicting the relative energies of bimetallic nanoparticles spanning a wide-ranging combinatorial space, using only the identity and nearest-neighbor coordination number of individual metal atoms as independent parameters. By performing straightforward metal atom adsorption calculations on surface slab models, we parameterize expressions for the energy of metal atoms as a function of their coordination number in 21 bimetallic pairings of fcc metals. We rigorously establish the transferability of our model by predicting relative energies of a series of nanoparticles across a large number of morphologies, sizes, atomic compositions, and arrangements. The model is particularly accurate in predicting atomic rearrangements at or near the metal surfaces, which is essential for its potential applications when studying segregation phenomena or dynamic processes in heterogeneous catalysis. By rapidly forecasting site stabilities with atomic specificity across generic structural and compositional features, our model is able to reverse engineer thermodynamically feasible motifs of active sites in bimetallic nanoparticles through robust property ⇔ structure relations.

Published
2019
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17. Elucidating Pathways to Electrochemical Reduction of Furfural Via Tailoring Interfacial Environments Toward Selective Production of Valuable Furanic Chemicals

Author

Hengzhou Liu, Deep Patel, Yifu Chen, Luke T. Roling, and Wenzhen Li

Abstract

Electrochemical reduction of biomass-derived feedstocks holds great promise to produce value-added chemicals or fuels driven by renewable electricity. However, mechanistic understanding of the aldehyde reduction toward valuable products at the electrode/electrolyte interface at the molecular level is still lacking. Herein, we studied the furfural reduction on Pb electrodes in acid conditions and elucidated the detailed pathways toward three key products: furfuryl alcohol (FA), 2-methylfuran (MF), and hydrofuroin. First, by coupling isotopic labeling and electrokinetics, we revealed that protons (H2O and H3O+) plays an important role in the hydrogenation pathway toward FA and MF. In particular, the study of product-selective kinetic isotopic effect of H/D and the surface property-dependent hydrogenation/deuteration pathway strongly impacted the generation of FA but not MF, which can be attributed to their different formation mechanisms: FA is produced from Langmuir-Hinshelwood pathway that need both adsorbed furfural and hydrogen, but MF produced from Eley-Rideal pathway that need proton directly from the electrolyte. Modifying the double layer by cations with large radii, we further correlated the product selectivity (FA and MF) with interfacial environments (local H3O+ and H2O content, etc). Combined methods, including pulsed electrolysis, electron paramagnetic resonance (EPR) spectroscopy, and DFT calculations, further suggested that the formation of hydrofuroin and FA shared one intermediate. Hydrofuroin is produced through the desorption of the intermediate as ketyl radicals followed by its self-coupling in the electrolyte, while FA is generated from further hydrogenation of that intermediate. The acquired into the electrochemical reduction of the aldehyde group in furfural to alcohol, alkyl, and dimer may be extended to other organic compounds with carbonyl group, such as 5-hydromethylfurfural, toward a sustainable electrochemical manufacturing of higher-valued chemicals from biomass feedstock.

Published
2022
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19. Structure‐Sensitive Scaling Relations: Adsorption Energies from Surface Site Stability

Author

Frank Abild-Pedersen and Luke T. Roling

Subjects
Surface (mathematics), Materials science, Coordination number, Organic Chemistry, Nanoparticle, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Heterogeneous catalysis, 01 natural sciences, Catalysis, 0104 chemical sciences, Inorganic Chemistry, Adsorption, Transition metal, Chemical physics, Density functional theory, Physical and Theoretical Chemistry, 0210 nano-technology, Scaling
Published
2018
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21. Configurational Energies of Nanoparticles Based on Metal–Metal Coordination

Author

Frank Abild-Pedersen, Luke T. Roling, and Lin Li

Subjects
Materials science, Sintering, Nanoparticle, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Heterogeneous catalysis, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Catalysis, Metal, General Energy, Adsorption, Chemical physics, visual_art, Atom, visual_art.visual_art_medium, Density functional theory, Physical and Theoretical Chemistry, 0210 nano-technology
Abstract

Nanoparticle sintering remains a fundamental problem in heterogeneous catalysis, motivating mechanistic studies toward mitigating deactivation of precious metal catalysts. We present a model based on the local coordination environment of metal atoms that can be used to provide total energy estimates for metal nanoparticles in a space of generic configurations. All energies are based only on a small set of density functional theory calculations of single metal atom adsorption on metal slabs. A model that can provide accurate nanoparticle energies is an important step toward the goal of understanding their sintering behavior in practical catalytic contexts.

