Your search keyword '"Celino, M."' showing total 23 results

1. Study of solid molecular deuterium D2 growth under gas pressure

Author

Giusepponi, S., Buonocore, F., Celino, M., Lupo Pasini, M., Frattolillo, A., and Migliori, S.

Published

2022

2. Ultra-Fast High-Precision Metallic Nanoparticle Synthesis using Laser-Accelerated Protons

Author

Barberio, M., Giusepponi, S., Vallières, S., Scisció, M., Celino, M., and Antici, P.

Published

2020

3. Progetti, tecnologie e soluzioni ENEA per la transizione e la sostenibilità energetica

Author

D'Agosta, G., De Fazio, P., Prosini, P. P., Cigolotti, V., Della Pietra, M., Roca, F., Mittiga, A., De Juliis, S., Celino, M., Costanzo, E., Sabatelli, V., Roberto, R., Ponti, G., Dipinto, S., Pierro, N., Motola, V., Giocoli, A., De Bari, Isabella, D'Agosta, G., De Fazio, P., Prosini, P. P., Cigolotti, V., Della Pietra, M., Roca, F., Mittiga, A., De Juliis, S., Celino, M., Costanzo, E., Sabatelli, V., Roberto, R., Ponti, G., Dipinto, S., Pierro, N., Motola, V., Giocoli, A., and De Bari, Isabella

Subjects

Comunità energetiche, Accumulo energetico, Mobilità sostenibile, Biomasse, Bioenergia, Smart grid, Idrogeno, Smart cities

Published

2023

4. FIRST PRINCIPLES MOLECULAR DYNAMICS SIMULATIONS OF AMORPHOUS GEO2 UNDER PRESSURE IN THE RANGE 0-30GPA

Author

Mancini, G. and Celino, M.

Published

2020

5. Turning Open Science and Open Innovation into reality

Author

Bassini S., Boccali T., Cacciaguerra S., Castelli D., Celino M., Cocco M., Di Giorgio S., Giorgetti A., Kourousias G., Locati M., Lucchesi D, Migliori S., Pappalardo G., Perini L., Petrillo C., Pugliese R., Rossi G., Ruggieri F., Smareglia R., and Tanlongo F.

Subjects

EOSC, FAIR Principles, EOSC Research and Innovation Agenda, ICDI, European Open Science Cloud

Abstract

This document summarises the views expressed by the Italian Computing and Data Initiative (ICDI) in response to the open consultation for the EOSC Strategic Research and Innovation Agenda (SRIA), closed on the 31st of August. It provides insightful input and suggestions about the current draft of the SRIA document shared with the wider EOSC community, with the aim of helping to shape the future vision of the European Open Science Cloud.

Published

2020

6. Glass polymorphism in amorphous germanium probed by first-principles computer simulations

Author

Mancini, G, primary, Celino, M, additional, Iesari, F, additional, and Di Cicco, A, additional

Published

2015

7. Crystal-Like Rearrangements of Icosahedra in Simulated Copper-Zirconium Metallic Glasses and their Effect on Mechanical Properties

Author

Zemp, J., primary, Celino, M., additional, Schönfeld, B., additional, and Löffler, J. F., additional

Published

2015

8. Tuning the Electronic Properties of Graphane via Hydroxylation: An Ab Initio Study

Author

Francesco Buonocore, Olivia Pulci, Nicola Lisi, Massimo Celino, Andrea Capasso, Buonocore, F., Capasso, A., Celino, M., Lisi, N., and Pulci, O.

