Your search keyword '"Saleh, Gabriele"' showing total 14 results

1. Boosting the Photoluminescence Efficiency of InAs Nanocrystals Synthesized with Aminoarsine via a ZnSe Thick‐Shell Overgrowth.

Author

Zhu, Dongxu, Bahmani Jalali, Houman, Saleh, Gabriele, Di Stasio, Francesco, Prato, Mirko, Polykarpou, Nefeli, Othonos, Andreas, Christodoulou, Sotirios, Ivanov, Yurii P., Divitini, Giorgio, Infante, Ivan, De Trizio, Luca, and Manna, Liberato

Published

2023

2. High-performance alkaline water electrolyzers based on Ru-perturbed Cu nanoplatelets cathode.

Author

Zuo, Yong, Bellani, Sebastiano, Ferri, Michele, Saleh, Gabriele, Shinde, Dipak V., Zappia, Marilena Isabella, Brescia, Rosaria, Prato, Mirko, De Trizio, Luca, Infante, Ivan, Bonaccorso, Francesco, and Manna, Liberato

Subjects

COPPER, ELECTROLYTIC cells, IRON-nickel alloys, CATHODES, STAINLESS steel, NANOPARTICLES, HYDROGEN evolution reactions

Abstract

Alkaline electrolyzers generally produce hydrogen at current densities below 0.5 A/cm2. Here, we design a cost-effective and robust cathode, consisting of electrodeposited Ru nanoparticles (mass loading ~ 53 µg/cm2) on vertically oriented Cu nanoplatelet arrays grown on metallic meshes. Such cathode is coupled with an anode based on stacked stainless steel meshes, which outperform NiFe hydroxide catalysts. Our electrolyzers exhibit current densities as high as 1 A/cm2 at 1.69 V and 3.6 A/cm2 at 2 V, reaching the performances of proton-exchange membrane electrolyzers. Also, our electrolyzers stably operate in continuous (1 A/cm2 for over 300 h) and intermittent modes. A total production cost of US$2.09/kgH2 is foreseen for a 1 MW plant (30-year lifetime) based on the proposed electrode technology, meeting the worldwide targets (US$2–2.5/kgH2). Hence, the use of a small amount of Ru in cathodes (~0.04 gRu per kW) is a promising strategy to solve the dichotomy between the capital and operational expenditures of conventional alkaline electrolyzers for high-throughput operation, while facing the scarcity issues of Pt-group metals. Achieving high-efficiency alkaline water electrolyzer operating at large current densities remains a critical challenge. Here the authors report Ru nanoparticle-perturbed Cu nanoplatelets as cathode for hydrogen evolution reaction coupled with stainless steel anode in alkaline electrolyzer with high performance, long-term stability and relatively low-capital expenditures. [ABSTRACT FROM AUTHOR]

Published

2023

3. Colloidal Bismuth Chalcohalide Nanocrystals.

Author

Quarta, Danila, Toso, Stefano, Giannuzzi, Roberto, Caliandro, Rocco, Moliterni, Anna, Saleh, Gabriele, Capodilupo, Agostina‐Lina, Debellis, Doriana, Prato, Mirko, Nobile, Concetta, Maiorano, Vincenzo, Infante, Ivan, Gigli, Giuseppe, Giannini, Cinzia, Manna, Liberato, and Giansante, Carlo

Subjects

THIN films, BAND gaps, CHEMICAL stability, ABSORPTION coefficients, METAL halides, BISMUTH

Abstract

Here we present a colloidal approach to synthesize bismuth chalcohalide nanocrystals (BiEX NCs, in which E=S, Se and X=Cl, Br, I). Our method yields orthorhombic elongated BiEX NCs, with BiSCl crystallizing in a previously unknown polymorph. The BiEX NCs display a composition‐dependent band gap spanning the visible spectral range and absorption coefficients exceeding 105 cm−1. The BiEX NCs show chemical stability at standard laboratory conditions and form colloidal inks in different solvents. These features enable the solution processing of the NCs into robust solid films yielding stable photoelectrochemical current densities under solar‐simulated irradiation. Overall, our versatile synthetic protocol may prove valuable in accessing colloidal metal chalcohalide nanomaterials at large and contributes to establish metal chalcohalides as a promising complement to metal chalcogenides and halides for applied nanotechnology. [ABSTRACT FROM AUTHOR]