Published
2017
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22. Understanding the Thermal Stability of Palladium–Platinum Core–Shell Nanocrystals by In Situ Transmission Electron Microscopy and Density Functional Theory

Author

Luke T. Roling, Manos Mavrikakis, Xue Wang, Madeline Vara, Miaofang Chi, Zachary D. Hood, Younan Xia, and Ahmed O. Elnabawy

Subjects
Materials science, General Engineering, General Physics and Astronomy, chemistry.chemical_element, Nanotechnology, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Heterogeneous catalysis, 01 natural sciences, 0104 chemical sciences, chemistry, Chemical engineering, Nanocrystal, General Materials Science, Thermal stability, Density functional theory, Facet, 0210 nano-technology, Platinum, Nanoscopic scale, Palladium
Abstract

Core–shell nanocrystals offer many advantages for heterogeneous catalysis, including precise control over both the surface structure and composition, as well as reduction in loading for rare and costly metals. Although many catalytic processes are operated at elevated temperatures, the adverse impacts of heating on the shape and structure of core–shell nanocrystals are yet to be understood. In this work, we used ex situ heating experiments to demonstrate that Pd@Pt4L core–shell nanoscale cubes and octahedra are promising for catalytic applications at temperatures up to 400 °C. We also used in situ transmission electron microscopy to monitor the thermal stability of the core–shell nanocrystals in real time. Our results demonstrate a facet dependence for the thermal stability in terms of shape and composition. Specifically, the cubes enclosed by {100} facets readily deform shape at a temperature 300 °C lower than that of the octahedral counterparts enclosed by {111} facets. A reversed trend is observed for ...

Published
2017
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23. Thermal Stability of Metal Nanocrystals: An Investigation of the Surface and Bulk Reconstructions of Pd Concave Icosahedra

Author

Luke T. Roling, Manos Mavrikakis, Younan Xia, Tung-Han Yang, Ahmed O. Elnabawy, Kyle D. Gilroy, and Jane Y. Howe

Subjects
Materials science, Mechanical Engineering, Bioengineering, 02 engineering and technology, General Chemistry, Crystal structure, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Crystallography, Nanocrystal, Chemical physics, Transmission electron microscopy, Metastability, General Materials Science, Density functional theory, Icosahedron, Thermal stability, 0210 nano-technology, Surface reconstruction
Abstract

Despite the remarkable success in controlling the synthesis of metal nanocrystals, it still remains a grand challenge to stabilize and preserve the shapes or internal structures of metastable kinetic products. In this work, we address this issue by systematically investigating the surface and bulk reconstructions experienced by a Pd concave icosahedron when subjected to heating up to 600 °C in vacuum. We used in situ high-resolution transmission electron microscopy to identify the equilibration pathways of this far-from-equilibrium structure. We were able to capture key structural transformations occurring during the thermal annealing process, which were mechanistically rationalized by implementing self-consistent plane-wave density functional theory (DFT) calculations. Specifically, the concave icosahedron was found to evolve into a regular icosahedron via surface reconstruction in the range of 200-400 °C, and then transform into a pseudospherical crystalline structure through bulk reconstruction when further heated to 600 °C. The mechanistic understanding may lead to the development of strategies for enhancing the thermal stability of metal nanocrystals.

Published
2017
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24. Design of Chemoresponsive Liquid Crystals through Integration of Computational Chemistry and Experimental Studies

Author

Nicholas L. Abbott, Tibor Szilvási, Luke T. Roling, Huaizhe Yu, Robert J. Twieg, Manos Mavrikakis, Prabin Rai, and Sang Wook Choi

Subjects
General Chemical Engineering, 02 engineering and technology, General Chemistry, Electronic structure, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Ion, Metal, Perchlorate, chemistry.chemical_compound, chemistry, Competitive binding, Liquid crystal, Computational chemistry, visual_art, Materials Chemistry, visual_art.visual_art_medium, 0210 nano-technology
Abstract

We report the use of computational chemistry methods to design a chemically responsive liquid crystal (LC). Specifically, we used electronic structure calculations to model the binding of nitrile-containing mesogens (4′-n-pentyl-4-biphenylcarbonitrile) to metal perchlorate salts (with explicit description of the perchlorate anion), which we call the coordinately saturated anion model (CSAM). The model results were validated against experimental data. We then used the CSAM to predict that selective fluorination can reduce the strength of binding of nitrile-containing nematic LCs to metal-salt-decorated surfaces and thus generate a faster reordering of the LC in response to competitive binding of dimethylmethylphosphonate (DMMP). We tested this prediction via synthesis of fluorinated compounds 3-fluoro-4′-pentyl[1,1′-biphenyl]-4-carbonitrile and 4-fluoro-4′-pentyl-1,1′-biphenyl, and subsequent experimental measurements of the orientational response of LCs containing these compounds to DMMP. These experiment...

