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2. Hydrogenation of graphene on Ni(111) by H2 under near ambient pressure conditions

Author

Carraro, G, Atakoohi, S, Perilli, D, Alayan, O, Bracco, G, Garbarino, G, Leidinger, P, Novotny, Z, Rocca, M, Savio, L, Smerieri, M, Di Valentin, C, Vattuone, L, Carraro, Giovanni, Atakoohi, Sina Ebrahim, Perilli, Daniele, Alayan, Ola, Bracco, Gianangelo, Garbarino, Gabriella, Leidinger, Paul M., Novotny, Zbynek, Rocca, Mario, Savio, Letizia, Smerieri, Marco, Di Valentin, Cristiana, Vattuone, Luca, Carraro, G, Atakoohi, S, Perilli, D, Alayan, O, Bracco, G, Garbarino, G, Leidinger, P, Novotny, Z, Rocca, M, Savio, L, Smerieri, M, Di Valentin, C, Vattuone, L, Carraro, Giovanni, Atakoohi, Sina Ebrahim, Perilli, Daniele, Alayan, Ola, Bracco, Gianangelo, Garbarino, Gabriella, Leidinger, Paul M., Novotny, Zbynek, Rocca, Mario, Savio, Letizia, Smerieri, Marco, Di Valentin, Cristiana, and Vattuone, Luca

Abstract

Graphene hydrogenation on Ni(111) in the mbar region has been investigated by combining Near Ambient Pressure X-ray Photoemission Spectroscopy and Density Functional Theory calculations. A complete and nearly perfect graphene single layer and an incomplete defective monolayer were exposed to a methanation mixture (H2 + CO and H2 + CO2, respectively) with a large excess of H2. The observed behavior is quite different for the two systems. In the former case, the C 1s spectrum of the initially strongly interacting graphene shows the appearance of new components corresponding to hydrogenated C atoms and their first nearest neighbors. The defective carbon layer, grown in the presence of sulfur contamination and consisting of a mixture of strongly and weakly interacting graphene with a significant amount of dissolved C, initially shows the same C species and then evolves with the formation of sp3 carbon and patches of Ni oxide/hydroxide. NiO forms by CO2 dissociation, while sp3 carbon is indicative of a rumpling of the graphene adlayer induced by hydrogenation. Both species disappear when annealing in H2. Dissociation of H2 and graphene hydrogenation is possible thanks to the presence of the Ni substrate which makes the reaction weakly exothermic and significantly reduces the barrier for H2 dissociation.

Published
2024

3. A novel synthesis route with large-scale sublattice asymmetry in boron doped graphene on Ni(111)

Author

Patil, S, Perilli, D, Panighel, M, Baby, A, Cepek, C, Comelli, G, Di Valentin, C, Africh, C, Patil, Sumati, Perilli, Daniele, Panighel, Mirco, Baby, Anu, Cepek, Cinzia, Comelli, Giovanni, Di Valentin, Cristiana, Africh, Cristina, Patil, S, Perilli, D, Panighel, M, Baby, A, Cepek, C, Comelli, G, Di Valentin, C, Africh, C, Patil, Sumati, Perilli, Daniele, Panighel, Mirco, Baby, Anu, Cepek, Cinzia, Comelli, Giovanni, Di Valentin, Cristiana, and Africh, Cristina

Abstract

One of the promising ways to functionalize graphene is incorporation of heteroatoms in carbon sp2 lattice, as it is proven to be an efficient and versatile method for controllably tuning chemistry of graphene. We present unique, contamination-free method for selectively doping graphene with B dopants, which are incorporated in layer from a reservoir created in the bulk of Ni(111) single crystal, during standard CVD growth process, leading to clean, versatile and efficient method for creating B-doped graphene. We combine experimental (STM, XPS) and theoretical (DFT, simulated STM) studies to understand structural and chemical properties of substitutional B dopants. Along with previously reported substitutional B in fcc sites, we have observed, for the first time, two more defects, namely substitutional B in top sites and interstitial B in octahedral subsurface sites. Extensive STM investigations confirm presence of low and high concentration regions of B dopants in as-prepared B-doped graphene, indicating non-uniform boron incorporation. Among two substitutional sites, no preference is observed in low-concentration B-doped regions, whereas in high B concentration regions, one of the sublattices is preferred for incorporation, along with alignment of defects. This generates an asymmetric sublattice doping in as-grown B-doped graphene, which is theoretically predicted to result in notable band gap.

