Your search keyword '"Mavrikakis, Manos"' showing total 152 results

1. Generalized Brønsted‐Evans‐Polanyi Relationships for Reactions on Metal Surfaces from Machine Learning.

Author

Göltl, Florian and Mavrikakis, Manos

Subjects

*METALLIC surfaces, *MACHINE learning, *TRANSITION metal catalysts, *SURFACE reactions, *HETEROGENEOUS catalysts

Abstract

Brønsted‐Evans‐Polanyi (BEP) relationships, i. e., a linear scaling between reaction and activation energies, lie at the core of computational design of heterogeneous catalysts. However, BEPs are not general and often require reparameterization for each class of reactions. Here we construct generalized BEPs (gBEPs), which can predict activation energies for a diverse dataset of reactions of C, O, N and H containing molecules on metal surfaces. In a first step we develop a set of descriptors based on scaling relationships that can capture the change in chemical identity of reactants during the reaction. Subsequently, we use the reaction energy, these descriptors and a single descriptor for the surface structure to parameterize machine learning based regression approaches for the prediction of activation energies. The best approach we developed shows a Mean Absolute Error (MAE) of 0.11 eV for the training set (80 % of the data set) and 0.23 eV for the test set (20 % of the data set). The methodology presented here allows to calculate activation energies within fractions of seconds on a typical personal computer and due to its generality, accuracy and simplicity in application it might prove to be useful in transition metal catalyst design. [ABSTRACT FROM AUTHOR]

Published

2022

2. Structure sensitivity in adsorbate-induced adatom formation on FCC transition-metal surfaces.

Author

Xu, Lang and Mavrikakis, Manos

Subjects

*ADATOMS, *FACE centered cubic structure, *HETEROGENEOUS catalysis, *DENSITY functional theory, *ADSORBATES, *METAL-metal bonds, *COPPER, *TRANSITION metal oxides, *STEAM reforming

Abstract

[Display omitted] • A theoretical database for predicting adsorbate-induced metal–metal bond scission. • Metal adatom formation is generally easier on (100) surfaces than (111) surfaces. • More open facets are required for adatom formation on intrinsically harder metals. • A new perspective for interpreting structure sensitivity in heterogeneous catalysis by metals. Recent surface science discoveries reveal that adsorbates may induce in situ sub-nanometer cluster formation on transition-metal surfaces. To elucidate the structure sensitivity behind this phenomenon, we performed density functional theory calculations to construct an adatom formation energy database for eight fcc metals and 26 adsorbates commonly involved in catalytic reactions. We show that the adatom formation on (100) surfaces is generally easier than that on (111) surfaces. Many adsorbate/metal pairs exist, mostly on Pd, Ni, Rh, Pt, and Ir, for which adsorbates might induce adatom formation under near-ambient conditions on the (100) facet, but not on (111), highlighting the role of more open facets in adatom formation on metals intrinsically harder than Ag, Au, and Cu. Our study offers a new perspective towards understanding structure sensitivity in heterogeneous thermal- and electro-catalytic systems such as methane steam reforming, Fischer-Tropsch synthesis, and ammonia decomposition. [ABSTRACT FROM AUTHOR]

Published

2024

3. Effect of strain on the reactivity of graphene films.

Author

Kropp, Thomas and Mavrikakis, Manos

Subjects

*DENSITY functional theory, *METALLIC surfaces, *OXYGEN reduction, *BINDING energy, *SURFACE strains

Abstract

• Compressive and expansive strain increase binding energies on graphene. • Bidentate adsorbates are more strongly stabilized than monodentate or physisorbed species. • Strain improves the oxygen reduction activity of graphene and can change the dominant reaction mechanism. The effect of strain on the adsorption of atomic species (Cl, H, N, and O) on pristine and nitrogen-doped graphene is studied using density functional theory. Expansive strain increases surface reactivity by destabilizing graphene π orbitals, which is similar to the shift in the d -band center observed on stretched metal surfaces. However, compressive strain leads to the formation of nanoripples that strongly bind atomic species at ridge sites, which is fundamentally different from adsorption on compressed metal surfaces. Our findings suggest that strain can be used as an effective means of manipulating graphene's reactivity, which is explicitly shown here for the oxygen reduction reaction. [ABSTRACT FROM AUTHOR]

Published

2020

4. Adsorption and dissociation of O[sub 2] on Ir(111).

Author

Xu, Ye and Mavrikakis, Manos

Subjects

*OXYGEN, *IRIDIUM, *ADSORPTION (Chemistry), *DISSOCIATION (Chemistry)

Abstract

The adsorption and dissociation of dioxygen on the Ir(111) surface have been studied using periodic self-consistent density functional theory (DFT-GGA) calculations. Three di-σ-type chemisorbed molecular precursors are identified: One is located over bridge sites and has a binding energy of -1.3 eV and a bond length of 1.4 Å; the other two are located over threefold hollows and have similar binding energies of ca. -1.2 eV and bond lengths of ca. 1.5 Å. None are magnetic, suggesting a peroxo (O[sub 2][sup 2-]) nature for these precursors. The minimum energy path for O[sub 2] dissociation is determined using the nudged elastic band method, and a very small activation energy is found, ca. 0.06 eV. [ABSTRACT FROM AUTHOR]

Published

2002

5. Brønsted–Evans–Polanyi relation for CO oxidation on metal oxides following the Mars–van Krevelen mechanism.

Author

Kropp, Thomas and Mavrikakis, Manos

Subjects

*METALLIC surfaces, *OXIDATION, *DENSITY functional theory, *OXIDATION states, *SURFACE reactions

Abstract

• DFT-derived BEP correlations for CO oxidation on metal oxides via the MvK mechanism. • Barriers estimated from O-vacancy formation energies (uncertainty of 14 kJ/mol). • The lateness of the transition state depends on the O-vacancy formation energy. Scaling relations are widely used to model catalytic reactions on metal surfaces, but they are less commonly applied to metal oxides. Oxygen vacancy formation energies have been suggested as a descriptor for the activity toward oxidation reactions via the Mars-van Krevelen mechanism. However, there is currently no function that maps oxygen vacancy formation energies to CO oxidation barriers. We have compiled a data set for CO oxidation on doped and pristine metal oxide surfaces as well as metal/metal oxide interface sites using density functional theory. Based on this data, we can predict CO oxidation barriers from oxygen vacancy formation energies using a Brønsted–Evans–Polanyi relation with a mean absolute error of 14 kJ/mol. Contrary to what is known for reactions on metal surfaces, we find that the scaling parameter α that describes the lateness of the transition state for CO oxidation on metal oxides is not constant. [ABSTRACT FROM AUTHOR]

Published

2019

6. Mechanistic Study of Nitric Oxide Reduction by Hydrogen on Pt(100) (I): A DFT Analysis of the Reaction Network.

Author

Yunhai Bai and Mavrikakis, Manos

Subjects

*NITRIC oxide, *DENSITY functional theory, *HYDROGEN plasmas, *CHEMICAL bonds, *HYDROGENATION

Abstract

Periodic, self-consistent density functional theory (DFT-GGA, PW91) calculations are used to study the reaction mechanism for nitric oxide (NO) reduction by hydrogen (H2) on Pt(100). Energetics of various N-O activation paths, including both direct and hydrogen-assisted N-O bond-breaking paths, and the formation of three different N-containing products (N2, N2O, and NH3), are systematically studied. On the basis of our analysis, NO* dissociation has a lower barrier than NO* hydrogenation to HNO* or NOH*, and therefore, the direct NO dissociation path is predicted to dominate N-O activation on clean Pt(100). The reaction of atomic N* with N* and NO* is proposed as the mechanism for N2 and N2O formation, respectively. NH3 formation from N* via three successive hydrogenation steps is also studied and is found to be kinetically more difficult than N2 and N2O formation from N*. Finally, NO adsorption phase diagrams on Pt(100) are constructed, and these phase diagrams suggest that, at low temperatures (e.g., 400 K), the Pt(100) surface may be covered by half a monolayer of NO. We propose that high NO coverage might affect the NO + H2 reaction mechanism, and therefore, one should explicitly take the NO coverage into consideration in first-principles studies to determine the reaction mechanism on catalyst surfaces under reaction conditions. A detailed analysis of high NO coverage effects on the reaction mechanism will be presented in a separate contribution. [ABSTRACT FROM AUTHOR]

Published

2018

7. A comparative analysis of different van der Waals treatments for molecular adsorption on the basal plane of 2H-MoS2.

Author

Rangarajan, Srinivas and Mavrikakis, Manos

Subjects

*MOLYBDENUM sulfides, *BINDING energy, *MOLYBDENUM disulfide, *ADSORPTION (Chemistry), *DENSITY functional theory, *HYDROGEN as fuel, *HYDROGEN sulfide