Published
2017
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25. Toward rational nanoparticle synthesis: predicting surface intermixing in bimetallic alloy nanocatalysts

Author

Manos Mavrikakis and Luke T. Roling

Subjects
Materials science, Nanoparticle, Surface hopping, 02 engineering and technology, Activation energy, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Nanomaterial-based catalyst, 0104 chemical sciences, Nanocrystal, Computational chemistry, Chemical physics, Atom, General Materials Science, Diffusion (business), 0210 nano-technology, Bimetallic strip
Abstract

We present a database of first-principles calculated activation energy barriers for two competitive processes involving bimetallic adatom-surface permutations of ten transition metals: (i) adatom "hopping" diffusion and (ii) adatom substitution into the surface. We consider the surface structure sensitivity of these events as well as coverage effects. We find that surface hopping mechanisms are facile and always preferred to substitution events on close-packed fcc(111) and hcp(0001) surfaces. However, surface atom substitution is more facile on the more open fcc(100) surfaces and is competitive with adatom surface hopping, which is more difficult than on the close-packed surfaces. By comparing the absolute and relative magnitudes of the energetics of hopping and substitution, our calculations can offer qualitative predictions of intermixing and other phenomena relevant to nanocrystal growth, such as the tendency to form intermixed alloys or core-shell structures during layer-by-layer nanoparticle synthesis involving a given bimetallic pair, and thereby inform the rational design and synthesis of novel bimetallic nanomaterials.

Published
2017
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26. Predicting Adsorption Properties of Catalytic Descriptors on Bimetallic Nanoalloys with Site-Specific Precision

Author

Luke T. Roling, Verena Streibel, Tej S. Choksi, and Frank Abild-Pedersen

Subjects
Materials science, biology, Alloy, Binding energy, Active site, Nanoparticle, 02 engineering and technology, Metal adsorption, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Catalysis, Adsorption, Chemical physics, engineering, biology.protein, General Materials Science, Physical and Theoretical Chemistry, 0210 nano-technology, Bimetallic strip
Abstract

Bimetallic nanoparticles present a vastly tunable structural and compositional design space rendering them promising materials for catalytic and energy applications. Yet it remains an enduring challenge to efficiently screen candidate alloys with atomic level specificity while explicitly accounting for their inherent stabilities under reaction conditions. Herein, by leveraging correlations between binding energies of metal adsorption sites and metal-adsorbate complexes, we predict adsorption energies of typical catalytic descriptors (OH*, CH3*, CH*, and CO*) on bimetallic alloys with site-specific resolution. We demonstrate that our approach predicts adsorption energies on top and bridge sites of bimetallic nanoparticles having generic morphologies and chemical environments with errors between 0.09 and 0.18 eV. By forging a link between the inherent stability of an alloy and the adsorption properties of catalytic descriptors, we can now identify active site motifs in nanoalloys that possess targeted catalytic descriptor values while being thermodynamically stable under working conditions.

Published
2019

27. (Invited) Silicon Nanosheets as Candidates for Silicon-Based Optoelectronics

Author

Luke T. Roling, Carly J. Dolgos, Matthew G. Panthani, Yuqi Guo, Benjamin T. Diroll, Bradley J. Ryan, and Qing Hua Wang

Subjects
Photoluminescence, Materials science, Silicon, business.industry, Band gap, chemistry.chemical_element, Hardware_PERFORMANCEANDRELIABILITY, Atomic units, CMOS, chemistry, Monolayer, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, Thermal stability, Photonics, business
Abstract

Colloidal Group IV nanomaterials (Si, Ge, Sn and their alloys) are of great interest due to their potential to offer broadly tunable optical properties. By manipulating composition, size, or surface chemistry Group IV nanomaterials have potential to serve as nontoxic, earth abundant phosphors or semiconductors that can be used for optoelectronic applications that span the ultraviolet to the mid-infrared spectral ranges. The synthesis of colloidal Group IV nanostructures is challenging due to the highly covalent character of Si and Ge, and typically require temperatures in excess of 400°C to form crystalline particles. We have recently reported new synthetic methods for Si and Ge nanomaterials derived from precursors synthesized in the solid-state, including suboxides and Zintl phases. In each of these cases, colloidal nanostructures can be accessed by selectively removing unwanted components from the solid-state precursor, liberating nanostructures that are terminated with atomic or molecular species such as hydrogen atoms or methyl groups. We also characterize the structural properties of the Group IV nanostructures that we synthesized using a combination of infrared spectroscopy, solid-state NMR, and pair distribution function analysis to confirm the structure and order. In the case of Si and Ge, single-atom thick nanosheets were synthesized, their stability and decomposition at elevated temperatures were characterized. The optical properties of Group IV nanomaterials have sparked debate over the past few decades. We found that Si nanosheets exhibit fast (nanosecond) photoluminescence lifetime, which is several orders of magnitude greater than Si nanocrystals, and offer potential explanations for the observed difference. Finally we show that Si and Ge nanocrystals and nanosheets can be used for sensing applications, including infrared photodetectors and ionophore-based sensing schemes.