Published
2024

6. Light-Induced Transformation of Virus-Like Particles on TiO2

Author

Kohantorabi, M, Ugolotti, A, Sochor, B, Roessler, J, Wagstaffe, M, Meinhardt, A, Beck, E, Dolling, D, Garcia, M, Creutzburg, M, Keller, T, Schwartzkopf, M, Vayalil, S, Thuenauer, R, Guédez, G, Löw, C, Ebert, G, Protzer, U, Hammerschmidt, W, Zeidler, R, Roth, S, Di Valentin, C, Stierle, A, Noei, H, Kohantorabi, Mona, Ugolotti, Aldo, Sochor, Benedikt, Roessler, Johannes, Wagstaffe, Michael, Meinhardt, Alexander, Beck, E. Erik, Dolling, Daniel Silvan, Garcia, Miguel Blanco, Creutzburg, Marcus, Keller, Thomas F., Schwartzkopf, Matthias, Vayalil, Sarathlal Koyiloth, Thuenauer, Roland, Guédez, Gabriela, Löw, Christian, Ebert, Gregor, Protzer, Ulrike, Hammerschmidt, Wolfgang, Zeidler, Reinhard, Roth, Stephan V., Di Valentin, Cristiana, Stierle, Andreas, Noei, Heshmat, Kohantorabi, M, Ugolotti, A, Sochor, B, Roessler, J, Wagstaffe, M, Meinhardt, A, Beck, E, Dolling, D, Garcia, M, Creutzburg, M, Keller, T, Schwartzkopf, M, Vayalil, S, Thuenauer, R, Guédez, G, Löw, C, Ebert, G, Protzer, U, Hammerschmidt, W, Zeidler, R, Roth, S, Di Valentin, C, Stierle, A, Noei, H, Kohantorabi, Mona, Ugolotti, Aldo, Sochor, Benedikt, Roessler, Johannes, Wagstaffe, Michael, Meinhardt, Alexander, Beck, E. Erik, Dolling, Daniel Silvan, Garcia, Miguel Blanco, Creutzburg, Marcus, Keller, Thomas F., Schwartzkopf, Matthias, Vayalil, Sarathlal Koyiloth, Thuenauer, Roland, Guédez, Gabriela, Löw, Christian, Ebert, Gregor, Protzer, Ulrike, Hammerschmidt, Wolfgang, Zeidler, Reinhard, Roth, Stephan V., Di Valentin, Cristiana, Stierle, Andreas, and Noei, Heshmat

Abstract

Titanium dioxide (TiO2) shows significant potential as a self-cleaning material to inactivate severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and prevent virus transmission. This study provides insights into the impact of UV-A light on the photocatalytic inactivation of adsorbed SARS-CoV-2 virus-like particles (VLPs) on a TiO2 surface at the molecular and atomic levels. X-ray photoelectron spectroscopy, combined with density functional theory calculations, reveals that spike proteins can adsorb on TiO2 predominantly via their amine and amide functional groups in their amino acids blocks. We employ atomic force microscopy and grazing-incidence small-angle X-ray scattering (GISAXS) to investigate the molecular-scale morphological changes during the inactivation of VLPs on TiO2 under light irradiation. Notably, in situ measurements reveal photoinduced morphological changes of VLPs, resulting in increased particle diameters. These results suggest that the denaturation of structural proteins induced by UV irradiation and oxidation of the virus structure through photocatalytic reactions can take place on the TiO2 surface. The in situ GISAXS measurements under an N-2 atmosphere reveal that the virus morphology remains intact under UV light. This provides evidence that the presence of both oxygen and UV light is necessary to initiate photocatalytic reactions on the surface and subsequently inactivate the adsorbed viruses. The chemical insights into the virus inactivation process obtained in this study contribute significantly to the development of solid materials for the inactivation of enveloped viruses.