Abstract

• Comparing 7 dispersion methods for binding of 10 adsorbates on basal plane of MoS 2. • vdW-DF and PBE-D3 closest to experimental isosteric heats. • Magnitude of dispersion proportional to the number of heavy atoms in the adsorbate. • Dispersion can be significant (0.05 – 0.09 eV/heavy atom) for large molecules. • Provide quick calculation of dispersion corrections for studying other MoS 2 sites. The binding energy of hydrogen sulfide, ammonia, ethane, ethylene, butadiene, benzene, toluene, pyridine, pyrrole, and thiophene on the basal plane of the semi-conducting 2H-molybdenum sulfide (MoS 2) was calculated with the following flavors of Density Functional Theory (DFT): GGA-PW91, PBE-D3, vdW-DF, optPBE, optB86b, optB88, vdW-TS, and BEEF-vdW. The GGA-PW91 binding energies are negligible (<0.07 eV in magnitude) in all cases. The predictions with vdW-DF and PBE-D3 are the closest (error <0.05 eV) to the isosteric heats of adsorption calculated from reported temperature programmed desorption data for thiophene and butadiene. For all dispersion flavors examined here, the magnitude of the dispersion contribution to the binding energy increases linearly with the number of heavy atoms in the adsorbate, with each atom contributing 0.05 eV (BEEF-vdW) – 0.09 eV (optB88-vdW). This implies that the calculated adsorption constants of molecules larger than acridine (i.e., comprising > 14 non-heavy atoms) can vary by more than four orders of magnitude at industrial conditions depending on the chosen method of dispersion correction. Further, dispersion effects fall off rapidly (>0.03 eV/ non-hydrogen atom/Å) as the adsorbate-surface distance increases. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

8. Density functional theory studies of HCOOH decomposition on Pd(111).

Author

Scaranto, Jessica and Mavrikakis, Manos

Subjects

*DENSITY functional theory, *MOLECULAR theory, *FORMIC acid, *METALLIC surfaces, *DEHYDROGENATION

Abstract

The investigation of formic acid (HCOOH) decomposition on transition metal surfaces is important to derive useful insights for vapor phase catalysis involving HCOOH and for the development of direct HCOOH fuel cells (DFAFC). Here we present the results obtained from periodic, self-consistent, density functional theory (DFT-GGA) calculations for the elementary steps involved in the gas-phase decomposition of HCOOH on Pd(111). Accordingly, we analyzed the minimum energy paths for HCOOH dehydrogenation to CO 2 + H 2 and dehydration to CO + H 2 O through the carboxyl (COOH) and formate (HCOO) intermediates. Our results suggest that HCOO formation is easier than COOH formation, but HCOO decomposition is more difficult than COOH decomposition, in particular in the presence of co-adsorbed O and OH species. Therefore, both paths may contribute to HCOOH decomposition. CO formation goes mainly through COOH decomposition. [ABSTRACT FROM AUTHOR]

Published

2016

9. HCOOH decomposition on Pt(111): A DFT study.

Author

Scaranto, Jessica and Mavrikakis, Manos

Subjects

*FORMIC acid, *CHEMICAL decomposition, *DENSITY functional theory, *METALLIC surfaces, *DEHYDROGENATION kinetics

Abstract

Formic acid (HCOOH) decomposition on transition metal surfaces is important for hydrogen production and for its electro-oxidation in direct HCOOH fuel cells. HCOOH can decompose through dehydrogenation leading to formation of CO 2 and H 2 or dehydration leading to CO and H 2 O; because CO can poison metal surfaces, dehydrogenation is typically the desirable decomposition path. Here we report a mechanistic analysis of HCOOH decomposition on Pt(111), obtained from a plane wave density functional theory (DFT-PW91) study. We analyzed the dehydrogenation mechanism by considering the two possible pathways involving the formate (HCOO) or the carboxyl (COOH) intermediate. We also considered several possible dehydration paths leading to CO formation. We studied HCOO and COOH decomposition both on the clean surface and in the presence of other relevant co-adsorbates. The results suggest that COOH formation is energetically more difficult than HCOO formation. In contrast, COOH dehydrogenation is easier than HCOO decomposition. We found that CO 2 is the main product through both pathways and that CO is produced mainly through the dehydroxylation of the COOH intermediate. [ABSTRACT FROM AUTHOR]

Published

2016

10. Stability of surface and subsurface hydrogen on and in Au/Ni near-surface alloys.

Author

Celik, Fuat E. and Mavrikakis, Manos

Subjects

*GOLD-nickel alloys, *HYDROGEN atom, *SURFACE stability, *HYDROGEN absorption & adsorption, *DENSITY functional theory

Abstract

Periodic, self-consistent DFT-GGA (PW91) calculations were used to study the interaction of hydrogen atoms with the (111) surfaces of substitutional near-surface alloys (NSAs) of Au and Ni with different surface layer compositions and different arrangements of Au atoms in the surface layer. The effect of hydrogen adsorption on the surface and in the first and second subsurface layers of the NSAs was studied. Increasing the Au content in the surface layer weakens hydrogen binding on the surface, but strengthens subsurface binding, suggesting that the distribution of surface and subsurface hydrogen will be different than that on pure Ni(111). While the metal composition of the surface layer has an effect on the binding energy of hydrogen on NSA surfaces, the local composition of the binding site has a stronger effect. For example, fcc hollow sites consisting of three Ni atoms bind H nearly as strongly as on Ni(111), and fcc sites consisting of three Au atoms bind H nearly as weakly as on Au(111). Sites with one or two Au atoms show intermediate binding energies. The preference of hydrogen for three-fold Ni hollow sites alters the relative stabilities of different surface metal atom arrangements, and may provide a driving force for adsorbate-induced surface rearrangement. [ABSTRACT FROM AUTHOR]

Published

2015

11. Adsorbate Diffusion on Transition Metal Nanoparticles.

Author

Peng, Guowen and Mavrikakis, Manos

Subjects

*METAL nanoparticles, *ADSORBATES, *DIFFUSION, *CHEMICAL precursors, *HETEROGENEOUS catalysts, *DENSITY functional theory

Abstract

Diffusionof adsorbates on transition metal nanoparticles is a precursor processfor heterogeneously catalyzed reactions, and as a result, an atomisticunderstanding of the diffusion mechanism is very important. We systematicallystudied adsorption and diffusion of atomic and diatomic species (H,C, N, O, CO, and NO) on nanometer-sized Pt and Cu nanoparticles withdifferent sizes and shapes using density functional theory calculations.We show that nanoparticles bind adsorbates more strongly than thecorresponding extended single crystal metal surfaces. We find thatthere is a Brønsted–Evans–Polanyi-type linear correlationbetween the transition state energy and the initial state energy foradsorbate diffusion across the edges of Pt and Cu nanoparticles. Wefurther show that the barrier for adsorbate diffusion across the nanoparticlesedges can be estimated by the binding energy of the adsorbate on thenanoparticles. These results provide useful insights for understandingdiffusion-mediated chemical reactions catalyzed by transition metalnanoparticles, which are widely used in heterogeneous catalysis. [ABSTRACT FROM AUTHOR]

Published

2015

12. On the composition of bimetallic near-surface alloys in the presence of oxygen and carbon monoxide.

Author

Herron, Jeffrey A. and Mavrikakis, Manos

Subjects

*BIMETALLIC catalysts, *ALLOYS, *SELF-consistent field theory, *DENSITY functional theory, *CARBON monoxide, *SURFACE segregation

Abstract

Abstract: Periodic, self-consistent density functional theory calculations (GGA-PW91) are used to examine surface segregation in close-packed bimetallic Pt-overlayer alloy surfaces (Pt*/M, M=Au, Ag, Cu, Pd, Ir, Rh, Os, Ru, and Re) in different environments. In particular, we find that the thermodynamically stable surface termination in these Pt*/M alloys can be inverted from Pt-terminated in vacuum to M-terminated under exposure to oxygen (for an M that is more oxophilic than Pt). Interestingly, in many of these alloys, Pt is not driven into the bulk; rather it remains in the first subsurface layer where it enhances oxygen binding through a ligand interaction with the surface metal atoms. On the other hand, exposure to CO provides a much milder driving force for the surface composition inversion. To quantify segregation under catalytically relevant conditions, we constructed approximate phase diagrams for the PtRu system as a function of O2 and CO chemical potential (temperature, pressure). The results show that the surface termination inverts with many orders of magnitude higher CO pressure than with O2. [Copyright &y& Elsevier]

