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2. Magnetoelectric effect in hydrogen harvesting: magnetic field as a trigger of catalytic reactions

Author

Kim, Donghoon, Efe, Ipek, Torlakcik, Harun, Terzopoulou, Anastasia, Picazo, Andrea Veciana, Siringil, Erdem, Mushtaq, Fajer, Franco, Carlos, Puigmartí-Luis, Josep, Nelson, Bradley, Spaldin, Nicola A., Gattinoni, Chiara, Chen, Xiangzhong, and Pané, Salvador

Subjects
Condensed Matter - Materials Science
Abstract

Magnetic fields have been regarded as an additional stimulus for electro- and photocatalytic reactions, but not as a direct trigger for catalytic processes. Multiferroic/magnetoelectric materials, whose electrical polarization and surface charges can be magnetically altered, are especially suitable for triggering and control of catalytic reactions solely with magnetic fields. Here, we demonstrate that magnetic fields can be employed as an independent input energy source for hydrogen harvesting by means of the magnetoelectric effect. Composite multiferroic CoFe2O4-BiFeO3 core-shell nanoparticles act as catalysts for the hydrogen evolution reaction (HER) that is triggered when an alternating magnetic field is applied to an aqueous dispersion of the magnetoelectric nanocatalysts. Based on density functional calculations, we propose that the hydrogen evolution is driven by changes in the ferroelectric polarization direction of BiFeO3 caused by the magnetoelectric coupling. We believe our findings will open new avenues towards magnetically induced renewable energy harvesting., Comment: 26pages including supplementary information, 4 figures

Published
2021
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3. A strong polarizing field in thin-film paraelectrics

Author

Gattinoni, Chiara and Spaldin, Nicola A.

Subjects
Condensed Matter - Materials Science
Abstract

The surface charge associated with the spontaneous polarization in ferroelectrics is well known to cause a depolarizing field that can be particularly detrimental in the thin-film geometry desirable for microelectronic devices. Incomplete screening of the surface charge, for example by metallic electrodes or surface adsorbates, can lead to the formation of domains, suppression or reorientation of the polarization, or even stabilization of a higher energy non-polar phase . A huge amount of research and development effort has been invested in understanding the depolarizing behavior and minimizing its unfavorable effects. Here we demonstrate the opposite behavior: A strong polarizing field that drives thin films of materials that are centrosymmetric and paraelectric in their bulk form into a non-centrosymmetric, polar state. We illustrate the behavior using density functional computations for perovskite-structure potassium tantalate, KTaO$_3$, which is of considerable interest for its high dielectric constant, proximity to a quantum critical point and superconductivity. We then provide a simple recipe to identify whether a particular material and film orientation will exhibit the effect, and develop an electrostatic model to estimate the critical thickness of the induced polarization in terms of well-known material parameters. Our results provide practical guidelines for exploiting the electrostatic properties of thin-film ionic insulators to engineer novel functionalities for nanoscale devices., Comment: Version 2 is updated to include 3 appendices A) with DOSs for larger slabs, B) with more details of the derivations, and C) with the Matlab code for the model calculation. (Also fixed a couple of typos.)

Published
2021

4. Layer and spontaneous polarizations in perovskite oxides and their interplay in multiferroic bismuth ferrite

Author

Spaldin, Nicola A, Efe, Ipek, Rossell, Marta D, and Gattinoni, Chiara

Subjects
Condensed Matter - Materials Science
Abstract

We review the concept of surface charge, first in the context of the polarization in ferroelectric materials, and second in the context of layers of charged ions in ionic insulators. While the former is traditionally discussed in the ferroelectrics community, and the latter in the surface science community, we remind the reader that the two descriptions are conveniently unified within the modern theory of polarization. In both cases, the surface charge leads to electrostatic instability - the so-called "polar catastrophe" - if it is not compensated, and we review the range of phenomena that arise as a result of different compensation mechanisms. We illustrate these concepts using the example of the prototypical multiferroic bismuth ferrite, BiFeO3, which is unusual in that its spontaneous ferroelectric polarization and its layer charges can be of the same magnitude. As a result, for certain combinations of polarization orientation and surface terminationits surface charge is self-compensating. We use density functional calculations of BiFeO3 slabs and superlattices, analysis of high-resolution transmission electron micrographs as well as examples from the literature to explore the consequences of this peculiarity., Comment: Submitted to the Journal of Chemical Physics