Subjects

Materials science, Band gap, Ab initio, 02 engineering and technology, 01 natural sciences, 7. Clean energy, Article, chemistry.chemical_compound, Ab initio quantum chemistry methods, Electron affinity, 0103 physical sciences, Monolayer, Graphane, Physical and Theoretical Chemistry, 010306 general physics, Settore FIS/03, Heterojunction, 021001 nanoscience & nanotechnology, 3. Good health, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Crystallography, General Energy, chemistry, Density functional theory, 0210 nano-technology

Abstract

The thermodynamic stability of hydroxylated graphane, that is, fully sp3 graphene derivatives coordinated with -H and -OH groups, has been recently demonstrated by ab initio calculations. Within the density functional theory approach, we investigate the electronic property modifications of graphane by progressive hydroxylation, that is, by progressively substituting -H with -OH groups. When 50% of graphane is hydroxylated, the energy bandgap reaches its largest value of 6.68 eV. The electronic affinity of 0.8 eV for graphane can widely change in the 0.28-1.60 eV range depending on the geometric configuration. Hydroxylated graphane has two interfaces with vacuum, hence its electron affinity can be different on each interface with the formation of an intrinsic dipole perpendicular to the monolayer. We envisage the possibility of using hydroxylated graphane allotropes with tunable electronic affinity to serve as interfacial layers in 2D material-based heterojunctions.

Published

2021

9. Ultra-Fast High-Precision Metallic Nanoparticle Synthesis using Laser-Accelerated Protons

Author

Massimo Celino, S. Vallières, M. Scisció, Patrizio Antici, Marianna Barberio, Simone Giusepponi, Barberio, M., Giusepponi, S., Vallieres, S., Sciscio, M., Celino, M., and Antici, P.

Subjects

Materials science, Proton, Dispersity, Nanoparticle, lcsh:Medicine, 02 engineering and technology, 01 natural sciences, Article, law.invention, law, Boiling, 0103 physical sciences, Deposition (phase transition), 010306 general physics, lcsh:Science, Ultrafast lasers, Multidisciplinary, business.industry, lcsh:R, Plasma, 021001 nanoscience & nanotechnology, Laser, Nanocrystal, Optoelectronics, lcsh:Q, 0210 nano-technology, business, Plasma-based accelerators

Abstract

Laser-driven proton acceleration, as produced during the interaction of a high-intensity (I > 1 × 1018 W/cm2), short pulse (

Published

2020

10. Properties and characterization of materials

Author

Salanne, M., Celino, M., Borgis, D., Jeanmairet, G., Walker, A., Aeberhard, U., Giusepponi, S., and Gusso, M.

Subjects

surface systems / generation, geothermal energy

Abstract

Development of characterization methods and tools to address structural, electronic and optical properties of materials from the atomic-scale models. Characterization procedures to assess the reliability of the numerical models. Application of MDFT code to supercapacitor materials screening. Coupling of codes to increase accurateness of the computed properties. Modeling of materials at different lenght scales. Description of applications via continuous models. Model settings to design large scale simulations to address accurately macroscopic properties., H2020

Published

2018

11. Biomembrane solubilization mechanism by Triton X-100: a computational study of the three stage model

Author

Massimo Celino, Mattia Rocco, Antonio De Nicola, Antonio Pizzirusso, Michele Cascella, Andrea Correa, Giuseppe Milano, Toshihiro Kawakatsu, Ying Zhao, G. J. Agur Sevink, Pizzirusso, Antonio, De Nicola, Antonio, Sevink, G. J. Agur, Correa, Andrea, Cascella, Michele, Kawakatsu, Toshihiro, Rocco, Mattia, Zhao, Ying, Celino, Massimo, Milano, Giuseppe, and Celino, M.

Subjects

0301 basic medicine, Physics and Astronomy (all), Physical and Theoretical Chemistry, 010304 chemical physics, Chemistry, Vesicle, Analytical chemistry, General Physics and Astronomy, Biological membrane, Curvature, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Molecular dynamics, 030104 developmental biology, Membrane, 0103 physical sciences, Triton X-100, Biophysics, Partition (number theory), Lipid bilayer