Published

2014

13. Atomic and Molecular Adsorption on Re(0001).

Author

Hahn, Konstanze and Mavrikakis, Manos

Subjects

*RHENIUM compounds, *ADSORPTION (Chemistry), *DENSITY functional theory, *CATALYSIS, *BINDING energy, *GAS phase reactions, *THERMOCHEMISTRY, *MOLECULAR structure

Abstract

Using periodic, self-consistent density functional theory calculations, the adsorption of several atomic (H, S, N, O and C) and molecular (CO, N, NH, HCN, CO and NO) species and molecular fragments (NH, NH, CN, CNH, HNO, NOH, CH, CH, CH and OH) on the (0001) facet of rhenium at a coverage of 0.25 ML has been studied. Preferred binding sites with their corresponding binding energy and deformation energy of the surface, as well as an estimated diffusion barrier of each species have been determined. Atomic species and molecular fragments tend to bind to threefold sites, whereas molecular species tend to bind to top sites. The binding strength, with respect to the corresponding gas phase species and in increasing order for all species studied, is: CO < N < NH < CO < CH < HCN < NO < H < NH < OH < CH < CNH < CN < HNO < NH < NOH < S < N < O < CH < C. The vibrational frequencies of all species in their most energetically favorable adsorbed configuration have been calculated. Finally, the thermochemistry of adsorption and decomposition of NO, NO + H, NH, N, CO, CO and CH on Re(0001) has been analyzed. [ABSTRACT FROM AUTHOR]

Published

2014

14. Structure Sensitivity of Methanol Electrooxidation on Transition Metals.

Author

Ferrin, Peter and Mavrikakis, Manos

Subjects

*TRANSITION metals, *METHANOL, *ELECTROLYTIC oxidation, *DENSITY functionals, *METALLURGY, *ELECTROCHEMICAL analysis

Abstract

We have investigated the structure sensitivity of methanol electrooxidation on eight transition metals (Au, Ag, Cu, Pt, Pd, Ir, Rh, and Ni) using periodic, self-consistent density functional theory (DFT- GGA). Using the adsorption energies of 16 intermediates on two different facets of these eight face-centered- cubic transition metals, combined with a simple electrochemical model, we address the differences in the reaction mechanism between the (111) and (100) facets of these metals. We investigate two separate mechanisms for methanol electrooxidation: one going through a CO* intermediate (the indirect pathway) and another that oxidizes methanol directly to CO2 without CO* as an intermediate (the direct pathway). A comparison of our results for the (111) and (100) surfaces explains the origin of methanol electrooxidation's experimentally-established structure sensitivity on Pt surfaces. For most metals studied, on both the (111) and (100) facets, we predict that the indirect mechanism has a higher onset potential than the direct mechanism. Ni(111), Au(100), and Au(111) are the cases where the direct and indirect mechanisms have the same onset potential. For the direct mechanism, Rh, Ir, and Ni show a lower onset potential on the (111) facet, whereas Pt, Cu, Ag, and Au possess lower onset potential on the (100) facet. Pd(100) and Pd(111) have the same onset potential for the direct mechanism. These results can be rationalized by the stronger binding energy of adsorbates on the (100) facet versus the (111) facet. Using linear scaling relations, we establish reactivity descriptors for the (100) surface similar to those recently developed for the (111) surface; the free energies of adsorbed CO* and OH* can describe methanol electrooxidation trends on various metal surfaces reasonably well. [ABSTRACT FROM AUTHOR]

Published

2009

15. Near-surface alloys for hydrogen fuel cell applications

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*FUEL cells, *HYDROGEN, *ALLOYS, *METALLIC composites

Abstract

Abstract: Near-surface alloys (NSAs) possess a variety of unusual catalytic properties that could make them useful candidates for improved catalysts in a variety of chemical processes. It is known from previous work, for example, that some NSAs bind hydrogen very weakly while, at the same time, permitting facile H2 activation. These NSAs could, potentially, facilitate highly selective hydrogenation reactions at low temperatures. In the present work, the suitability of NSAs for use as hydrogen fuel cell anodes has been evaluated; the combination of properties, possessed by selected NSAs, of weak binding of CO with relatively facile H2 activation is nearly ideal for this application. We suggest that, as nanoscale materials synthesis techniques improve, it will become feasible to reproducibly prepare NSAs with highly specified surface structures, resulting in the design and manufacture of a wide variety of such materials for use in fuel cells and in an ever-increasing range of catalytic applications. Furthermore, we introduce a new concept for NSA-defect sites, which could be responsible for the promotional catalytic effects of a second metal added, even in minute quantities, to a host metal catalyst. [Copyright &y& Elsevier]

Published

2006

16. Alloy catalysts designed from first principles.

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*METAL catalysts, *CATALYSTS, *ALLOYS, *DENSITY functionals, *ANODES, *FUEL cells

Abstract

The rational design of pure and alloy metal catalysts from fundamental principles has the potential to yield catalysts of greatly improved activity and selectivity. A promising area of research concerns the role that near-surface alloys (NSAs) can play in endowing surfaces with novel catalytic properties. NSAs are defined as alloys wherein a solute metal is present near the surface of a host metal in concentrations different from the bulk; here we use density functional theory calculations to introduce a new class of these alloys that can yield superior catalytic behaviour for hydrogen-related reactions. Some of these NSAs bind atomic hydrogen (H) as weakly as the noble metals (Cu, Au) while, at the same time, dissociating H2 much more easily. This unique set of properties may permit these alloys to serve as low-temperature, highly selective catalysts for pharmaceuticals production and as robust fuel-cell anodes. [ABSTRACT FROM AUTHOR]

Published

2004

17. Competitive Paths for Methanol Decomposition on Pt(111).

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*DENSITY functionals, *METHANOL, *TRANSITION metals, *HYDROGENATION, *FORMALDEHYDE, *ALCOHOLS (Chemical class)

Abstract

Periodic, self-consistent, Density Functional Theory (PW91-GGA) calculations are used to study competitive paths for the decomposition of methanol on Pt(111). Pathways proceeding through initial C-H and C-O bond scission events in methanol are considered, and the results are compared to data for a pathway proceeding through an initial O-H scission event [Greeley et al. J Am. Chem. Soc. 2002, 124, 7193]. The DFT results suggest that methanol decomposition via CH2OH and either formaldehyde or HCOH intermediates is an energetically feasible pathway; O-H scission to CH3O, followed by sequential dehydrogenation, may be another realistic route. Microkinetic modeling based on the first-principles results shows that, under realistic reaction conditions, C-H scission in methanol is the initial decomposition step with the highest net rate. The elementary steps of all reaction pathways (with the exception of C-O scission) follow a linear correlation between the transition state and final state energies. Simulated HREELS spectra of the intermediates show good agreement with available experimental data, and HREELS spectra of experimentally elusive reaction intermediates are predicted. [ABSTRACT FROM AUTHOR]

Published

2004

18. A first-principles study of surface and subsurface H on and in Ni(1 1 1): diffusional properties and coverage-dependent behavior

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*HYDROGEN, *DIFFUSION

Abstract

Periodic, self-consistent, density functional theory (GGA-PW91) calculations are performed for both surface and subsurface atomic hydrogen on and in Ni(1 1 1). At a low coverage (θ=0.25 ML), the binding energies (BEs) of a hydrogen atom in surface fcc, subsurface octahedral (first layer), and subsurface octahedral (second layer) sites are −2.89, −2.18, and −2.11 eV, respectively. The activation energy barriers for hydrogen diffusion from the surface to the first subsurface layer and from the first to the second subsurface layer are estimated to be 0.88 and 0.52 eV, respectively. In the entire coverage range studied, hydrogen occupies surface fcc and hcp sites and subsurface octahedral sites. In addition, the magnitude of the BE per hydrogen atom and the magnetization of the nickel slabs both decrease as hydrogen coverage increases. Vibrational frequencies of hydrogen at various surface and subsurface sites are calculated and are in reasonable agreement with experimental data. A phase stability calculation with a 2 × 2 surface unit cell shows that a p(2 × 2)-2H overlayer structure (θ=0.5 ML) and a p(1 × 1)-1H structure (θ=1.0 ML) are stable at low hydrogen pressures, in agreement with numerous experimental results. A very large increase in pressure is required to populate subsurface sites. After such an increase occurs, the first subsurface layer is filled completely. [Copyright &y& Elsevier]

Published

2003

19. The adsorption and dissociation of O2 molecular precursors on Cu: the effect of steps

Author

Xu, Ye and Mavrikakis, Manos

Subjects

*ADSORPTION (Chemistry), *DISSOCIATION (Chemistry)