Published
2021
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5. On the happiness of ferroelectric surfaces and its role in water dissociation: the example of bismuth ferrite

Author

Efe, Ipek, Spaldin, Nicola A., and Gattinoni, Chiara

Subjects
Condensed Matter - Materials Science
Abstract

We investigate, using density functional theory, how the interaction between the ferroelectric polarization and the chemical structure of the (001) surfaces of bismuth ferrite influences the surface properties and reactivity of this material. A precise understanding ofthe surface behavior of ferroelectrics is necessary for their use in surface science applications such as catalysis as well as for their incorporation in microelectronic devices. Using the (001) surface of bismuth ferrite as a model system we show that the most energetically favoured surface geometries are combinations of surface termination and polarization direction that lead to uncharged, stable surfaces. On the unfavorable charged surfaces, we explore the compensation mechanisms of surface charges provided by the introduction of point defects and adsorbates, such as water. Finally, we propose that the special surface properties of bismuth ferrite (001) could be used to produce an effective water splitting cycle through cyclic polarization switching., Comment: The following article has been submitted to the Journal of Chemical Physics

Published
2020
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6. Chirality at two-dimensional surfaces: A perspective from small molecule alcohol assembly on Au(111)

Author

Liriano, Melissa L., Larson, Amanda M., Gattinoni, Chiara, Carrasco, Javier, Baber, Ashleigh E., Lewis, Emily A., Murphy, Colin J., Lawton, Timothy J., Marcinkowski, Matthew D., Therrien, Andrew J., Michaelides, Angelos, and Sykes, E. Charles H.

Subjects
Condensed Matter - Materials Science
Abstract

The delicate balance between H-bonding and van der Waals interactions determine the stability,structure and chirality of many molecular and supramolecular aggregates weakly adsorbed on solid surfaces.Yet the inherent complexity of these systems makes their experimental study at the molecular level very challenging.Small alcohols adsorbed on metal surfaces have become a useful model system to gain fundamental insight into the interplay of such molecule-surface and molecule-molecule interactions.Here, through a combination of scanning tunneling microscopy and density functional theory,we compare and contrast the adsorption and self-assembly of a range of small alcohols from methanol to butanol on Au(111).We find that that longer chained alcohols prefer to form zigzag chains held together by extended H-bonded networks between adjacent molecules.When alcohols bind to a metal surface datively via one of the two lone electron pairs of the oxygen atom they become chiral.Therefore,the chain structures are formed by a H-bonded network between adjacent molecules with alternating adsorbed chirality.These chain structures accommodate longer alkyl tails through larger unit cells, while the position of the hydroxyl group within the alcohol molecule can produce denser unit cells that maximize intermolecular interactions.Interestingly,when intrinsic chirality is introduced into the molecule as in the case of 2-butanol the assembly changes completely and square packing structures with chiral pockets are observed. This is rationalized by the fact that the intrinsic chirality of the molecule directs the chirality of the adsorbed hydroxyl group meaning that heterochiral chain structures cannot form.Overall this study provides a general framework for understanding the effect of simple alcohol molecular adstructures on H-bonded aggregates and paves the way for rationalizing 2D chiral supramolecular assembly.

Published
2018
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7. Water (Non-)Interaction with MoO3

Author

Head, Ashley R, Gattinoni, Chiara, Trotochaud, Lena, Yu, Yi, Karslıoğlu, Osman, Pletincx, Sven, Eichhorn, Bryan, and Bluhm, Hendrik

Subjects
Chemical Sciences, Physical Chemistry, Engineering, Technology, Chemical sciences
Abstract

Molybdenum(VI) oxide (MoO3) is used in a number of technical processes such as gas filtration and heterogeneous catalysis. In these applications, the adsorption and dissociation of water on the surface can influence the chemistry of MoO3 and thus the course of heterogeneous reactions. We use ambient pressure X-ray photoelectron spectroscopy to study the interaction of water with a stoichiometric MoO3 surface and a MoO3 surface that features oxygen defects and hydroxyl groups. The experimental results are supported by density functional theory calculations. We show that on a stoichiometric MoO3(010) surface, where Mo sites are unavailable, water adsorption is strongly disfavored. However, the introduction of surface species, which can interact with the lone pairs on the water O atom, e.g., Mo5+ atoms or surface OH groups, promotes water adsorption. Dissociation of water is favored at unsaturated Mo sites, i.e., at oxygen vacancies, while water adsorbs molecularly at hydroxyl sites.