Published

2022

4. Colloidal Bismuth Chalcohalide Nanocrystals.

Author

Quarta, Danila, Toso, Stefano, Giannuzzi, Roberto, Caliandro, Rocco, Moliterni, Anna, Saleh, Gabriele, Capodilupo, Agostina‐Lina, Debellis, Doriana, Prato, Mirko, Nobile, Concetta, Maiorano, Vincenzo, Infante, Ivan, Gigli, Giuseppe, Giannini, Cinzia, Manna, Liberato, and Giansante, Carlo

Subjects

THIN films, BAND gaps, CHEMICAL stability, ABSORPTION coefficients, METAL halides, BISMUTH

Abstract

Here we present a colloidal approach to synthesize bismuth chalcohalide nanocrystals (BiEX NCs, in which E=S, Se and X=Cl, Br, I). Our method yields orthorhombic elongated BiEX NCs, with BiSCl crystallizing in a previously unknown polymorph. The BiEX NCs display a composition‐dependent band gap spanning the visible spectral range and absorption coefficients exceeding 105 cm−1. The BiEX NCs show chemical stability at standard laboratory conditions and form colloidal inks in different solvents. These features enable the solution processing of the NCs into robust solid films yielding stable photoelectrochemical current densities under solar‐simulated irradiation. Overall, our versatile synthetic protocol may prove valuable in accessing colloidal metal chalcohalide nanomaterials at large and contributes to establish metal chalcohalides as a promising complement to metal chalcogenides and halides for applied nanotechnology. [ABSTRACT FROM AUTHOR]

Published

2022

5. Engineering the Optical Emission and Robustness of Metal‐Halide Layered Perovskites through Ligand Accommodation.

Author

Dhanabalan, Balaji, Biffi, Giulia, Moliterni, Anna, Olieric, Vincent, Giannini, Cinzia, Saleh, Gabriele, Ponet, Louis, Prato, Mirko, Imran, Muhammad, Manna, Liberato, Krahne, Roman, Artyukhin, Sergey, and Arciniegas, Milena P.

Published

2021

6. Silver Tarnishing Mechanism Revealed by Molecular Dynamics Simulations.

Author

Saleh, Gabriele, Xu, Chen, and Sanvito, Stefano

Subjects

SILVER sulfide, MOLECULAR dynamics, SILVER, ION migration & velocity, THERMODYNAMICS, SULFUR

Abstract

The mechanism of silver–oxygen and silver–sulfur reactions is revealed by means of molecular dynamics simulations, performed with reactive force fields purposely built and extensively tested against quantum‐chemical results. Different reaction mechanisms and rates for Ag–O and Ag–S emerge. This study solves the long‐lasting question why silver exposed to the environment is strongly vulnerable to sulfur corrosion (tarnishing) but hardly reacts with O2, despite the thermodynamic prediction that both oxide and sulfide should form. The reliability of the simulation results is confirmed by the agreement with a multitude of experimental results from the literature. Varnish the tarnish: Sulfur corrodes silver very efficiently while O2 hardly reacts, a difference that thermodynamics cannot explain. With large‐scale molecular dynamics, it is shown that Ag oxide growth is hindered by the inherently self‐limiting mechanism and strong O–O repulsion. Ag sulfide instead grows by an upward migration of Ag ions, a kinetically efficient process. The differences are rationalized by ab initio calculations. [ABSTRACT FROM AUTHOR]

Published

2019

7. Silver Tarnishing Mechanism Revealed by Molecular Dynamics Simulations.

Author

Saleh, Gabriele, Xu, Chen, and Sanvito, Stefano

Subjects

MOLECULAR dynamics, DESULFURIZATION, SILVER, REACTIVE flow, THERMODYNAMICS

Abstract

Copyright of Angewandte Chemie is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

8. Boosting the Photoluminescence Efficiency of InAs Nanocrystals Synthesized with Aminoarsine via a ZnSe Thick‐Shell Overgrowth (Adv. Mater. 38/2023).