Abstract

The adsorption and dissociation of dioxygen on Cu steps are studied using periodic self-consistent density functional theory (PW91-GGA) calculations. Cu steps are modeled with a Cu(2 1 1) surface. The results are compared with those on the flat Cu(1 1 1) surface. The adsorption of both atomic and molecular oxygen is enhanced on the stepped surface: the binding energy of atomic oxygen is −4.5 eV at its preferred site on the relaxed Cu(2 1 1) surface vs. −4.3 eV at its preferred site on the relaxed Cu(1 1 1) surface, and the binding energy of the molecular oxygen precursor is increased from ∼−0.6 to ∼−1.0 eV. Several possible O2 dissociation paths at the edge of the Cu(2 1 1) step have been investigated. The activation energies range from 0.09 to 0.24 eV, comparable to a minimum activation energy of 0.20 eV found on Cu(1 1 1). However, compared to Cu(1 1 1) the paths on Cu(2 1 1) are stabilized in their entirety by the step by ∼0.5 eV in terms of initial state, transition state, and final state energies. The dissociation of O2 precursors at the foot of the step is close to being barrier-less. Because of the small dissociation barrier on Cu(1 1 1), the effect of steps on O2 dissociation is nevertheless not expected to be as pronounced as in other gas/metal systems. [Copyright &y& Elsevier]

Published

2003

20. A First-Principles Study of Methanol Decomposition on Pt(111).

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*METHANOL, *PLATINUM, *THERMOCHEMISTRY, *BINDING energy

Abstract

Examines the methanol decomposition on platinum. Adsorption thermochemistry of reaction intermediates; Structure of adsorbed methanol; Binding energy of the carbinol.

Published

2002

21. Methanol Decomposition on Cu(111): A DFT Study

Author

Greeley, Jeff and Mavrikakis, Manos

Subjects

*METHANOL, *COPPER, *CHEMICAL decomposition, *CARBON monoxide

Abstract

Self-consistent periodic DFT–GGA calculations are used to investigate the methanol decomposition pathway on both equilibrium and stretched Cu(111) surfaces. The thermochemistry and kinetics of the decomposition via sequential hydrogen abstraction are both found to be highly unfavorable. The second step in this pathway, the abstraction of hydrogen from the methoxy intermediate, has large thermochemical (∼0.6 eV) and kinetic (∼1.4 eV) barriers. Our thermochemical results indicate that methanol, formaldehyde, and carbon monoxide are weakly bound to the surface and will likely desorb before undergoing any reaction under UHV conditions. In contrast, methoxy, formyl, and atomic hydrogen are much more strongly bound. Introduction of a 4% lateral strain to the Cu(111) lattice decreased the transition state energy of the methoxy hydrogen abstraction step, suggesting that strain might facilitate the kinetics of this reaction. [Copyright &y& Elsevier]

Published

2002

22. Compressively Strained and Interconnected Platinum Cones with Greatly Enhanced Activity and Durability toward Oxygen Reduction.

Author

Liu, Mingkai, Zhou, Siyu, Figueras‐Valls, Marc, Ding, Yong, Lyu, Zhiheng, Mavrikakis, Manos, and Xia, Younan

Subjects

*CONES (Botany), *DENSITY functional theory, *ACCELERATED life testing, *NANOPARTICLES, *FUEL cells

Abstract

The synthesis of cone‐shaped Pt nanoparticles featuring compressively‐strained {111} facets by depositing Pt atoms on the vertices of Pd icosahedral nanocrystals, followed by selective removal of the Pd template via wet etching, is reported. By controlling the lateral dimensions down to ca. 3 nm, together with a thickness of ca. 2 nm, the Pt cones show greatly enhanced specific and mass activities toward oxygen reduction, with values being 2.8 and 6.4 times those of commercial Pt/C, respectively. Both the strain field and the observed activity trend are rationalized using density functional theory calculations. With the formation of ultrathin linkers among the Pt cones derived from the same Pd icosahedral seed, the interconnected Pt cones acquire stronger interactions with the carbon support, preventing them from detachment and aggregation during the catalytic reaction. Even after 20 000 cycles of accelerated durability test, the Pt cones still show a mass activity 5.3 times higher than the initial value of the Pt/C. [ABSTRACT FROM AUTHOR]

Published

2024

23. First synthesis, experimental and theoretical vibrational spectra of an oxametallacyle on a...

Author

Jones, G. Scott, Mavrikakis, Manos, Barteau, Mark A., and Vohs, John M.

Subjects

*HIGH resolution spectroscopy

Abstract

Examines the reactions of 2-iodoethanol (ICH2CH2OH) on the Ag(110) surface with the use of high-resolution electron energy loss spectroscopy (HREELS) studies. Information on the goal of these experiments; Implementation of Density Functional Theory (DFT) calculations to determine the fully optimized structure for the oxametallacycle on silver; Details on the principal reaction channel for this intermediate in temperature programmed desorption (TPD) experiments.

Published

1998

24. HCOOH Decomposition on Sub-Nanometer Pd6 Cluster Catalysts: The Effect of Defective Boron Nitride Supports Through First Principles.

Author

Schimmenti, Roberto and Mavrikakis, Manos

Subjects

*BORON nitride, *FORMIC acid, *DENSITY functional theory, *CHARGE transfer, *CATALYSTS, *HYDROGEN production

Abstract

• Hexagonal Boron-Nitride supporting Pd 6 nanoclusters. • Boron vs Nitrogen vacancy. • Opposite charge transfer direction depending on vacancy identity. • Vacancy type leads to distinctly different selectivity for formic acid decomposition on supported Pd 6 clusters. The catalytic properties of a hexagonal boron nitride- (h -BN) supported Pd 6 sub-nanometer cluster in the context of formic acid (HCOOH) decomposition were studied by means of periodic Density Functional Theory (DFT) calculations. The effect of support defectivity – boron (h -B v N) and nitrogen (h -BN v) monovacancies – on the competition between the formate (HCOO)- and carboxyl (COOH)-mediated decomposition pathways was analyzed. Defects are responsible for charge-transfer leading to a positively or negatively charged cluster, and open new reactive channels in which vacancy-mediated dehydrogenation pathways can occur. Pd 6 cluster reconstructions, induced by the adsorption of reaction intermediates and by the presence of monovacancies in the support, greatly stabilize the formation of CO from COOH, which could drastically decrease the selectivity towards hydrogen production. A simplified descriptor-based analysis, based on selected thermochemical quantities calculated on charged cluster models, suggests that Pd 6 sub-nanometer clusters supported on pristine h -BN and h -BN v can be more selective than Pd 6 supported on defective h -B v N towards HCOOH dehydrogenation. [ABSTRACT FROM AUTHOR]

Published

2021

25. Exploring the Impact of Active Site Structure on the Conversion of Methane to Methanol in Cu‐Exchanged Zeolites.

Author

Göltl, Florian, Bhandari, Saurabh, Lebrón‐Rodríguez, Edgard A., Gold, Jake I., Hutton, Daniel J., Zones, Stacey I., Hermans, Ive, Dumesic, James A., and Mavrikakis, Manos

Subjects

*ZEOLITES, *METAL clusters, *METHANOL, *METHANE, *HYDROXYL group, *METHANE as fuel, *STRUCTURE-activity relationships

Abstract

In the past, Cu‐oxo or ‐hydroxy clusters hosted in zeolites have been suggested to enable the selective conversion of methane to methanol, but the impact of the active site's stoichiometry and structure on methanol production is still poorly understood. Herein, we apply theoretical modeling in conjunction with experiments to study the impact of these two factors on partial methane oxidation in the Cu‐exchanged zeolite SSZ‐13. Phase diagrams developed from first‐principles suggest that Cu‐hydroxy or Cu‐oxo dimers are stabilized when O2 or N2O are used to activate the catalyst, respectively. We confirm these predictions experimentally and determine that in a stepwise conversion process, Cu‐oxo dimers can convert twice as much methane to methanol compared to Cu‐hydroxyl dimers. Our theoretical models rationalize how Cu‐di‐oxo dimers can convert up to two methane molecules to methanol, while Cu‐di‐hydroxyl dimers can convert only one methane molecule to methanol per catalytic cycle. These findings imply that in Cu clusters, at least one oxo group or two hydroxyl groups are needed to convert one methane molecule to methanol per cycle. This simple structure–activity relationship allows to intuitively understand the potential of small oxygenated or hydroxylated transition metal clusters to convert methane to methanol. [ABSTRACT FROM AUTHOR]

Published

2024

26. Exploring the Impact of Active Site Structure on the Conversion of Methane to Methanol in Cu‐Exchanged Zeolites.

Author

Göltl, Florian, Bhandari, Saurabh, Lebrón‐Rodríguez, Edgard A., Gold, Jake I., Hutton, Daniel J., Zones, Stacey I., Hermans, Ive, Dumesic, James A., and Mavrikakis, Manos