Published
2019

10. Understanding corrosion inhibition with van der Waals DFT methods: the case of benzotriazole

Author

Gattinoni, Chiara and Michaelides, Angelos

Subjects
Condensed Matter - Materials Science
Abstract

The corrosion of materials is an undesirable and costly process affecting many areas of technology and everyday life. As such, considerable effort has gone into understanding and preventing it. Organic molecule based coatings can in certain circumstances act as effective corrosion inhibitors. Although they have been used to great effect for more than sixty years, how they function at the atomic-level is still a matter of debate. In this work, computer simulation approaches based on density functional theory are used to investigate benzotriazole (BTAH), one of the most widely used and studied corrosion inhibitors for copper. In particular, the structures formed by protonated and deprotonated BTAH molecules on Cu(111) have been determined and linked to their inhibiting properties. It is found that hydrogen bonding, van der Waals interactions and steric repulsions all contribute in shaping how BTAH molecules adsorb, with flat-lying structures preferred at low coverage and upright configurations preferred at high coverage. The interaction of the dehydrogenated benzotriazole molecule (BTA) with the copper surface is instead dominated by strong chemisorption via the azole moiety with the aid of copper adatoms. Structures of dimers or chains are found to be the most stable structures at all coverages, in good agreement with scanning tunnelling microscopy results. Benzotriazole thus shows a complex phase behaviour in which van der Waals forces play an important role and which depends on coverage and on its protonation state and all of these factors feasibly contribute to its effectiveness as a corrosion inhibitor., Comment: 20 pages, 7 figures

Published
2015
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11. Atomistic details of oxide surfaces and surface oxidation: the example of copper and its oxides

Author

Gattinoni, Chiara and Michaelides, Angelos

Subjects
Condensed Matter - Materials Science
Abstract

The oxidation and corrosion of metals are fundamental problems in materials science and technology that have been studied using a large variety of experimental and computational techniques. Here we review some of the recent studies that have led to significant advances in our atomic-level understanding of copper oxide, one of the most studied and best understood metal oxides. We show that a good atomistic understanding of the physical characteristics of cuprous (Cu$_2$O) and cupric (CuO) oxide and of some key processes of their formation has been obtained. Indeed, the growth of the oxide has been shown to be epitaxial with the surface and to proceed, in most cases, through the formation of oxide nano-islands which, with continuous oxygen exposure, grow and eventually coalesce. We also show how electronic structure calculations have become increasingly useful in helping to characterise the structures and energetics of various Cu oxide surfaces. However a number of challenges remain. For example, it is not clear under which conditions the oxidation of copper in air at room temperature (known as native oxidation) leads to the formation of a cuprous oxide film only, or also of a cupric overlayer. Moreover, the atomistic details of the nucleation of the oxide islands are still unknown. We close our review with a brief perspective on future work and discuss how recent advances in experimental techniques, bringing greater temporal and spatial resolution, along with improvements in the accuracy, realism and timescales achievable with computational approaches make it possible for these questions to be answered in the near future., Comment: 24 pages, 11 figures

Published
2015
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15. Layer and spontaneous polarizations in perovskite oxides and their interplay in multiferroic bismuth ferrite