Published
2021
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28. Towards first-principles molecular design of liquid crystal-based chemoresponsive systems

Author

Jessica Scaranto, Manos Mavrikakis, Huaizhe Yu, Jeffrey A. Herron, Luke T. Roling, Nicholas L. Abbott, and Sang Wook Choi

Subjects
Materials science, Science, Binding energy, General Physics and Astronomy, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, General Biochemistry, Genetics and Molecular Biology, Article, Crystal, chemistry.chemical_compound, Liquid crystal, Molecule, Multidisciplinary, Dimethyl methylphosphonate, Response time, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Condensed Matter::Soft Condensed Matter, Chemical species, Benzonitrile, chemistry, Chemical physics, 0210 nano-technology
Abstract

Nematic liquid crystals make promising chemoresponsive systems, but their development is currently limited by extensive experimental screening. Here we report a computational model to understand and predict orientational changes of surface-anchored nematic liquid crystals in response to chemical stimuli. In particular, we use first-principles calculations to evaluate the binding energies of benzonitrile, a model for 4′-pentyl-4-biphenylcarbonitrile, and dimethyl methylphosphonate to metal cation models representing the substrate chemical sensing surface. We find a correlation between these quantities and the experimental response time useful for predicting the response time of cation–liquid crystal combinations. Consideration of charge donation from chemical species in the surface environment is critical for obtaining agreement between theory and experiment. Our model may be extended to the design of improved chemoresponsive liquid crystals for selectively detecting other chemicals of practical interest by choosing appropriate combinations of metal cations with liquid crystals of suitable molecular structure., Nematic liquid crystals have potential as sensors for various molecules. Here, the authors present a computational chemistry model for describing the detection of a warfare agent by liquid crystals, opening the door for the atomic-scale design of sensitive and selective chemoresponsive systems.

Published
2016

29. Dimethyl ether electro-oxidation on platinum surfaces

Author

Manos Mavrikakis, Jeffrey A. Herron, Peter Ferrin, Luke T. Roling, and Winny Budiman

Subjects
Reaction mechanism, Renewable Energy, Sustainability and the Environment, Chemistry, chemistry.chemical_element, 02 engineering and technology, Reaction intermediate, Overpotential, 010402 general chemistry, 021001 nanoscience & nanotechnology, Photochemistry, 01 natural sciences, 0104 chemical sciences, chemistry.chemical_compound, Transition metal, General Materials Science, Dehydrogenation, Dimethyl ether, Electrical and Electronic Engineering, 0210 nano-technology, Platinum, Bond cleavage
Abstract

A first-principles density functional theory study was performed to elucidate the mechanism of dimethyl ether electro-oxidation on three low-index platinum surfaces (Pt(111), Pt(100), and Pt(211)). The goal of this study is to provide a fundamental explanation for the high activity observed experimentally on Pt(100) compared to Pt(111) and stepped surfaces. We determine that the enhanced activity of Pt(100) stems from more facile C–O bond breaking kinetics, as well as from easier removal of CO as a surface poison through activation of water. In general, the C–O bond (in CH x OCH y ) becomes easier to break as dimethyl ether is dehydrogenated to a greater extent. In contrast, dehydrogenation becomes more difficult as more hydrogen atoms are removed. We perform two analyses of probable reaction pathways, which both identify CHOC and CO as the key reaction intermediates on these Pt surfaces. We show that the reaction mechanism on each surface is dependent on the cell operating potential, as increasing the potential facilitates C–H bond scission, in turn promoting the formation of intermediates for which C–O scission is more facile. We additionally demonstrate that CO oxidation determines the high overpotential required for electro-oxidation on Pt surfaces. At practical operating potentials (~0.60 V RHE ), we determine that C–O bond breaking is most likely the most difficult step on all three Pt surfaces studied.

Published
2016
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30. Synthesis and Characterization of Pt–Ag Alloy Nanocages with Enhanced Activity and Durability toward Oxygen Reduction

Author

Xuan Yang, Zachary D. Hood, Luke T. Roling, Ahmed O. Elnabawy, Younan Xia, Madeline Vara, Manos Mavrikakis, Ming Zhao, and Shixiong Bao

Subjects
Materials science, Mechanical Engineering, Alloy, Bioengineering, One-Step, Nanotechnology, 02 engineering and technology, General Chemistry, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Durability, Oxygen reduction, 0104 chemical sciences, Characterization (materials science), Catalysis, Nanocages, Chemical engineering, engineering, General Materials Science, Density functional theory, 0210 nano-technology
Abstract

Engineering the elemental composition of metal nanocrystals offers an effective strategy for the development of catalysts or electrocatalysts with greatly enhanced activity. Herein, we report the synthesis of Pt–Ag alloy nanocages with an outer edge length of 18 nm and a wall thickness of about 3 nm. Such nanocages with a composition of Pt19Ag81 could be readily prepared in one step through the galvanic replacement reaction between Ag nanocubes and a Pt(II) precursor. After 10 000 cycles of potential cycling in the range of 0.60–1.0 V as in an accelerated durability test, the composition of the nanocages changed to Pt56Ag44, together with a specific activity of 1.23 mA cm–2 toward oxygen reduction, which was 3.3 times that of a state-of-the-art commercial Pt/C catalyst (0.37 mA cm–2) prior to durability testing. Density functional theory calculations attributed the increased activity to the stabilization of the transition state for breaking the O–O bond in molecular oxygen. Even after 30 000 cycles of pot...