Abstract

The solubilization mechanism of lipid membranes in the presence of Triton X-100 (TX-100) is investigated at molecular resolution using molecular dynamics (MD) simulations. Thanks to the large time and length scales accessible by the hybrid particle-field formulation of the models employed here, the complex process of membrane solubilization has been studied, with the goal of verifying the three stage model reported in the literature. DPPC lipid bilayers and vesicles have been studied at different concentrations of the TX-100 detergent employing coarse grained (CG) models. Systems up to ∼600.000 beads, corresponding to more than 2 millions heavy atoms, have been simulated. Moreover, in order to clarify several experimental pieces of evidence, both slow and fast detergent partition scenarios have been investigated. Flat and curved (vesicles) lipid bilayer surfaces, interacting with TX-100, have been considered to study the curvature effects on the detergent partition rate in the membrane. Shape and conformational changes of mixed DPPC/TX-100 vesicles, as a function of TX-100 content, have also been studied. In particular, high curvature surfaces, corresponding to a higher local TX-100 content, promote a membrane rupture. In flat lipid surfaces, on the time scale simulated the detergent partition is almost absent, following a different pathway of the solubilization membrane mechanism. © 2017 the Owner Societies.

Published

2017

12. Optimization Of Methods

Author

Deutsch, T., Celino, M., Duchemin, I., Salanne, Borgis, D., Walker, U., Aeberhard, U., Giusepponi, S., and Gusso, M.

Subjects

geothermal energy, non technical

Abstract

Optimization of all numerical codes ported in the infrastructure and used for supercapacitors, PV and batteries. The scope of deliverable D3.2 is to report the new advances in the field of materials for energy that comes from the search of new methodologies and models that could be more efficient on the new generation of computer hardware for exascale. In this respect, deliverable D3.2 is a transversal deliverable that report the new advances related to activities described in task T3.2, T3.3 and T3.4., H2020

Published

2017

13. Ab-initio study of hydrogen mobility in the vicinity of MgH2[sbnd]Mg interface: The role of Ti and TiO2

Author

Simone Giusepponi, Massimo Celino, Radojka Vujasin, Nikola Novaković, Jasmina Grbović Novaković, and Celino, M.

Subjects

Materials science, Hydrogen, Interfaces, Ab initio, chemistry.chemical_element, Ionic bonding, Nanotechnology, 02 engineering and technology, Electronic structure, 01 natural sciences, Ab–initio calculation, Condensed Matter::Materials Science, Molecular dynamics, Dopants, Desorption, 0103 physical sciences, Oxidation, Physics::Atomic and Molecular Clusters, Materials Chemistry, 010306 general physics, Dopant, Hydrogen desorption, Hydrogen storage, Ab–initio calculations, ab initio calculations, Mechanical Engineering, Doping, Metals and Alloys, Interface, 021001 nanoscience & nanotechnology, 3. Good health, chemistry, Mechanics of Materials, Chemical physics, 0210 nano-technology

Abstract

Doping of MgH2 with transition metals and their oxides is well-known procedure to improve its hydrogen (de) sorption properties, namely to lower the temperature of desorption and to achieve the kinetics speedup. In order to assess the influence Ti and TiO2 doping has on H mobility and to characterize structurally and electronically observed differences, MgH2-Mg interface doped with both Ti and TiO2 have been studied using ab-initio interface molecular dynamics and bulk calculations. Results suggest different mechanisms of MgH2 structure destabilization. The presence of dopants significantly stabilize MgH2-Mg interface, which is confirmed by work of adhesion computation. Calculated formation energies show that interface system with doped TiO2 is more stable. In terms of H mobility, molecular dynamics simulations confirm that Ti doping is more effective than TiO2 in lowering the desorption temperature. The mobility of hydrogen atoms close to dopant is much higher in the case of Ti than in the case of TiO2. Electronic structure characterization reveals that oxygen atoms with high electron affinity forms more pronounced ionic bonding with Ti and the other neighbor Mg atoms. This in turn cause a shorter Ti-H bonds in first coordination than in the case of Ti doping and further reduction of H atoms mobility. This is in accordance with molecular dynamics predictions. (C) 2016 Elsevier B.V. All rights reserved.

Published

2017

14. Adsorption of Modified Arg, Lys, Asp, and Gln to Dry and Hydrated ZnO Surface: A Density Functional Theory Study

Author

Caterina Arcangeli, Francesco Buonocore, Massimo Celino, Fabrizio Gala, Giuseppe Zollo, Celino, M., Arcangeli, C., and Buonocore, F.