Author

Spaldin, Nicola A., Efe, Ipek, Rossell, Marta D., and Gattinoni, Chiara

Subjects
Condensed Matter::Materials Science
Abstract

We review the concept of surface charge, first, in the context of the polarization in ferroelectric materials and, second, in the context of layers of charged ions in ionic insulators. While the former is traditionally discussed in the ferroelectrics community and the latter in the surface science community, we remind the reader that the two descriptions are conveniently unified within the modern theory of polarization. In both cases, the surface charge leads to electrostatic instability—the so-called “polar catastrophe”—if it is not compensated, and we review the range of phenomena that arise as a result of different compensation mechanisms. We illustrate these concepts using the example of the prototypical multiferroic bismuth ferrite, BiFeO3, which is unusual in that its spontaneous ferroelectric polarization and the polarization arising from its layer charges can be of the same magnitude. As a result, for certain combinations of polarization orientation and surface termination, its surface charge is self-compensating. We use density functional calculations of BiFeO3 slabs and superlattices, analysis of high-resolution transmission electron micrographs, and examples from the literature to explore the consequences of this peculiarity. ISSN:0021-9606 ISSN:1089-7690

Published
2021

16. Adsorption of Surfactants on alpha-Fe2O3(0001): A Density Functional Theory Study

Author

Gattinoni, Chiara, Ewen, James P., and Dini, Daniele

Abstract

From corrosion inhibition to lubrication, a detailed understanding of the interactions between surfactants and iron oxide surfaces is critical for a range of industrial applications. However, there is still limited understanding of this behavior at the atomic-level, which hinders the design of improved surfactant molecules. In this study, the adsorption of three surfactants which are commonly employed as lubricant additives (carboxylic acid, amide, monoglyceride) on a α-Fe2O3(0001) surface is studied with density functional theory. The nature and strength of the adsorption for the different surfactants, as well as their propensity to deprotonate on the surface, is studied at a range of surface coverages. In agreement with the available experiments, strong chemisorption on α-Fe2O3(0001) is observed for all cases considered. Dissociation is energetically favorable for carboxylic acid and glyceride surfactants through the formation of a surface hydroxyl group, whereas this is not the case for amides. Glycerides form the most strongly adsorbed films at both low and high surface coverage due to the presence of multiple functional groups, which can all act as binding sites. However, the large size of the glyceride headgroup also means that adsorption is stronger at low coverage, where the formation of multiple bonds with the surface is possible, than at high coverage. Conversely, carboxylic acid films have similar stability at low and high coverage, where van der Waals forces between proximal tailgroups stabilize the adsorption structures. The results of this study provide atomic-level insights which help to explain friction results from previous macroscopic tribology experiments and classical molecular dynamics simulations. They also facilitate the molecular design of new surfactants to maximize the adsorption energy, surface coverage, and ultimately friction reduction on iron oxide surfaces., The Journal of Physical Chemistry C, 122 (36), ISSN:1932-7455, ISSN:1932-7447

Published
2018

17. Piezoelectrically Enhanced Photocatalysis with BiFeO 3 Nanostructures for Efficient Water Remediation

Author

Mushtaq, Fajer, Chen, Xiangzhong, Hoop, Marcus, Torlakcik, Harun, Pellicer, Eva, Sort, Jordi, Gattinoni, Chiara, Nelson, Bradley J., and Pané, Salvador

Subjects
Chemistry, Catalysis, Environmental Nanotechnology
Abstract

Designing new catalysts that can efficiently utilize multiple energy sources can contribute to solving the current challenges of environmental remediation and increasing energy demands. In this work, we fabricated single-crystalline BiFeO3 (BFO) nanosheets and nanowires that can successfully harness visible light and mechanical vibrations and utilize them for degradation of organic pollutants. Under visible light both BFO nanostructures displayed a relatively slow reaction rate. However, under piezocatalysis both nanosheets and nanowires exhibited higher reaction rates in comparison with photocatalytic degradation. When both solar light and mechanical vibrations were used simultaneously, the reaction rates were elevated even further, with the BFO nanowires degrading 97% of RhB dye within 1 hr (k-value 0.058 min−1). The enhanced degradation under mechanical vibrations can be attributed to the promotion of charge separation caused by the internal piezoelectric field of BFO. BFO nanowires also exhibited good reusability and versatility toward degrading four different organic pollutants. ISSN:2589-0042

Published
2018

19. On the effect of confined fluid molecular structure on nonequilibrium phase behaviour and friction

Author

Ewen, James P., Gattinoni, Chiara, Zhang, Jie, Heyes, David M., Spikes, Hugh A., Dini, Daniele, Engineering & Physical Science Research Council (EPSRC), Shell Research Limited, and Engineering and Physical Sciences Research Council