Subjects

*ZEOLITES, *METAL clusters, *METHANOL, *METHANE, *HYDROXYL group, *METHANE as fuel, *STRUCTURE-activity relationships

Abstract

In the past, Cu‐oxo or ‐hydroxy clusters hosted in zeolites have been suggested to enable the selective conversion of methane to methanol, but the impact of the active site's stoichiometry and structure on methanol production is still poorly understood. Herein, we apply theoretical modeling in conjunction with experiments to study the impact of these two factors on partial methane oxidation in the Cu‐exchanged zeolite SSZ‐13. Phase diagrams developed from first‐principles suggest that Cu‐hydroxy or Cu‐oxo dimers are stabilized when O2 or N2O are used to activate the catalyst, respectively. We confirm these predictions experimentally and determine that in a stepwise conversion process, Cu‐oxo dimers can convert twice as much methane to methanol compared to Cu‐hydroxyl dimers. Our theoretical models rationalize how Cu‐di‐oxo dimers can convert up to two methane molecules to methanol, while Cu‐di‐hydroxyl dimers can convert only one methane molecule to methanol per catalytic cycle. These findings imply that in Cu clusters, at least one oxo group or two hydroxyl groups are needed to convert one methane molecule to methanol per cycle. This simple structure–activity relationship allows to intuitively understand the potential of small oxygenated or hydroxylated transition metal clusters to convert methane to methanol. [ABSTRACT FROM AUTHOR]

Published

2024

27. Synthesis and examination of alkoxycyanobiphenyl mesogens with a single fluorine atom at specific locations in the tail.

Author

Agrahari, Kiran, Wolter, Trenton J., Smith, Evangelos, Abbott, Nicholas L., Mavrikakis, Manos, Mighion, Jeffrey D., and Twieg, Robert J.

Subjects

*ENANTIOMERIC purity, *HIGH performance liquid chromatography, *LIQUID crystals, *DIPOLE moments, *RECRYSTALLIZATION (Metallurgy)

Abstract

Selective fluorination is a well-established technique to tailor and improve many of the physical properties of liquid crystals. Cyanobiphenyls are among the best-known and understood thermotropic liquid crystals and have served admirably as a testbed for structural modifications that can eventually be extended to other classes of liquid crystals. As such, and expanding on our earlier work, in the present study of the alkoxycyanobiphenyl M series, the individual tail sites of both 4'-(butoxy)[1,1'-biphenyl]-4-carbonitrile (M12) and 4'-(pentyloxy)[1,1'-biphenyl]-4-carbonitrile (M15) were selectively monofluorinated in order to examine the influence on the phase behavior. These fluorinated compounds were synthesized using epoxidation, regioselective epoxide opening and deoxyfluorination chemistry. In all the fluorinated compounds in both series a monotropic nematic phase was found in the cooling cycle. It was observed that as the fluorine atom on the tail moves closer to the core, the compounds exhibited a metastable room temperature nematic mesophase, but recrystallization invariably occurred. Both enantiomers of 4'-(2-fluorobutoxy)[1,1'-biphenyl]-4-carbonitrile were synthesized in high enantiomeric purity by regioselective opening of chiral epoxide intermediates followed by deoxyfluorination, as established by chiral high-performance liquid chromatography, and their phase behaviors were determined. Moreover, the average dipole moments of the synthesized fluorine substituted derivatives were also calculated. [ABSTRACT FROM AUTHOR]

Published

2024

28. Computational Methods in Heterogeneous Catalysis.

Author

Chen, Benjamin W. J., Xu, Lang, and Mavrikakis, Manos

Abstract

The unprecedented ability of computations to probe atomic-level details of catalytic systems holds immense promise for the fundamentals-based bottom-up design of novel heterogeneous catalysts, which are at the heart of the chemical and energy sectors of industry. Here, we critically analyze recent advances in computational heterogeneous catalysis. First, we will survey the progress in electronic structure methods and atomistic catalyst models employed, which have enabled the catalysis community to build increasingly intricate, realistic, and accurate models of the active sites of supported transition-metal catalysts. We then review developments in microkinetic modeling, specifically mean-field microkinetic models and kinetic Monte Carlo simulations, which bridge the gap between nanoscale computational insights and macroscale experimental kinetics data with increasing fidelity. We finally review the advancements in theoretical methods for accelerating catalyst design and discovery. Throughout the review, we provide ample examples of applications, discuss remaining challenges, and provide our outlook for the near future. [ABSTRACT FROM AUTHOR]

Published

2021

29. Pd3Ag(111) as a Model System for Hydrogen Separation Membranes: Combined Effects of CO Adsorption and Surface Termination on the Activation of Molecular Hydrogen.

Author

Svenum, Ingeborg-Helene, Herron, Jeffrey A., Mavrikakis, Manos, and Venvik, Hilde J.

Subjects

*MEMBRANE separation, *HYDROGEN, *DENSITY functional theory, *CARBON monoxide, *ADSORPTION (Chemistry)

Abstract

The co-adsorption of hydrogen and carbon monoxide on Pd3Ag(111) alloy surfaces has been studied as a model system for Pd-Ag alloys in membrane and catalysis applications using periodic density functional theory calculations (PW91-GGA). We explored the effects of Pd–Ag surface composition, since segregation of silver towards and away from the surface has been suggested to explain the experimentally observed changes in H2 activation, CO inhibition and reactivity. We found that CO pre-adsorbed on the surface weakens the adsorption of H on Pd3Ag(111) alloy surfaces irrespective of whether the surface termination corresponds to the bulk Pd3Ag composition, or is purely Pd-terminated. A higher coverage of H with CO present is obtained for the Pd-terminated surface; this surface also exhibits a larger range of chemical potentials for co-adsorbed hydrogen and CO. The barrier for H2 activation increases with increasing CO coverage, but the surface composition has the largest impact on H2 activation at intermediate CO coverage. The results imply that Pd-based membranes with typically ~ 23 wt% Ag are less prone to CO poisoning if the surface becomes Pd-terminated. [ABSTRACT FROM AUTHOR]

Published

2020

30. Computational methods: A search engine for catalysts.

Author

Mavrikakis, Manos

Subjects

*CATALYSTS, *ALLOYS, *METALS, *SEARCH engines, *DATABASE searching

Abstract

The article reports on the development of a systematic and inexpensive computational framework for the rational searching of a large number of pure metal and bimetallic alloys for the hydrogen evolution reaction (HER). HER involved the reduction of protons for the evolution of hydrogen and has an important role in hydrogen fuel cells and in the storage, electrodeposition and corrosion of metals.

Published

2006

31. Preface.

Author

Mavrikakis, Manos

Subjects

*PREFACES & forewords, *CATALYSIS

Abstract

A preface for the March 2006 issue of the "Topics in Catalysis" is presented.

Published

2006

32. Fast and Non‐equilibrium Uptake of Hydrogen by Pd Icosahedral Nanocrystals.

Author

Zhou, Siyu, Figueras‐Valls, Marc, Shi, Yifeng, Ding, Yong, Mavrikakis, Manos, and Xia, Younan

Subjects

*OXIDATION of formic acid, *NANOCRYSTALS, *TWIN boundaries, *CHEMICAL potential

Abstract

We report for the first time that Pd nanocrystals can absorb H via a "single‐phase pathway" when particles with a proper combination of shape and size are used. Specifically, when Pd icosahedral nanocrystals of 7‐ and 12‐nm in size are exposed to H atoms, the H‐saturated twin boundaries can divide each particle into 20 smaller single‐crystal units in which the formation of phase boundaries is no longer favored. As such, absorption of H atoms is dominated by the single‐phase pathway and one can readily obtain PdHx with anyx in the range of 0–0.7. When switched to Pd octahedral nanocrystals, the single‐phase pathway is only observed for particles of 7 nm in size. We also establish that the H‐absorption kinetics will be accelerated if there is a tensile strain in the nanocrystals due to the increase in lattice spacing. Besides the unique H‐absorption behaviors, the PdHx (x=0–0.7) icosahedral nanocrystals show remarkable thermal and catalytic stability toward the formic acid oxidation due tothe decrease in chemical potential for H atoms in a Pd lattice under tensile strain. [ABSTRACT FROM AUTHOR]

Published

2023

33. Fast and Non‐equilibrium Uptake of Hydrogen by Pd Icosahedral Nanocrystals.

Author

Zhou, Siyu, Figueras‐Valls, Marc, Shi, Yifeng, Ding, Yong, Mavrikakis, Manos, and Xia, Younan