Published
2016
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31. Nature of Lone-Pair-Surface Bonds and Their Scaling Relations

Author

Luke T. Roling, Samira Siahrostami, Allegra A. Latimer, Arvin Kakekhani, Ambarish Kulkarni, Jens K. Nørskov, Julia Schumann, Hassan Aljama, Hadi Abroshan, Frank Abild-Pedersen, and Sohrab Ismail-Beigi

Subjects
Chemistry, Binding energy, Molecular binding, Ionic bonding, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Inorganic Chemistry, Chemical physics, Covalent bond, Single bond, Molecule, Density functional theory, Physical and Theoretical Chemistry, 0210 nano-technology, Lone pair
Abstract

We investigate the (surface) bonding of a class of industrially and biologically important molecules in which the chemically active orbital is a 2 p electron lone pair located on an N or O atom bound via single bonds to H or alkyl groups. This class includes water, ammonia, alcohols, ethers, and amines. Using extensive density functional theory (DFT) calculations, we discover scaling relations (correlations) among molecular binding energies of different members of this class: the bonding energetics of a single member can be used as a descriptor for other members. We investigate the bonding mechanism for a representative (H2O) and find the most important physical surface properties that dictate the strength and nature of the bonding through a combination of covalent and noncovalent electrostatic effects. We describe the importance of surface intrinsic electrostatic, geometric, and mechanical properties in determining the extent of the lone-pair-surface interactions. We study systems including ionic materials in which the surface positive and negative centers create strong local surface electric fields, which polarize the dangling lone pair and lead to a strong "electrostatically driven bond". We emphasize the importance of noncovalent electrostatic effects and discuss why a fully covalent picture, common in the current first-principles literature on surface bonding of these molecules, is not adequate to correctly describe the bonding mechanism and energy trends. By pointing out a completely different mechanism (charge transfer) as the major factor for binding N- and O-containing unsaturated (radical) adsorbates, we explain why their binding energies can be tuned independently from those of the aforementioned species, having potential implications in scaling-driven catalyst discovery.

Published
2018

32. Platinum-based nanocages with subnanometer-thick walls and well-defined, controllable facets

Author

Xue Wang, Jinho Park, Luke T. Roling, Zhaoxiong Xie, Lei Zhang, Jingyue Liu, Younan Xia, Sang-Il Choi, Manos Mavrikakis, Miaofang Chi, Madeline Vara, and Jeffrey A. Herron

Subjects
Multidisciplinary, Nanocages, chemistry, Nanocrystal, Octahedron, Chemical engineering, Etching (microfabrication), chemistry.chemical_element, Nanotechnology, Density functional theory, Platinum, Layer (electronics), Palladium
Abstract

Etching platinum nanocage catalysts Although platinum is an excellent catalyst for the oxygen reduction reaction that occurs in fuel cells, its scarcity continues to drive efforts to improve its utilization. Zhang et al. made nanocages of platinum by coating palladium nanocrystals with only a few layers of platinum and then etching away the palladium core (see the Perspective by Strasser). Platinum nanocages made using nanoscale octahedra and cubes of palladium displayed different catalytic activity for the oxygen reduction reaction. Science , this issue p. 412 ; see also p. 379

Published
2015
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33. Atomic Layer-by-Layer Deposition of Platinum on Palladium Octahedra for Enhanced Catalysts toward the Oxygen Reduction Reaction

Author

Luke T. Roling, Jinguo Wang, Manos Mavrikakis, Lei Zhang, Jinho Park, Younan Xia, Ning Lu, Moon J. Kim, Shuifen Xie, Jeffrey A. Herron, and Sang-Il Choi

Subjects
chemistry.chemical_classification, Inorganic chemistry, Layer by layer, General Engineering, General Physics and Astronomy, chemistry.chemical_element, Catalysis, Octahedron, chemistry, Polyol, Oxygen reduction reaction, General Materials Science, Density functional theory, Platinum, Palladium
Abstract

We systematically evaluated two different approaches to the syntheses of Pd@PtnL (n = 2-5) core-shell octahedra. We initially prepared the core-shell octahedra using a polyol-based route by titrating a Pt(IV) precursor into the growth solution containing Pd octahedral seeds at 200 °C through the use of a syringe pump. The number of Pt atomic layers could be precisely controlled from two to five by increasing the volume of the precursor solution while fixing the amount of seeds. We then demonstrated the synthesis of Pd@PtnL octahedra using a water-based route at 95 °C through the one-shot injection of a Pt(II) precursor. Due to the large difference in reaction temperature, the Pd@PtnL octahedra obtained via the water-based route showed sharper corners than their counterparts obtained through the polyol-based route. When compared to a commercial Pt/C catalyst based upon 3.2 nm Pt particles, the Pd@PtnL octahedra prepared using both methods showed similar remarkable enhancement in terms of activity (both specific and mass) and durability toward the oxygen reduction reaction. Calculations based upon periodic, self-consistent density functional theory suggested that the enhancement in specific activity for the Pd@PtnL octahedra could be attributed to the destabilization of OH on their PtnL*/Pd(111) surface relative to the {111} and {100} facets exposed on the surface of Pt/C. The destabilization of OH facilitates its hydrogenation, which was found to be the rate-limiting step of the oxygen reduction reaction on all these surfaces.