Published
2024

7. Vitamin C Affinity to TiO2 Nanotubes: A Computational Study by Hybrid Density Functional Theory Calculations

Author

Ugolotti, A, Dolce, M, Di Valentin, C, Ugolotti, A, Dolce, M, and Di Valentin, C

Abstract

Titanium dioxide nanotubes (TNT) have been extensively studied because of their unique properties, which make such systems ideal candidates for biomedical application, especially for the targeted release of drugs. However, knowledge about the properties of TiO2 nanotubes with typical dimensions of the order of the nanometer is limited, especially concerning the adsorption of molecules that can be potentially loaded in actual devices. In this work, we investigate, by means of simulations based on hybrid density functional theory, the adsorption of Vitamin C molecules on different nanotubes through a comparative analysis of the properties of different structures. We consider two different anatase TiO2 surfaces, the most stable (101) and the more reactive (001)A; we evaluate the role of the curvature, the thickness and of the diameter as well as of the rolling direction of the nanotube. Different orientations of the molecule with respect to the surface are studied in order to identify any trends in the adsorption mechanism. Our results show that there is no preferential functional group of the molecule interacting with the substrate, nor any definite spatial dependency, like a rolling orientation or the concavity of the nanotube. Instead, the adsorption is driven by geometrical factors only, i.e., the favorable matching of the position and the alignment of any functional groups with undercoordinated Ti atoms of the surface, through the interplay between chemical and hydrogen bonds. Differently from flat slabs, thicker nanotubes do not improve the stability of the adsorption, but rather develop weaker interactions, due to the enhanced curvature of the substrate layers.

Published
2024

8. Functionalizing TiO2 Nanoparticles with Fluorescent Cyanine Dye for Photodynamic Therapy and Bioimaging: A DFT and TDDFT Study

Author

Daldossi, C, Perilli, D, Ferraro, L, Di Valentin, C, Daldossi, C, Perilli, D, Ferraro, L, and Di Valentin, C

Abstract

In the field of nanomedicine, significant attention is directed toward near-infrared (NIR) light-responsive inorganic nanosystems, primarily for their applications in photodynamic therapy and fluorescence bioimaging. The crucial role of the NIR range lies in enabling optimal tissue penetration, which is essential for both irradiating and detecting nanoparticles deep within the human body. In this study, we employed density functional theory (DFT) and time-dependent DFT (TDDFT) calculations to explore the structural and electronic properties of cyanine-functionalized TiO2 spherical nanoparticles (NPs) with a realistic diameter of 2.2 nm. We revealed that different adsorption configurations of cyanine (VG20-C1) on the TiO2 NP surface exhibit distinct features in the optical spectra. These cyanine dyes, serving as bifunctional linkers with two carboxylic end groups, can adsorb in either a side-on mode (binding with both end groups) or an end-on mode (binding only one end group). In end-on adsorption structures, low-energy excitations are exclusive to dye-to-dye electronic transitions, while side-on structures exhibit electron charge transfer excitations from the dye to the TiO2 NP at low energy. This thorough analysis provides a rational foundation for designing cyanine-functionalized TiO2 nanosystems with optimal optical characteristics tailored for specific nanomedical applications such as photodynamic therapy or fluorescence bioimaging.

Published
2024

9. Insights into the active nickel centers embedded in graphitic carbon nitride for the oxygen evolution reaction

Author

Rossetti, N, Ugolotti, A, Cometto, C, Celorrio, V, Drazic, G, Di Valentin, C, Calvillo, L, Rossetti, N, Ugolotti, A, Cometto, C, Celorrio, V, Drazic, G, Di Valentin, C, and Calvillo, L

Abstract

Experimental and theoretical studies have demonstrated that the use of single atom catalysts (SACs) for energy conversion processes is very promising. However, their stability under catalytic conditions is the main issue that hinders their commercial use. In this work, we report an oxygen evolution catalyst based on single nickel atoms stabilized in triazine-based carbon nitride (CN) and a detailed study of the evolution of the Ni centers under catalytic conditions. The nanostructured materials have been characterized by combining experimental techniques, such as X-ray diffraction, transmission electron microscopy, X-ray absorption and X-ray photoemission spectroscopy, with DFT theoretical calculations to determine the CN structure, the metal adsorption sites, the coordination of the Ni atoms, and the changes undergone under catalytic conditions. Electrochemical characterization showed a linear increase of the catalytic activity with Ni loading. The stability of the materials was studied by HR-TEM and XAS post-catalysis measurements and DFT simulations. Results indicated a partial chemical restructuring of the single Ni atoms under catalytic conditions with the formation of Ni-O-Ni moieties, stabilized in the CN cavities, which are the real catalytic species.