Author

Zhu, Dongxu, Bahmani Jalali, Houman, Saleh, Gabriele, Di Stasio, Francesco, Prato, Mirko, Polykarpou, Nefeli, Othonos, Andreas, Christodoulou, Sotirios, Ivanov, Yurii P., Divitini, Giorgio, Infante, Ivan, De Trizio, Luca, and Manna, Liberato

Published

2023

9. Ab initio surface properties of Ag–Sn alloys: implications for lead-free soldering.

Author

Saleh, Gabriele, Xu, Chen, and Sanvito, Stefano

Abstract

Ag and Sn are the major components of solder alloys adopted to assemble printed circuit boards. The qualities that make them the alloys of choice for the modern electronic industry are related to their physical and chemical properties. For corrosion resistance and solderability, surface properties are particularly important. Yet, atomic-level information about the surfaces of these alloys is not known. Here we fill this gap by presenting an extensive ab initio investigation of composition, energetics, structure and reactivity of Ag–Sn alloy surfaces. The structure and stability of various surfaces is evaluated, and the main factors determining the energetics of surface formation are uncovered. Oxygen and sulphur chemisorptions are studied and discussed in the framework of corrosion tendency, an important issue for printed circuit boards. Adsorption energy trends are rationalized based on the analysis of structural and electronic features. [ABSTRACT FROM AUTHOR]

Published

2018

10. Source Function applied to experimental densities reveals subtle electron-delocalization effects and appraises their transferability properties in crystals.

Author

Gatti, Carlo, Saleh, Gabriele, and Lo Presti, Leonardo

Subjects

GREEN'S functions, ELECTRON delocalization, MOLECULAR crystals

Abstract

The Source Function (SF), introduced in 1998 by Richard Bader and Carlo Gatti, is succinctly reviewed and a number of paradigmatic applications to in vacuo and crystal systems are illustrated to exemplify how the SF may be used to discuss chemical bonding in both conventional and highly challenging cases. The SF enables the electron density to be seen at a point determined by source contributions from the atoms or a group of atoms of a system, and it is therefore well linked to the chemist's awareness that any local property and chemical behaviour is to some degree influenced by all the remaining parts of a system. The key and captivating feature of the SF is that its evaluation requires only knowledge of the electron density (ED) of a system, thereby enabling a comparison of ab initio and X-ray diffraction derived electron density properties on a common and rigorous basis. The capability of the SF to detect electron-delocalization effects and to quantify their degree of transferability is systematically explored in this paper through the analysis and comparison of experimentally X-ray derived Source Function patterns in benzene, naphthalene and (±)-8′-benzhydrylideneamino-1,1′-binaphthyl-2-ol (BAB) molecular crystals. It is shown that the SF tool recovers the characteristic SF percentage patterns caused by π-electron conjugation in the first two paradigmatic aromatic molecules in almost perfect quantitative agreement with those obtained from ab initio periodic calculations. Moreover, the effect of chemical substitution on the degree of transferability of such patterns to the benzene- and naphthalene-like moieties of BAB is neatly shown and quantified by the observed systematic deviations, relative to benzene and naphthalene, of only those SF contributions from the substituted C atoms. Finally, the capability of the SF to reveal electron-delocalization effects is challenged by using a promolecule density, rather than the proper quantum mechanical density, to determine the changes in SF patterns along the cyclohexene, 1,3-cyclohexadiene and benzene molecule series. It is shown that, differently from the proper quantum density, the promolecular density is unable to reproduce the SF trends anticipated by the increase of electron delocalization along the series, therefore ruling out the geometrical effect as being the only cause for the observed SF patterns changes. [ABSTRACT FROM AUTHOR]

Published

2016

11. NCImilano: an electron-density-based code for the study of noncovalent interactions.

Author

Saleh, Gabriele, Lo Presti, Leonardo, Gatti, Carlo, and Ceresoli, Davide

Subjects

MASS density gradients, PHENOMENOLOGICAL equations, DENSITY gradient centrifugation, GAS phase reactions, CHEMICAL reactions, SOLID state chemistry, GAUSSIAN distribution

Abstract

NCImilano, a Fortran90 code for applying the reduced density gradient (RDG) descriptor to a real-space study of noncovalent interactions, is presented. This code has been specifically designed for the X-ray charge density community, as it can deal with both gas-phase and solid-state electron densities as evaluated by popular multipolar ( XD2006) and Gaussian-based quantum mechanical ( Gaussian03/ 09, CRYSTAL) computational platforms. Moreover, it implements for the first time the possibility of plotting energy densities over RDG isosurfaces. [ABSTRACT FROM AUTHOR]

Published

2013

12. Progress in the Understanding of the Key Pharmacophoric Features of the Antimalarial Drug Dihydroartemisinin: An Experimental and Theoretical Charge Density Study.