Published
2015
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34. Synthesis and Characterization of Ru Cubic Nanocages with a Face-Centered Cubic Structure by Templating with Pd Nanocubes

Author

Legna Figueroa-Cosme, Ming Zhao, Xuan Yang, Manos Mavrikakis, Ahmed O. Elnabawy, Miaofang Chi, Luke T. Roling, Younan Xia, and Madeline Vara

Subjects
Surface diffusion, Materials science, Mechanical Engineering, chemistry.chemical_element, Bioengineering, 02 engineering and technology, General Chemistry, Crystal structure, Cubic crystal system, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Dissociation (chemistry), 0104 chemical sciences, Catalysis, Ruthenium, Crystallography, Nanocages, chemistry, General Materials Science, Density functional theory, 0210 nano-technology
Abstract

Nanocages have received considerable attention in recent years for catalytic applications owing to their high utilization efficiency of atoms and well-defined facets. Here we report, for the first time, the synthesis of Ru cubic nanocages with ultrathin walls, in which the atoms are crystallized in a face-centered cubic (fcc) rather than hexagonal close-packed (hcp) structure. The key to the success of this synthesis is to ensure layer-by-layer deposition of Ru atoms on the surface of Pd cubic seeds by controlling the reaction temperature and the injection rate of a Ru(III) precursor. By selectively etching away the Pd from the Pd@Ru core-shell nanocubes, we obtain Ru nanocages with an average wall thickness of 1.1 nm or about six atomic layers. Most importantly, the Ru nanocages adopt an fcc crystal structure rather than the hcp structure observed in bulk Ru. The synthesis has been successfully applied to Pd cubic seeds with different edge lengths in the range of 6-18 nm, with smaller seeds being more favorable for the formation of Ru shells with a flat, smooth surface due to shorter distance for the surface diffusion of the Ru adatoms. Self-consistent density functional theory calculations indicate that these unique fcc-structured Ru nanocages might possess promising catalytic properties for ammonia synthesis compared to hcp Ru(0001), on the basis of strengthened binding of atomic N and substantially reduced activation energies for N2 dissociation, which is the rate-determining step for ammonia synthesis on hcp Ru catalysts.

Published
2016

35. (Keynote) Theoretical Inspirations from Radoslav Adzic’s Electrocatalysis Work

Author

Manos Mavrikakis, Ahmed O. Elnabawy, Luke T. Roling, and Jeff A. Herron

Abstract

When combined with controlled synthesis of well-defined facets and shapes, density functional theory (DFT) could give especially accurate descriptions of electrocatalytic reactions on surfaces. Dr. Adzic’s group has pioneered the controlled and uniform deposition of a monolayer (or overlayers) of Pt on a single crystal or nanoparticles of another transition metal or transition metal alloys.1-6 Not only does this morphology achieve better utilization of the overlying Pt atoms, but the resulting structures also possess remarkable stability as electrocatalysts. Here, we review our long-standing collaboration with Dr. Adzic on the oxygen reduction reaction (ORR) over Pt monolayer or overlayers atop a variety of transition metals5,7-12, as well as the electrooxidation of formic acid on Pt monolayers on single-crystals of transition metals. A logical extension of this methodology is to support Pt overlayers atop shape-selected nanoparticles, which selectively expose well-defined facets. Time-permitting, we will also be discussing insights from studying ORR of Pt overlayers on Pd icosahedra13, octahedra14, and nanocubes15. In several cases, the induced compressive strain and ligand effects that the Pt monolayer or overlayers experience on various substrates weaken the adsorption of oxygenated species (e.g.: OH) compared to pure Pt, thereby enhancing the ORR activity. Zhang J, Mo Y, Vukmirovic MB, Klie R, Sasaki K, Adzic RR. Platinum monolayer electrocatalysts for O-2 reduction: Pt monolayer on Pd(111) and on carbon-supported Pd nanoparticles. J. Phys. Chem. B. Jul 29 2004;108(30):10955-10964. Sasaki K, Naohara H, Cai Y, et al. Core-Protected Platinum Monolayer Shell High-Stability Electrocatalysts for Fuel-Cell Cathodes. Angew. Chem. Int. Ed. 2010;49(46):8602-8607. Adzic R. Platinum Monolayer Electrocatalysts: Tunable Activity, Stability, and Self-Healing Properties. Electrocatalysis. Dec 2012;3(3-4):163-169. Bliznakov ST, Vukmirovic MB, Yang L, Sutter EA, Adzic RR. Pt Monolayer on Electrodeposited Pd Nanostructures: Advanced Cathode Catalysts for PEM Fuel Cells. Journal of the Electrochemical Society. 2012;159(9):F501-F506. Knupp SL, Vukmirovic MB, Haldar P, Herron JA, Mavrikakis M, Adzic RR. Platinum Monolayer Electrocatalysts for O-2 Reduction: Pt Monolayer on Carbon-Supported PdIr Nanoparticles. Electrocatalysis. Dec 2010;1(4):213-223. Sasaki K, Wang JX, Naohara H, et al. Recent advances in platinum monolayer electrocatalysts for oxygen reduction reaction: Scale-up synthesis, structure and activity of Pt shells on Pd cores. Electrochimica Acta. Mar 2010;55(8):2645-2652. Yang L, Vukmirovic MB, Su D, et al. Tuning the Catalytic Activity of Ru@Pt Core-Shell Nanoparticles for the Oxygen Reduction Reaction by Varying the Shell Thickness. J. Phys. Chem. C. Jan 31 2013;117(4):1748-1753. Herron JA, Jiao J, Hahn K, Peng G, Adzic RR, Mavrikakis M. Oxygen Reduction Reaction on Platinum-Terminated "Onion-structured" Alloy Catalysts. Electrocatal. Dec 2012;3(3-4):192-202. Zhou W-P, Yang X, Vukmirovic MB, et al. Improving Electrocatalysts for O-2 Reduction by Fine-Tuning the Pt-Support Interaction: Pt Monolayer on the Surfaces of a Pd3Fe(111) Single-Crystal Alloy. J. Am. Chem. Soc. Sep 9 2009;131(35):12755-12762. Vukmirovic MB, Zhang J, Sasaki K, et al. Platinum monolayer electrocatalysts for oxygen reduction. Electrochim. Acta. Jan 20 2007;52(6):2257-2263. Adzic RR, Zhang J, Sasaki K, et al. Platinum monolayer fuel cell electrocatalysts. Topics in Catalysis. Dec 2007;46(3-4):249-262. Zhang JL, Vukmirovic MB, Xu Y, Mavrikakis M, Adzic RR. Controlling the catalytic activity of platinum-monolayer electrocatalysts for oxygen reduction with different substrates. Angewandte Chemie-International Edition. 2005;44(14):2132-2135. Wang X, Choi S-I, Roling LT, et al. Palladium-platinum core-shell icosahedra with substantially enhanced activity and durability towards oxygen reduction. Nature Commun. Jul 2015;6. Park J, Zhang L, Choi S-I, et al. Atomic Layer-by-Layer Deposition of Platinum on Palladium Octahedra for Enhanced Catalysts toward the Oxygen Reduction Reaction. Acs Nano. Mar 2015;9(3):2635-2647. Xie S, Choi S-I, Lu N, et al. Atomic Layer-by-Layer Deposition of Pt on Pd Nanocubes for Catalysts with Enhanced Activity and Durability toward Oxygen Reduction. Nano Lett. Jun 2014;14(6):3570-3576.