Subjects

Glutamine, Physical and Theoretical Chemistry, Materials Chemistry2506 Metals and Alloys, Surfaces, Coatings and Films, 02 engineering and technology, Molecular Dynamics Simulation, 010402 general chemistry, Arginine, 01 natural sciences, Molecular dynamics, Adsorption, Deprotonation, Ab initio quantum chemistry methods, Computational chemistry, Materials Chemistry, Molecule, chemistry.chemical_classification, Aspartic Acid, Biomolecule, Lysine, Water, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Amino acid, chemistry, Models, Chemical, Density functional theory, Zinc Oxide, 0210 nano-technology

Abstract

The interface of biological molecules with inorganic surfaces has been the subject of several recent studies. Experimentally some amino acids are evidenced to play a critical role in the adhesion and selectivity on oxide surfaces; however, detailed information on how the water molecules on the hydrated surface are able to mediate the adsorption is still missing. Accurate total energy ab initio calculations based on dispersion-corrected density functional theory have been performed to investigate the adsorption of selected amino acids on the hydrated ZnO(101¯0) surface, and the results are presented and discussed in this paper. We have also investigated the role played by water in the determination of the most energetically favorable adsorption configurations of the selected amino acids. We have found that for some amino acids the most energetically favorable configurations involve the deprotonation of the molecule if the water screening is not effective. © 2015 American Chemical Society.

Published

2015

15. Structural, Electronic and Vibrational Properties of B 24 N 24 Nanocapsules: Novel Anodes for Magnesium Batteries.

Author

Corona D, Buonocore F, Bechstedt F, Celino M, and Pulci O

Abstract

We report on DFT-TDDFT studies of the structural, electronic and vibrational properties of B24N24 nanocapsules and the effect of encapsulation of homonuclear diatomic halogens (Cl2, Br2 and I2) and chalcogens (S2 and Se2) on the interaction of the B24N24 nanocapsules with the divalent magnesium cation. In particular, to foretell whether these BN nanostructures could be proper negative electrodes for magnesium-ion batteries, the structural, vibrational and electronic properties, as well as the interaction energy and the cell voltage, which is important for applications, have been computed for each system, highlighting their differences and similarities. The encapsulation of halogen and chalcogen diatomic molecules increases the cell voltage, with an effect enhanced down groups 16 and 17 of the periodic table, leading to better performing anodes and fulfilling a remarkable cell voltage of 3.61 V for the iodine-encapsulated system.

Published

2024

16. The chimera of 2D- and 1D-graphene magnetization by hydrogenation or fluorination: critically revisiting old schemes and proposing new ones by ab initio methods.

Author

Albino A, Buonocore F, Celino M, and Totti F

Abstract

Graphene is an ideal candidate material for spintronics due to its layered structure and peculiar electronic structure. However, in its pristine state, the production of magnetic moments is not trivial. A very appealing approach is the chemical modification of pristine graphene. The main obstacle is the control of the geometrical features and the selectivity of functional groups. The lack of a periodic functionalization pattern of the graphene sheet prevents, therefore, the achievement of long-range magnetic order, thus limiting its use in spintronic devices. In such regards, the stability and the magnitude of the instilled magnetic moment depending on the size and shape of in silico designed graphane islands and ribbons embedded in graphene matrix will be computed and analysed. Our findings thus suggest that a novel and magneto-active graphene derivative nanostructure could become achievable more easily than extended graphone or nanoribbons, with a strong potential for future spintronics applications with a variable spin-current density., Competing Interests: There are no conflicts to declare., (This journal is © The Royal Society of Chemistry.)