Author

Saleh, Gabriele, Soave, Raffaella, Lo Presti, Leonardo, and Destro, Riccardo

Abstract

The accurate, experimental charge density distribution, ρ( r), of the potent antimalarial drug dihydroartemisinin (DHA) has been derived for the first time from single-crystal X-ray diffraction data at T=100(2) K. Gas-phase and solid-state DFT simulations have also been performed to provide a firm basis of comparison with experimental results. The quantum theory of atoms in molecules (QTAIM) has been employed to analyse the ρ( r) scalar field, with the aim of classifying and quantifying the key real-space elements responsible for the known pharmacophoric features of DHA. From the conformational perspective, the bicyclo[3.2.2]nonane system fixes the three-dimensional arrangement of the 1,2,4-trioxane bearing the active OO redox centre. This is the most nucleophilic function in DHA and acts as an important CH⋅⋅⋅O acceptor. On the contrary, the rest of the molecular backbone is almost neutral, in accordance with the lipophilic character of the compound. Another remarkable feature is the CO bond length alternation along the O-C-O-C polyether chain, due to correlations between pairs of adjacent CO bonds. These bonding features have been related with possible reactivity routes of the α- and β-DHA epimers, namely 1) the base-catalysed hemiacetal breakdown and 2) the peroxide reduction. As a general conclusion, the base-driven proton transfer has significant non-local effects on the whole polyether chain, whereas DHA reduction is thermodynamically favourable and invariably leads to a significant weakening (or even breaking) of the OO bond. The influence of the hemiacetal stereochemistry on the electronic properties of the system has also been considered. Such findings are discussed in the context of the known chemical reactivity of this class of important antimalarial drugs. [ABSTRACT FROM AUTHOR]

Published

2013

13. Revealing Non-covalent Interactions in Molecular Crystals through Their Experimental Electron Densities.

Author

Saleh, Gabriele, Gatti, Carlo, Lo Presti, Leonardo, and Contreras-García, Julia

Abstract

Non-covalent interactions (NCI) define the rules underlying crystallisation, self-assembly and drug-receptor docking processes. A novel NCI descriptor, based on the reduced electron density gradient (RDG), that enables easy visualisation of the zones of the electron density (ED) involved in either the supposedly attractive (dispersive, hydrogen bonding) or allegedly repulsive (steric) intermolecular interactions, was recently developed by Johnson et al. Here, it is applied for the first time to EDs derived from single-crystal X-ray diffraction data. A computer code handling both experimental and ab initio EDs in the RDG-NCI perspective was purposely written. Three cases spanning a wide range of NCI classes were analysed: 1) benzene, as the prototype of stacking and weak CH ⋅⋅⋅π interactions; 2) austdiol, a heavily functionalised fungal metabolite with a complex hydrogen-bonding network; 3) two polymorphs of the heteroatom-rich anti-ulcer drug famotidine, with van der Waals and hydrogen-bond contacts between N- and S-containing groups. Even when applied to experimental EDs, the RDG index is a valuable NCI descriptor that can highlight their different nature and strength and provide results of comparable quality to ab initio approaches. Combining the RDG-NCI study with Bader's ED approach was a key step forward, as the RDG index can depict inherently delocalised interactions in terms of extended and flat RDG isosurfaces, in contrast to the bond path analysis, which is often bounded to a too localised and possibly discontinuous (yes/no) description. Conversely, the topological tool can provide quantitative insight into the simple, qualitative NCI picture offered by the RDG index. Hopefully, this study may pave the way to a deeper analysis of weak interactions in proteins using structural and ED information from experiment. [ABSTRACT FROM AUTHOR]

Published

2012

14. Novel Stable Compounds in the C-H-O Ternary System at High Pressure.

Author

Saleh, Gabriele and Oganov, Artem R.

Published

2016