Subjects

*OXIDATION of formic acid, *NANOCRYSTALS, *TWIN boundaries, *CHEMICAL potential

Abstract

We report for the first time that Pd nanocrystals can absorb H via a "single‐phase pathway" when particles with a proper combination of shape and size are used. Specifically, when Pd icosahedral nanocrystals of 7‐ and 12‐nm in size are exposed to H atoms, the H‐saturated twin boundaries can divide each particle into 20 smaller single‐crystal units in which the formation of phase boundaries is no longer favored. As such, absorption of H atoms is dominated by the single‐phase pathway and one can readily obtain PdHx with anyx in the range of 0–0.7. When switched to Pd octahedral nanocrystals, the single‐phase pathway is only observed for particles of 7 nm in size. We also establish that the H‐absorption kinetics will be accelerated if there is a tensile strain in the nanocrystals due to the increase in lattice spacing. Besides the unique H‐absorption behaviors, the PdHx (x=0–0.7) icosahedral nanocrystals show remarkable thermal and catalytic stability toward the formic acid oxidation due tothe decrease in chemical potential for H atoms in a Pd lattice under tensile strain. [ABSTRACT FROM AUTHOR]

Published

2023

34. Ethylene versus ethane: A DFT-based selectivity descriptor for efficient catalyst screening.

Author

Xu, Lang, Stangland, Eric E., and Mavrikakis, Manos

Subjects

*ETHYLENE, *DENSITY functional theory, *CATALYTIC activity, *HYDROGENATION, *DESORPTION

Abstract

The production of ethylene without its hydrogenation to ethane is a challenge for several catalytic processes. Here, we present a catalyst screening scheme, where the Gibbs free energy difference between the ethylene hydrogenation barrier and ethylene desorption energy is defined as a descriptor for ethylene selectivity. Using plane-wave, dispersion-corrected DFT calculations, we evaluated the descriptor values over the (111) facets of Pt, Pd, and Cu as well as a series of Pt- and Pd-based bimetallic alloys. Our predicted descriptor values indicate that the addition of a Group IB metal (Cu, Ag, or Au) to Pt or Pd improves ethylene selectivity. Ag induces the most significant improvement at 50% while Au has the strongest effect at 75% atomic composition. Pd-based alloys exhibit superior ethylene selectivity over their Pt-based counterparts. Our descriptor model offers an efficient method for the initial screening of catalysts with improved ethylene selectivity. [ABSTRACT FROM AUTHOR]

Published

2018

35. Hydroformylation of pyrolysis oils to aldehydes and alcohols from polyolefin waste.

Author

Houqian Li, Jiayang Wu, Zhen Jiang, Jiaze Ma, Zavala, Victor M., Landis, Clark R., Mavrikakis, Manos, and Huber, George W.

Subjects

*GREENHOUSE gases, *BIODEGRADABLE plastics, *ALDEHYDES, *POLYOLEFINS, *HYDROFORMYLATION, *PYROLYSIS, *PLASTIC scrap

Abstract

Waste plastics are an abundant feedstock for the production of renewable chemicals. Pyrolysis of waste plastics produces pyrolysis oils with high concentrations of olefins (’50 weight %). The traditional petrochemical industry uses several energy-intensive steps to produce olefins from fossil feedstocks such as naphtha, natural gas, and crude oil. In this work, we demonstrate that pyrolysis oil can be used to produce aldehydes through hydroformylation, taking advantage of the olefin functionality. These aldehydes can then be reduced to mono- and dialcohols, oxidized to mono- and dicarboxylic acids, or aminated to mono- and diamines by using homogeneous and heterogeneous catalysis. This route produces high-value oxygenated chemicals from low-value postconsumer recycled polyethylene. We project that the chemicals produced by this route could lower greenhouse gas emissions ~60% compared with their production through petroleum feedstocks. [ABSTRACT FROM AUTHOR]

Published

2023

36. Gas-phase microactuation using kinetically controlled surface states of ultrathin catalytic sheets.

Author

Nanqi Bao, Qingkun Liu, Reynolds, Michael F., Figueras, Marc, Smith, Evangelos, Wei Wang, Cao, Michael C., Muller, David A., Mavrikakis, Manos, Cohen, Itai, McEuen, Paul L., and Abbott, Nicholas L.

Subjects

*SURFACE states, *CHEMICAL systems, *GAS as fuel, *HYDROGEN as fuel, *MECHANICAL energy, *CATALYTIC reforming

Abstract

Biological systems convert chemical energy into mechanical work by using protein catalysts that assume kinetically controlled conformational states. Synthetic chemomechanical systems using chemical catalysis have been reported, but they are slow, require high temperatures to operate, or indirectly perform work by harnessing reaction products in liquids (e.g., heat or protons). Here, we introduce a bioinspired chemical strategy for gas-phase chemomechanical transduction that sequences the elementary steps of catalytic reactions on ultrathin (<10 nm) platinum sheets to generate surface stresses that directly drive microactuation (bending radii of 700 nm) at ambient conditions (T = 20 °C; Ptotal = 1 atm). When fueled by hydrogen gas and either oxygen or ozone gas, we show how kinetically controlled surface states of the catalyst can be exploited to achieve fast actuation (600 ms/cycle) at 20 °C. We also show that the approach can integrate photochemically controlled reactions and can be used to drive the reconfiguration of microhinges and complex origami- and kirigami-based microstructures. [ABSTRACT FROM AUTHOR]

Published

2023

37. Formation of active sites on transition metals through reaction-driven migration of surface atoms.

Author

Xu, Lang, Papanikolaou, Konstantinos G., Lechner, Barbara A. J., Je, Lisa, Somorjai, Gabor A., Salmeron, Miquel, and Mavrikakis, Manos

Subjects

*TRANSITION metals, *SCANNING tunneling microscopy, *FACE centered cubic structure, *MONTE Carlo method, *COPPER surfaces, *OXIDATION of carbon monoxide

Abstract

Adopting low-index single-crystal surfaces as models for metal nanoparticle catalysts has been questioned by the experimental findings of adsorbate-induced formation of subnanometer clusters on several single-crystal surfaces. We used density functional theory calculations to elucidate the conditions that lead to cluster formation and show how adatom formation energies enable efficient screening of the conditions required for adsorbate-induced cluster formation. We studied a combination of eight face-centered cubic transition metals and 18 common surface intermediates and identified systems relevant to catalytic reactions, such as carbon monoxide (CO) oxidation and ammonia (NH3) oxidation. We used kinetic Monte Carlo simulations to elucidate the CO-induced cluster formation process on a copper surface. Scanning tunneling microscopy of CO on a nickel (111) surface that contains steps and dislocations points to the structure sensitivity of this phenomenon. Metal-metal bond breaking that leads to the evolution of catalyst structures under realistic reaction conditions occurs much more broadly than previously thought. [ABSTRACT FROM AUTHOR]

Published

2023

38. Thank you Charlie!

Author

Mavrikakis, Manos

Published

2012

39. Improved oxygen reduction reactivity of platinum monolayers on transition metal surfaces

Author

Nilekar, Anand Udaykumar and Mavrikakis, Manos

Subjects

*DENSITY functionals, *CHEMICAL reduction, *METALLIC surfaces, *MONOMOLECULAR films

Abstract

Abstract: The catalytic activity of platinum monolayers supported on close-packed transition metal surfaces (Au(111), Pt(111), Pd(111) and Ir(111)) is investigated for the oxygen reduction reaction (ORR) by generating free energy diagrams and performing Sabatier analysis based on periodic, self-consistent density functional theory (DFT) calculations. Three different ORR mechanisms, involving direct or hydrogen-assisted activation of O2, are considered. At the ORR equilibrium potential of 1.23V, the reactivity of all surfaces is shown to be limited by the rate of OH removal from the surface. At a cell potential of 0.80V, the ORR reactivity of different surfaces is dictated by the strength of oxygen adsorption, with OH removal via hydrogenation and O–O bond scission in either O2, O2H or H2O2 being the rate-limiting steps for surfaces with stronger and weaker oxygen binding, respectively. Among the surfaces studied, Pt monolayer on a Pd(111) substrate shows the highest reactivity and is more active than Pt(111). These results are in excellent agreement with our earlier experimental and theoretical work, which was based on a simpler model for the ORR. [Copyright &y& Elsevier]

Published

2008

40. Erratum to: “Adsorption and dissociation of O<f>2</f> on Cu(<f>1 1 1</f>): thermochemistry, reaction barrier and the effect of strain” [Surface Science 494 (2001) 131–144]

Author

Xu, Ye and Mavrikakis, Manos

Published

2002

41. The role of coverage effects on the structure–sensitivity of formic acid electrooxidation on Pd surfaces.

Author

Papanikolaou, Konstantinos G., Shi, Yifeng, Schimmenti, Roberto, Xia, Younan, and Mavrikakis, Manos