Published

2024

17. Ab Initio Study of Octane Moiety Adsorption on H- and Cl-Functionalized Silicon Nanowires.

Author

Ferrucci B, Buonocore F, Giusepponi S, Shalabny A, Bashouti MY, and Celino M

Abstract

Using first-principles calculations based on density functional theory, we investigated the effects of surface functionalization on the energetic and electronic properties of hydrogenated and chlorinated silicon nanowires oriented along the <112> direction. We show that the band structure is strongly influenced by the diameter of the nanowire, while substantial variations in the formation energy are observed by changing the passivation species. We modeled an octane moiety absorption on the (111) and (110) surface of the silicon nanowire to address the effects on the electronic structure of the chlorinated and hydrogenated systems. We found that the moiety does not substantially affect the electronic properties of the investigated systems. Indeed, the states localized on the molecules are embedded into the valence and conduction bands, with no generation of intragap energy levels and moderated change in the band gap. Therefore, Si-C bonds can enhance protection of the hydrogenated and chlorinated nanowire surfaces against oxidation without substantial modification of the electronic properties. However, we calculated a significant charge transfer from the silicon nanowires to the octane moiety.

Published

2022

18. Current state and call for action to accomplish findability, accessibility, interoperability, and reusability of low carbon energy data.

Author

Schwanitz VJ, Wierling A, Biresselioglu ME, Celino M, Demir MH, Bałazińska M, Kruczek M, Paier M, and Suna D

Subjects

Databases, Factual, Humans, Carbon, Data Management

Abstract

With the continued digitization of the energy sector, the problem of sunken scholarly data investments and forgone opportunities of harvesting existing data is exacerbating. It compounds the problem that the reproduction of knowledge is incomplete, impeding the transparency of science-based targets for the choices made in the energy transition. The FAIR data guiding principles are widely acknowledged as a way forward, but their operationalization is yet to be agreed upon within different research domains. We comprehensively test FAIR data practices in the low carbon energy research domain. 80 databases representative for data needed to support the low carbon energy transition are screened. Automated and manual tests are used to document the state-of-the art and provide insights on bottlenecks from the human and machine perspectives. We propose action items for overcoming the problem with FAIR energy data and suggest how to prioritize activities., (© 2022. The Author(s).)

Published

2022

19. Semiconductivity Transition in Silicon Nanowires by Hole Transport Layer.

Author

Shalabny A, Buonocore F, Celino M, Shalev G, Zhang L, Wu W, Li P, Arbiol J, and Bashouti MY

Abstract

The surface of nanowires is a source of interest mainly for electrical prospects. Thus, different surface chemical treatments were carried out to develop recipes to control the surface effect. In this work, we succeed in shifting and tuning the semiconductivity of a Si nanowire-based device from n- to p-type. This was accomplished by generating a hole transport layer at the surface by using an electrochemical reaction-based nonequilibrium position to enhance the impact of the surface charge transfer. This was completed by applying different annealing pulses at low temperature (below 400 °C) to reserve the hydrogen bonds at the surface. After each annealing pulse, the surface was characterized by XPS, Kelvin probe measurements, and conductivity measured by FET based on a single Si NW. The mechanism and conclusion were supported experimentally and theoretically. To this end, this strategy has been demonstrated as an essential tool which could pave a new road for regulating semiconductivity and for other low-dimensional nanomaterials.

Published

2020

20. Biomembrane solubilization mechanism by Triton X-100: a computational study of the three stage model.

Author

Pizzirusso A, De Nicola A, Sevink GJA, Correa A, Cascella M, Kawakatsu T, Rocco M, Zhao Y, Celino M, and Milano G

Abstract

The solubilization mechanism of lipid membranes in the presence of Triton X-100 (TX-100) is investigated at molecular resolution using molecular dynamics (MD) simulations. Thanks to the large time and length scales accessible by the hybrid particle-field formulation of the models employed here, the complex process of membrane solubilization has been studied, with the goal of verifying the three stage model reported in the literature. DPPC lipid bilayers and vesicles have been studied at different concentrations of the TX-100 detergent employing coarse grained (CG) models. Systems up to ∼600.000 beads, corresponding to more than 2 millions heavy atoms, have been simulated. Moreover, in order to clarify several experimental pieces of evidence, both slow and fast detergent partition scenarios have been investigated. Flat and curved (vesicles) lipid bilayer surfaces, interacting with TX-100, have been considered to study the curvature effects on the detergent partition rate in the membrane. Shape and conformational changes of mixed DPPC/TX-100 vesicles, as a function of TX-100 content, have also been studied. In particular, high curvature surfaces, corresponding to a higher local TX-100 content, promote a membrane rupture. In flat lipid surfaces, on the time scale simulated the detergent partition is almost absent, following a different pathway of the solubilization membrane mechanism.