Published
2024

10. The effect of polymer coating on nanoparticles’ interaction with lipid membranes studied by coarse-grained molecular dynamics simulations

Author

Donadoni, E, Siani, P, Frigerio, G, Milani, C, Cui, Q, Di Valentin, C, Donadoni, Edoardo, Siani, Paulo, Frigerio, Giulia, Milani, Carolina, Cui, Qiang, Di Valentin, Cristiana, Donadoni, E, Siani, P, Frigerio, G, Milani, C, Cui, Q, Di Valentin, C, Donadoni, Edoardo, Siani, Paulo, Frigerio, Giulia, Milani, Carolina, Cui, Qiang, and Di Valentin, Cristiana

Abstract

Nanoparticles' (NPs) permeation through cell membranes, whether it happens via passive or active transport, is an essential initial step for their cellular internalization. The NPs' surface coating impacts the way they translocate through the lipid bilayer and the spontaneity of the process. Understanding the molecular details of NPs' interaction with cell membranes allows the design of nanosystems with optimal characteristics for crossing the lipid bilayer: computer simulations are a powerful tool for this purpose. In this work, we have performed coarse-grained molecular dynamics simulations and free energy calculations on spherical titanium dioxide NPs conjugated with polymer chains of different chemical compositions. We have demonstrated that the hydrophobic/hydrophilic character of the chains, more than the nature of their terminal group, plays a crucial role in determining the NPs' interaction with the lipid bilayer and the thermodynamic spontaneity of NPs' translocation from water to the membrane. We envision that this computational work will be helpful to the experimental community in terms of the rational design of NPs for efficient cell membrane permeation.By coarse-grained molecular dynamics simulations, we have unveiled that nanoparticles coated with mixed hydrophobic/hydrophilic polymer chains spontaneously penetrate lipid membranes, unlike those covered with chains of hydrophilic character only.

Published
2024

12. Mechanistic Insights from Molecular Dynamics Simulations in Nanomedicine

Author

Siani, P, Frigerio, G, Donadoni, E, DI VALENTIN, C, Paulo Siani, Giulia Frigerio, Edoardo Donadoni, Cristiana Di Valentin, Siani, P, Frigerio, G, Donadoni, E, DI VALENTIN, C, Paulo Siani, Giulia Frigerio, Edoardo Donadoni, and Cristiana Di Valentin

Abstract

Molecular dynamics simulation techniques have been in the spotlight of recent nanomedicine research, becoming an indispensable tool for unveiling complex molecular mechanisms that are sometimes unreachable by experimental methods. Here, we demonstrate how MD simulations can complement existing experimental knowledge or provide new mechanistic insights into relevant aspects of nanoscale devices designed for nanomedicine. Through some case studies - from how thermodynamic variables (e.g., pH and ionic strength) affect the protein corona formation onto organic-functionalized nanoparticles to the impact of lipid composition in the permeation process of anti-tumoral drugs in membranes - this work compilation illustrates how classical MD simulations can be helpful bridging the simulated microscopic behaviors to their corresponding macroscopic manifestation.

Published
2024

13. Mechanistic Insights from Molecular Dynamics Simulations in Nanomedicine Research

Author

Siani, P, Frigerio, G, Donadoni, E, DI VALENTIN, C, Paulo Siani, Giulia Frigerio, Edoardo Donadoni, Cristiana Di Valentin, Siani, P, Frigerio, G, Donadoni, E, DI VALENTIN, C, Paulo Siani, Giulia Frigerio, Edoardo Donadoni, and Cristiana Di Valentin

Abstract

Molecular dynamics simulation techniques have been in the spotlight of recent nanomedicine research, becoming an indispensable tool for unveiling complex molecular mechanisms that are sometimes unreachable by experimental methods. Here, we demonstrate how MD simulations can complement existing experimental knowledge or provide new mechanistic insights into relevant aspects of nanoscale devices designed for nanomedicine. Through some case studies - from how thermodynamic variables (e.g., pH and ionic strength) affect the protein corona formation onto organic-functionalized nanoparticles to the impact of lipid composition in the permeation process of anti-tumoral drugs in membranes - this work compilation illustrates how classical MD simulations can be helpful bridging the simulated microscopic behaviors to their corresponding macroscopic manifestation.