Subjects

*OXIDATION of formic acid, *FORMIC acid, *GIBBS' free energy, *DENSITY functional theory, *DIRECT methanol fuel cells, *FUEL cells, *SINGLE crystals

Abstract

[Display omitted] • The structure–sensitivity of the electrooxidation of formic acid was extensively investigated on Pd(1 1 1), Pd(1 0 0), Pd(2 1 1) and Pd(1 1 0) surfaces. • The significance of CO coverage effect at applied potentials lower than 0.4 V was elucidated via density functional theory calculations. • The inclusion of coverage effects is necessary for accurate predictions of the electrocatalytic activity. • Coverage effects can alter the thermodynamically favored pathway over single crystal electrodes at different applied potentials. Direct formic acid (FA) fuel cells (DFAFCs) with Pd anode catalysts are promising for small portable applications. During the electrooxidation of formic acid (FAO), CO accumulates on the Pd electrocatalyst, thereby decreasing its performance. In this work, we use density functional theory (DFT; RPBE) to elucidate the significance of coverage effects on the structure–sensitivity of FAO over four low–index Pd surfaces: Pd(1 1 1), Pd(1 0 0), Pd(1 1 0), and Pd(2 1 1). We construct coverage–dependent Gibbs free energy diagrams and in agreement with experiment, predict that Pd(1 0 0) and Pd(2 1 1) are the most active surfaces. Additionally, we find that the presence of CO spectator species can alter the preferred electrooxidation pathway under different applied potentials. Such pathway transitions appear to be critical for rationalizing experimental trends regarding electrocatalytic activity and are only captured when coverage effects are accounted for. Insights derived from this work may facilitate the design of improved FAO electrocatalysts. [ABSTRACT FROM AUTHOR]

Published

2023

42. Expanding plastics recycling technologies: chemical aspects, technology status and challenges.

Author

Li, Houqian, Aguirre-Villegas, Horacio A., Allen, Robert D., Bai, Xianglan, Benson, Craig H., Beckham, Gregg T., Bradshaw, Sabrina L., Brown, Jessica L., Brown, Robert C., Cecon, Victor S., Curley, Julia B., Curtzwiler, Greg W., Dong, Son, Gaddameedi, Soumika, García, John E., Hermans, Ive, Kim, Min Soo, Ma, Jiaze, Mark, Lesli O., and Mavrikakis, Manos

Subjects

*CHEMICAL recycling, *PLASTIC recycling, *INDUSTRIAL chemistry, *WASTE recycling, *PLASTIC scrap, *WASTE management, *TECHNOLOGICAL innovations

Abstract

Less than 10% of the plastics generated globally are recycled, while the rest are incinerated, accumulated in landfills, or leak into the environment. New technologies are emerging to chemically recycle waste plastics that are receiving tremendous interest from academia and industry. Chemists and chemical engineers need to understand the fundamentals of these technologies to design improved systems for chemical recycling and upcycling of waste plastics. In this paper, we review the entire life cycle of plastics and options for the management of plastic waste to address barriers to industrial chemical recycling and further provide perceptions on possible opportunities with such materials. Knowledge and insights to enhance plastic recycling beyond its current scale are provided. Outstanding research problems and where researchers in the field should focus their efforts in the future are also discussed. [ABSTRACT FROM AUTHOR]

Published

2022

43. Investigation of the mesogenic behavior of alkoxy and fluorine tail terminated alkoxy nitrobiphenyls for chemoresponsive liquid crystals.

Author

Rahman, Mohammad S., Wolter, Trenton, Tripathi, Ayushi, Abbott, Nicholas L., Mavrikakis, Manos, and Twieg, Robert J.

Subjects

*LIQUID crystals, *ALKOXY compounds, *FLUORINE, *NITRO compounds, *POLYMER liquid crystals, *BINARY mixtures

Abstract

Liquid crystal properties of compounds with a variety of polar terminal groups including cyano, fluoro, isothiocyanato, etc., were studied well, however, not enough attention was given to nitro terminal compounds. In this work, a series of fluorine tail terminated alkoxy nitrobiphenyl compounds were synthesised and their mesogenic properties were analysed. In addition, the simple alkoxy nitrobiphenyl compounds were synthesised and analysed in order to compare them with fluoro-alkoxy nitrobiphenyl compounds and for binary mixture analysis. Fluorine tail termination to the alkoxy chain does suppress the smectic phase that was observed for the simple alkoxy nitrobiphenyl compounds with longer chains. Fluorine tail terminated alkoxy nitrobiphenyl compounds with longer chains (C7-C10) show monotropic nematic phase around ambient temperature and supercooling properties and these compounds are useful for a binary mixture analysis. Moreover, computation and experimental analyses of the alkoxy nitrobiphenyl compounds were performed to investigate the potential use of these nitro terminal compounds as chemoresponsive liquid crystal materials. [ABSTRACT FROM AUTHOR]

Published

2022

44. On the Structure Sensitivity of Formic Acid Decomposition on Cu Catalysts.

Author

Li, Sha, Scaranto, Jessica, and Mavrikakis, Manos

Subjects

*CHEMICAL decomposition, *COPPER catalysts, *FORMIC acid, *BIOMASS, *REACTION mechanisms (Chemistry), *LOW temperatures

Abstract

Catalytic decomposition of formic acid (HCOOH) has attracted substantial attention since HCOOH is a major by-product in biomass reforming, a promising hydrogen carrier, and also a potential low temperature fuel cell feed. Despite the abundance of experimental studies for vapor-phase HCOOH decomposition on Cu catalysts, the reaction mechanism and its structure sensitivity is still under debate. In this work, self-consistent, periodic density functional theory calculations were performed on three model surfaces of copper-Cu(111), Cu(100) and Cu(211), and both the HCOO (formate)-mediated and COOH (carboxyl)-mediated pathways were investigated for HCOOH decomposition. The energetics of both pathways suggest that the HCOO-mediated route is more favorable than the COOH-mediated route on all three surfaces, and that HCOOH decomposition proceeds through two consecutive dehydrogenation steps via the HCOO intermediate followed by the recombinative desorption of H. On all three surfaces, HCOO dehydrogenation is the likely rate determining step since it has the highest transition state energy and also the highest activation energy among the three catalytic steps in the HCOO pathway. The reaction is structure sensitive on Cu catalysts since the examined three Cu facets have dramatically different binding strengths for the key intermediate HCOO and varied barriers for the likely rate determining step-HCOO dehydrogenation. Cu(100) and Cu(211) bind HCOO much more strongly than Cu(111), and they are also characterized by potential energy surfaces that are lower in energy than that for the Cu(111) facet. Coadsorbed HCOO and H represents the most stable state along the reaction coordinate, indicating that, under reaction conditions, there might be a substantial surface coverage of the HCOO intermediate, especially at under-coordinated step, corner or defect sites. Therefore, under reaction conditions, HCOOH decomposition is predicted to occur most readily on the terrace sites of Cu nanoparticles. As a result, we hereby present an example of a fundamentally structure-sensitive reaction, which may present itself as structure-insensitive in typical varied particle-size experiments. [ABSTRACT FROM AUTHOR]

Published

2016

45. Ab initio molecular dynamics of solvation effects on reactivity at electrified interfaces.

Author

Herron, Jeffrey A., Morikawa, Yoshitada, and Mavrikakis, Manos

Subjects

*MOLECULAR dynamics, *DYNAMICS, *DENSITY functional theory, *ELECTRODE potential, *BIOENERGETICS

Abstract

Using ab initio molecular dynamics as implemented in periodic, self-consistent (generalized gradient approximation Perdew– Burke–Ernzerhof) density functional theory, we investigated the mechanism of methanol electrooxidation on Pt(111). We investigated the role of water solvation and electrode potential on the energetics of the first proton transfer step, methanol electrooxidation to methoxy (CH3O) or hydroxymethyl (CH2OH). The results show that solvation weakens the adsorption of methoxy to uncharged Pt(111), whereas the binding energies of methanol and hydroxymethyl are not significantly affected. The free energies of activation for breaking the C−H and O−H bonds in methanol were calculated through a Blue Moon Ensemble using constrained ab initio molecular dynamics. Calculated barriers for these elementary steps on unsolvated, uncharged Pt(111) are similar to results for climbing-image nudged elastic band calculations from the literature. Water solvation reduces the barriers for both C−H and O−H bond activation steps with respect to their vapor-phase values, although the effect is more pronounced for C−H bond activation, due to less disruption of the hydrogen bond network. The calculated activation energy barriers show that breaking the C−H bond of methanol is more facile than the O−H bond on solvated negatively biased or uncharged Pt(111). However, with positive bias, O−H bond activation is enhanced, becoming slightly more facile than C−H bond activation. [ABSTRACT FROM AUTHOR]

Published

2016

46. Heterogeneous Reduction Pathways for Hg(II) Species on Dry Aerosols: A First-Principles Computational Study.

Author

Tacey, Sean A., Lang Xu, Mavrikakis, Manos, and Schauer, James J.