Subjects
Science & Technology, Chemical Physics, 02 Physical Sciences, Chemistry, Physical, DYNAMICS SIMULATIONS, Physics, LIQUID LUBRICANTS, Physics, Atomic, Molecular & Chemical, 09 Engineering, Chemistry, ELASTOHYDRODYNAMIC LUBRICATION, IONIC LIQUIDS, N-ALKANES, Physical Sciences, HIGH-PRESSURE, WALL SLIP, EXTREME CONDITIONS, SHEAR-FLOW, AA FORCE-FIELD, 03 Chemical Sciences
Abstract

A detailed understanding of the behaviour of confined fluids is critical to a range of industrial applications, for example to control friction in engineering components. In this study, a combination of tribological experiments and confined nonequilibrium molecular dynamics simulations has been used to investigate the effect of base fluid molecular structure on nonequilibrium phase behaviour and friction. An extensive parameter study, including several lubricant and traction fluid molecules subjected to pressures (0.5–2.0 GPa) and strain rates (104–1010 s−1) typical of the elastohydrodynamic lubrication regime, reveals clear relationships between the friction and flow behaviour. Lubricants, which are flexible, broadly linear molecules, give low friction coefficients that increase with strain rate and pressure in both the experiments and the simulations. Conversely, traction fluids, which are based on inflexible cycloaliphatic groups, give high friction coefficients that only weakly depend on strain rate and pressure. The observed differences in friction behaviour can be rationalised through the stronger shear localisation which is observed for the traction fluids in the simulations. Higher pressures lead to more pronounced shear localisation, whilst increased strain rates lead to a widening of the sheared region. The methods utilised in this study have clarified the physical mechanisms of important confined fluid behaviour and show significant potential in both improving the prediction of elastohydrodynamic friction and developing new molecules to control it., Physical Chemistry Chemical Physics, 19 (27), ISSN:1463-9084, ISSN:1463-9076

Published
2017

21. Prediction of a strong polarizing field in thin film paraelectrics

Author

Gattinoni, Chiara and Spaldin, Nicola A.

Abstract

We demonstrate the existence of a polarizing field in thin films of insulators with charged ionic layers. The polarizing field derives from the same physics as the well-known depolarizing field that suppresses ferroelectric polarization in thin-film ferroelectrics, but instead drives thin films of materials that are centrosymmetric and paraelectric in their bulk form into a noncentrosymmetric, polar state. We illustrate the behavior using density-functional computations for perovskite-structure potassium tantalate, KTaO3, which is of considerable interest for its high dielectric constant, proximity to a quantum critical point, and superconductivity. We then provide a simple recipe to identify whether a particular material and film orientation will exhibit the effect and develop an electrostatic model to estimate the critical thickness of the induced polarization in terms of basic material parameters. Our results provide practical guidelines for exploiting the electrostatic properties of thin-film ionic insulators to engineer novel functionalities for nanoscale devices., Physical Review Research, 4 (3), ISSN:2643-1564

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22. Layer and spontaneous polarizations in perovskite oxides and their interplay in multiferroic bismuth ferrite

Author

Spaldin, Nicola A, Efe, Ipek, Rossell, Marta D, and Gattinoni, Chiara

Subjects
Condensed Matter::Materials Science, Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences
Abstract

We review the concept of surface charge, first in the context of the polarization in ferroelectric materials, and second in the context of layers of charged ions in ionic insulators. While the former is traditionally discussed in the ferroelectrics community, and the latter in the surface science community, we remind the reader that the two descriptions are conveniently unified within the modern theory of polarization. In both cases, the surface charge leads to electrostatic instability - the so-called "polar catastrophe" - if it is not compensated, and we review the range of phenomena that arise as a result of different compensation mechanisms. We illustrate these concepts using the example of the prototypical multiferroic bismuth ferrite, BiFeO3, which is unusual in that its spontaneous ferroelectric polarization and its layer charges can be of the same magnitude. As a result, for certain combinations of polarization orientation and surface terminationits surface charge is self-compensating. We use density functional calculations of BiFeO3 slabs and superlattices, analysis of high-resolution transmission electron micrographs as well as examples from the literature to explore the consequences of this peculiarity., Submitted to the Journal of Chemical Physics

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