Published
2018
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36. NANOCATALYSTS. Platinum-based nanocages with subnanometer-thick walls and well-defined, controllable facets

Author

Lei, Zhang, Luke T, Roling, Xue, Wang, Madeline, Vara, Miaofang, Chi, Jingyue, Liu, Sang-Il, Choi, Jinho, Park, Jeffrey A, Herron, Zhaoxiong, Xie, Manos, Mavrikakis, and Younan, Xia

Abstract

A cost-effective catalyst should have a high dispersion of the active atoms, together with a controllable surface structure for the optimization of activity, selectivity, or both. We fabricated nanocages by depositing a few atomic layers of platinum (Pt) as conformal shells on palladium (Pd) nanocrystals with well-defined facets and then etching away the Pd templates. Density functional theory calculations suggest that the etching is initiated via a mechanism that involves the formation of vacancies through the removal of Pd atoms incorporated into the outermost layer during the deposition of Pt. With the use of Pd nanoscale cubes and octahedra as templates, we obtained Pt cubic and octahedral nanocages enclosed by {100} and {111} facets, respectively, which exhibited distinctive catalytic activities toward oxygen reduction.

Published
2015

37. The nature of the Fe–graphene interface at the nanometer level

Author

Manos Mavrikakis, Luca Artiglia, Emanuele Cavaliere, Stefano Agnoli, Guowen Peng, Federica Bondino, Elena Magnano, Marco Favaro, Luke T. Roling, Gaetano Granozzi, Silvia Nappini, Alexei Barinov, Igor Píš, Luca Gavioli, and Mattia Cattelan

Subjects
Materials science, Spintronic devices Electronic bandstructure Nanomagnets Scanning tunneling microscopy Transition metals Graphene, High-resolution photoemission, Nanotechnology, Spin degeneracy, Angle-resolved photoemission, Settore FIS/03 - FISICA DELLA MATERIA, law.invention, Condensed Matter::Materials Science, law, Near edge X-ray absorption fine structures, Settore FIS/02 - FISICA TEORICA, MODELLI E METODI MATEMATICI, General Materials Science, Scanning tunneling microscopy, Electronic band structure, X ray absorption, Quantum tunnelling, Spin-polarized density functional theory, Density functional theory, Photoemission, X ray absorption, Angle-resolved photoemission, Nanometer level, Quasi-free standing graphene, Spintronic device, Graphene, Condensed matter physics, Spintronics, Chemistry, Graphene, Fe, Settore FIS/01 - FISICA SPERIMENTALE, Ferromagnetism, Nanometre, Condensed Matter::Strongly Correlated Electrons, Bilayer graphene, Spintronic device, Graphene nanoribbons
Abstract