Published

2017

21. Glass polymorphism in amorphous germanium probed by first-principles computer simulations.

Author

Mancini G, Celino M, Iesari F, and Di Cicco A

Abstract

The low-density (LDA) to high-density (HDA) transformation in amorphous Ge at high pressure is studied by first-principles molecular dynamics simulations in the framework of density functional theory. Previous experiments are accurately reproduced, including the presence of a well-defined LDA-HDA transition above 8 GPa. The LDA-HDA density increase is found to be about 14%. Pair and bond-angle distributions are obtained in the 0-16 GPa pressure range and allowed us a detailed analysis of the transition. The local fourfold coordination is transformed in an average HDA sixfold coordination associated with different local geometries as confirmed by coordination number analysis and shape of the bond-angle distributions.

Published

2016

22. Self-assembly of triton X-100 in water solutions: a multiscale simulation study linking mesoscale to atomistic models.

Author

De Nicola A, Kawakatsu T, Rosano C, Celino M, Rocco M, and Milano G

Subjects

Micelles, Molecular Dynamics Simulation, Solutions, Models, Chemical, Octoxynol chemistry, Water chemistry

Abstract

A multiscale scheme is proposed and validated for Triton X-100 (TX-100), which is a detergent widely employed in biology. The hybrid particle field formulation of the model allows simulations of large-scale systems. The coarse-grained (CG) model, accurately validated in a wide range of concentrations, shows a critical micelle concentration, shape transition in isotropic micellar phase, and appearance of hexagonal ordered phase in the experimental ranges reported in the literature. The fine resolution of the proposed CG model allows one to obtain, by a suitable reverse mapping procedure, atomistic models of micellar assemblies and of the hexagonal phase. In particular, atomistic models of the micelles give structures in good agreement with experimental pair distance distribution functions and hydrodynamic measurements. The picture emerging by detailed analysis of simulated systems is quite complex. Polydisperse mixtures of spherical-, oblate-, and prolate-shaped aggregates have been found. The shape and the micelle behavior are mainly dictated by the aggregation number (Nagg). Micelles with low Nagg values (∼40) are spherical, while those with high Nagg values (∼140 or larger) are characterized by prolate ellipsoidal shapes. For intermediate Nagg values (∼70), fluxional micelles alternating between oblate and prolate shapes are found. The proposed model opens the way to investigations of several mechanisms involving TX-100 assembly in protein and membrane biophysics.

Published

2015

23. Adsorption of Modified Arg, Lys, Asp, and Gln to Dry and Hydrated ZnO Surface: A Density Functional Theory Study.

Author

Buonocore F, Arcangeli C, Gala F, Zollo G, and Celino M

Subjects

Adsorption, Models, Chemical, Molecular Dynamics Simulation, Arginine chemistry, Aspartic Acid chemistry, Glutamine chemistry, Lysine chemistry, Water chemistry, Zinc Oxide chemistry

Abstract

The interface of biological molecules with inorganic surfaces has been the subject of several recent studies. Experimentally some amino acids are evidenced to play a critical role in the adhesion and selectivity on oxide surfaces; however, detailed information on how the water molecules on the hydrated surface are able to mediate the adsorption is still missing. Accurate total energy ab initio calculations based on dispersion-corrected density functional theory have been performed to investigate the adsorption of selected amino acids on the hydrated ZnO(101̅0) surface, and the results are presented and discussed in this paper. We have also investigated the role played by water in the determination of the most energetically favorable adsorption configurations of the selected amino acids. We have found that for some amino acids the most energetically favorable configurations involve the deprotonation of the molecule if the water screening is not effective.

Published

2015