Subjects

*MERCURY, *AEROSOLS, *POTENTIAL energy surfaces, *DENSITY functional theory, *GAS phase reactions

Abstract

The atmospheric lifetime of mercury is greatly impacted by redox chemistry resulting from the high deposition rate of reactive mercury (Hg(II)) compared to elemental mercury (Hg0). Recent laboratory and field studies have observed the reduction of Hg(II), but the chemical mechanism for this reaction has not been identified. Recent experimental work has shown that the reduction reaction is heterogeneous and can occur on iron and sodium chloride aerosol surfaces. This study explores the use of density functional theory calculations to discern the reduction pathways of HgCl2, HgBr2, Hg(NO3)2, and HgSO4 on clean Fe(110), NaCl(100), and NaCl(111)Na surfaces. Potential energy surfaces were prepared for the various reduction pathways, indicating that the reduction pathway leading to the production of gas-phase elemental mercury is highly favorable on Fe(110) and NaCl(111)Na. Moreover, the Fe(110) surface requires an external energy source of ∼0.5 eV to desorb the reduced mercury, whereas the NaCl(111)Na surface requires no energy input. The results indicate that a number of mercury species can be reduced on metallic iron and sodium chloride surfaces, which are known aerosol components, and that a photochemical reaction involving the aerosol surface is likely needed for the reaction to be catalytic. [ABSTRACT FROM AUTHOR]

Published

2016

47. On the Structure Sensitivity of Dimethyl Ether Electro-oxidation on Eight FCC Metals: A First-Principles Study.

Author

Herron, Jeffrey, Ferrin, Peter, and Mavrikakis, Manos

Subjects

*METHYL ether, *DENSITY functional theory, *DEHYDROGENATION, *CHEMICAL bonds, *NUMERICAL calculations

Abstract

The electro-oxidation of dimethyl ether (DME) was investigated using periodic, self-consistent density functional theory (DFT) calculations on the (111) and (100) facets of eight fcc metals: Au, Ag, Cu, Pt, Pd, Ni, Ir, and Rh. The goal of this study is to understand the experimentally observed structure sensitivity of this reaction on Pt, and to predict trends in structure sensitivity of this reaction across the other seven metals studied. The main conclusion is that the enhanced activity of Pt(100) originates from more facile C-O bond breaking and removal of surface poisoning species, including CO and CH. When comparing C-O bond breaking energetics, we do not find a universal trend where these elementary steps are always more exergonic on the (100) facet. However, we find that, at a given potential, DME can be dehydrogenated (prior to breaking the C-O bond) to a greater extent on the (100) facet. Additionally, we find that the reaction energy for C-O bond breaking in CHOCH-type species becomes increasingly exergonic as the species becomes increasingly dehydrogenated. Together, the more facile dehydrogenation on the (100) facets provides more favorable routes to C-O bond activation. Though we calculate a lower onset potential on Au(100), Ag(100), Cu(100), Pt(100), and Pd(100) than their respective (111) facets, the calculated onset potential for Ni(100), Ir(100), and Rh(100) are actually higher than for their respective (111) facets. Finally, by constructing theoretical volcano plots, we conclude that Au(100), Ag(100), Cu(100), Pt(100), and Pd(100) should be more active than their respective (111) facets, while Ni(100), Rh(100), and Ir(100) will show the opposite trend. [ABSTRACT FROM AUTHOR]

Published

2015

48. Computational chemistry for NH3 synthesis, hydrotreating, and NOx reduction: Three topics of special interest to Haldor Topsøe.

Author

Elnabawy, Ahmed O., Rangarajan, Srinivas, and Mavrikakis, Manos

Subjects

*AMMONIA synthesis, *HYDROTREATING catalysts, *REDUCTION of nitrogen oxides, *COMPUTATIONAL chemistry, *ELECTRONIC structure, *HETEROGENEOUS catalysis

Abstract

Computational chemistry, especially density functional theory, has experienced a remarkable growth in terms of application over the last few decades. This is attributed to the improvements in theory and computing infrastructure that enable the analysis of systems of unprecedented size and detail at an affordable computational expense. In this perspective, we discuss recent progress and current challenges facing electronic structure theory in the context of heterogeneous catalysis. We specifically focus on the impact of computational chemistry in elucidating and designing catalytic systems in three topics of interest to Haldor Topsøe – ammonia, synthesis, hydrotreating, and NO x reduction. We then discuss the common tools and concepts in computational catalysis that underline these topics and provide a perspective on the challenges and future directions of research in this area of catalysis research. [ABSTRACT FROM AUTHOR]

Published

2015

49. Decomposition Kinetics of H2O2 on Pd Nanocrystals with Different Shapes and Surface Strains.

Author

Shi, Yifeng, Elnabawy, Ahmed O., Gilroy, Kyle D., Hood, Zachary D., Chen, Ruhui, Wang, Chenxiao, Mavrikakis, Manos, and Xia, Younan

Subjects

*SURFACE strains, *NANOCRYSTALS, *DENSITY functional theory, *HYDROGEN production, *HYDROGEN peroxide

Abstract

Direct synthesis of hydrogen peroxide (H2O2) from H2 and O2 on a Pd‐based catalyst has emerged as a promising route to replace the energy‐consuming, highly inefficient anthraquinone process. However, Pd is also a good catalyst for the decomposition of H2O2, thereby compromising the selectivity toward the desired product. The coupling between the formation and decomposition reactions makes it difficult to single out the most important parameter that controls the selectivity toward direct synthesis of H2O2. Herein, support‐free monometallic Pd nanocrystals with different shapes and surface strains are used to investigate their impacts on the decomposition kinetics of H2O2. The kinetics are analyzed by tracking the concentration of the remaining H2O2 using infrared spectroscopy. The data indicates that both surface structure and strain affect the decomposition kinetics of H2O2, but their impacts are inferior to that caused by Br−, a surface capping agent for the Pd{100} facets. The experimental results are consistent with the trend obtained through density functional theory calculations. This work helps shed light on the development of Pd‐based catalysts for the direct synthesis of H2O2 by offering strategies to mitigate the decomposition of the desired product. [ABSTRACT FROM AUTHOR]

Published

2022

50. Adsorbate-induced adatom formation on Au-Cu bimetallic alloys and its possible consequences for CO2 electroreduction.

Author

Xu, Lang, Rebarchik, Michael, Bhandari, Saurabh, and Mavrikakis, Manos

Abstract

• A theoretical framework for elucidating adsorbate-induced adatom formation on alloys. • An adatom formation energy database for Au x Cu y alloys and 18 common adsorbates. • Identify adsorbate-alloy combinations where adatom may form under catalytic conditions. • Adatoms/clusters may serve as active sites for CO 2 electroreduction on Au x Cu y catalysts. The adsorbate-induced formation of sub-nanometer clusters on transition-metal single crystals observed in previous high-pressure microscopic studies hinted at the in-situ formation of unique active sites even on large nanoparticle catalysts. We propose that the adatom formation energy can be used as an energetic descriptor for the initial step toward the adsorbate-induced metal-cluster formation process. This descriptor can be efficiently computed using density functional theory (DFT) calculations and applied for screening and identification of metal catalysts where this phenomenon may play an important role in generating active sites in-situ. As a proof of concept, here, we construct an adatom formation energy database for three Au x Cu y alloys (x:y = 3:1, 1:1, or 1:3) and eighteen adsorbates (H, C, N, O, F, S, Cl, Br, I, CH x , NH x (x = 1 – 3), CO, NO, and OH) commonly involved in catalytic reactions. The energetics of adatom formation were examined in all cases where the (111) terrace, (211) step-edge, and (874) kink were the sources of the adatom. We demonstrate that the presence of an adsorbate could alter not only the energetics for adatom formation but also the elemental nature of the preferred adatom being formed. Using our database, we identified promising systems which favor adsorbate-induced adatom formation under near-ambient conditions. Specifically, CO-induced adatom formation on all three Au-Cu alloy surfaces could occur under CO 2 electroreduction (CO 2 RR) conditions. This phenomenon offers a qualitative explanation for the experimentally observed CO 2 RR activity on Au-Cu alloy catalysts. Our methodology offers an easily expandable and efficient approach for large-scale catalyst screening with regards to adatom/cluster formation under reaction conditions and provides insight into the possible nature of active sites on alloy catalysts from a novel perspective. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2025