The emerging fields of graphene-based magnetic and spintronic devices require a deep understanding of the interface between graphene and ferromagnetic metals. This paper reports a detailed investigation at the nanometer level of the Fe-graphene interface carried out by angle-resolved photoemission, high-resolution photoemission from core levels, near edge X-ray absorption fine structure, scanning tunnelling microscopy and spin polarized density functional theory calculations. Quasi-free-standing graphene was grown on Pt(111), and the iron film was either deposited atop or intercalated beneath graphene. Calculations and experimental results show that iron strongly modifies the graphene band structure and lifts its pi band spin degeneracy.

Published
2015
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38. Atomic layer-by-layer deposition of Pt on Pd nanocubes for catalysts with enhanced activity and durability toward oxygen reduction

Author

Jeffrey A. Herron, Moon J. Kim, Zhaoxiong Xie, Shuifen Xie, Luke T. Roling, Ning Lu, Jinguo Wang, Jinho Park, Younan Xia, Manos Mavrikakis, Lei Zhang, and Sang-Il Choi

Subjects
Materials science, Mechanical Engineering, Layer by layer, Alloy, Bioengineering, Nanotechnology, General Chemistry, engineering.material, Island growth, Condensed Matter Physics, Catalysis, Metal, Chemical engineering, visual_art, Monolayer, engineering, visual_art.visual_art_medium, General Materials Science, Nanoscopic scale, Deposition (law)
Abstract

An effective strategy for reducing the Pt content while retaining the activity of a Pt-based catalyst is to deposit the Pt atoms as ultrathin skins of only a few atomic layers thick on nanoscale substrates made of another metal. During deposition, however, the Pt atoms often take an island growth mode because of a strong bonding between Pt atoms. Here we report a versatile route to the conformal deposition of Pt as uniform, ultrathin shells on Pd nanocubes in a solution phase. The introduction of the Pt precursor at a relatively slow rate and high temperature allowed the deposited Pt atoms to spread across the entire surface of a Pd nanocube to generate a uniform shell. The thickness of the Pt shell could be controlled from one to six atomic layers by varying the amount of Pt precursor added into the system. Compared to a commercial Pt/C catalyst, the Pd@PtnL (n = 1-6) core-shell nanocubes showed enhancements in specific activity and durability toward the oxygen reduction reaction (ORR). Density functional theory (DFT) calculations on model (100) surfaces suggest that the enhancement in specific activity can be attributed to the weakening of OH binding through ligand and strain effects, which, in turn, increases the rate of OH hydrogenation. A volcano-type relationship between the ORR specific activity and the number of Pt atomic layers was derived, in good agreement with the experimental results. Both theoretical and experimental studies indicate that the ORR specific activity was maximized for the catalysts based on Pd@Pt2-3L nanocubes. Because of the reduction in Pt content used and the enhancement in specific activity, the Pd@Pt1L nanocubes showed a Pt mass activity with almost three-fold enhancement relative to the Pt/C catalyst.

Published
2014

39. Significant quantum effects in hydrogen activation

Author

Georgios, Kyriakou, Erlend R M, Davidson, Guowen, Peng, Luke T, Roling, Suyash, Singh, Matthew B, Boucher, Matthew D, Marcinkowski, Manos, Mavrikakis, Angelos, Michaelides, and E Charles H, Sykes

Subjects
kinetic Monte Carlo simulation, single-atom alloy, path integral density functional theory, hydrogen, activation, Article, quantum tunneling
Abstract

Dissociation of molecular hydrogen is an important step in a wide variety of chemical, biological, and physical processes. Due to the light mass of hydrogen, it is recognized that quantum effects are often important to its reactivity. However, understanding how quantum effects impact the reactivity of hydrogen is still in its infancy. Here, we examine this issue using a well-defined Pd/Cu(111) alloy that allows the activation of hydrogen and deuterium molecules to be examined at individual Pd atom surface sites over a wide range of temperatures. Experiments comparing the uptake of hydrogen and deuterium as a function of temperature reveal completely different behavior of the two species. The rate of hydrogen activation increases at lower sample temperature, whereas deuterium activation slows as the temperature is lowered. Density functional theory simulations in which quantum nuclear effects are accounted for reveal that tunneling through the dissociation barrier is prevalent for H2 up to ∼190 K and for D2 up to ∼140 K. Kinetic Monte Carlo simulations indicate that the effective barrier to H2 dissociation is so low that hydrogen uptake on the surface is limited merely by thermodynamics, whereas the D2 dissociation process is controlled by kinetics. These data illustrate the complexity and inherent quantum nature of this ubiquitous and seemingly simple chemical process. Examining these effects in other systems with a similar range of approaches may uncover temperature regimes where quantum effects can be harnessed, yielding greater control of bond-breaking processes at surfaces and uncovering useful chemistries such as selective bond activation or isotope separation.

Published
2014

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