Published
2024

14. Corrigendum to “Well-ordered surface metal atoms complexation by deposition of Pd cyclometallated compounds on Ag (1 1 0)” [Appl. Surf. Sci. 606 (2022) 154960](S0169433222024886)(10.1016/j.apsusc.2022.154960)

Author

Stojkovska M., Stojkovska, M, Perilli, D, Barcelon, J, Smerieri, M, Carraro, G, Dinh, T, Vattuone, L, Rocca, M, Bracco, G, Dell'Angela, M, Costantini, R, Cossaro, A, Vaghi, L, Papagni, A, Di Valentin, C, Savio, L, Stojkovska M., Perilli D., Barcelon J. E., Smerieri M., Carraro G., Dinh T. H., Vattuone L., Rocca M., Bracco G., Dell'Angela M., Costantini R., Cossaro A., Vaghi L., Papagni A., Di Valentin C., Savio L., Stojkovska M., Stojkovska, M, Perilli, D, Barcelon, J, Smerieri, M, Carraro, G, Dinh, T, Vattuone, L, Rocca, M, Bracco, G, Dell'Angela, M, Costantini, R, Cossaro, A, Vaghi, L, Papagni, A, Di Valentin, C, Savio, L, Stojkovska M., Perilli D., Barcelon J. E., Smerieri M., Carraro G., Dinh T. H., Vattuone L., Rocca M., Bracco G., Dell'Angela M., Costantini R., Cossaro A., Vaghi L., Papagni A., Di Valentin C., and Savio L.

Published
2023

15. Chemistry of the Interaction and Retention of TcVII and TcIV Species at the Fe3O4(001) Surface

Author

Bianchetti, E, Oliveira, A, Scheinost, A, Di Valentin, C, Seifert, G, Bianchetti E., Oliveira A. F., Scheinost A. C., Di Valentin C., Seifert G., Bianchetti, E, Oliveira, A, Scheinost, A, Di Valentin, C, Seifert, G, Bianchetti E., Oliveira A. F., Scheinost A. C., Di Valentin C., and Seifert G.

Abstract

The pertechnetate ion TcVIIO4- is a nuclear fission product whose major issue is the high mobility in the environment. Experimentally, it is well known that Fe3O4 can reduce TcVIIO4- to TcIV species and retain such products quickly and completely, but the exact nature of the redox process and products is not completely understood. Therefore, we investigated the chemistry of TcVIIO4- and TcIV species at the Fe3O4(001) surface through a hybrid DFT functional (HSE06) method. We studied a possible initiation step of the TcVII reduction process. The interaction of the TcVIIO4- ion with the magnetite surface leads to the formation of a reduced TcVI species without any change in the Tc coordination sphere through an electron transfer that is favored by the magnetite surfaces with a higher FeII content. Furthermore, we explored various model structures for the immobilized TcIV final products. TcIV can be incorporated into a subsurface octahedral site or adsorbed on the surface in the form of TcIVO2·xH2O chains. We propose and discuss three model structures for the adsorbed TcIVO2·2H2O chains in terms of relative energies and simulated EXAFS spectra. Our results suggest that the periodicity of the Fe3O4(001) surface matches that of the TcO2·2H2O chains. The EXAFS analysis suggests that, in experiments, TcO2·xH2O chains were probably not formed as an inner-shell adsorption complex with the Fe3O4(001) surface.

Published
2023

16. Multi-scale modeling of folic acid-functionalized TiO2 nanoparticles for active targeting of tumor cells

Author

Donadoni, E, Siani, P, Frigerio, G, Di Valentin, C, Donadoni, E., Di Valentin, C., Donadoni, E, Siani, P, Frigerio, G, Di Valentin, C, Donadoni, E., and Di Valentin, C.

Abstract

Strategies based on the active targeting of tumor cells are emerging as smart and efficient nanomedical procedures. Folic acid (FA) is a vitamin and a well-established tumor targeting agent because of its strong affinity for the folate receptor (FR), which is an overexpressed protein on the cell membranes of the tumor cells. FA can be successfully anchored to several nanocarriers, including inorganic nanoparticles (NPs) based on transition metal oxides. Among them, TiO2 is extremely interesting because of its excellent photoabsorption and photocatalytic properties, which can be exploited in photodynamic therapy. However, it is not yet clear in which respects direct anchoring of FA to the NP or the use of spacers, based on polyethylene glycol (PEG) chains, are different and whether one approach is better than the other. In this work, we combine Quantum Mechanics (QM) and classical Molecular Dynamics (MD) to design and optimize the FA functionalization on bare and PEGylated TiO2 models and to study the dynamical behavior of the resulting nanoconjugates in a pure water environment and in physiological conditions. We observe that they are chemically stable, even under the effect of increasing temperature (up to 500 K). Using the results from long MD simulations (100 ns) and from free energy calculations, we determine how the density of FA molecules on the TiO2 NP and the presence of PEG spacers impact on the actual exposure of the ligands, especially by affecting the extent of FA–FA intermolecular interactions, which are detrimental for the targeting ability of FA towards the folate receptor. This analysis provides a solid and rational basis for experimentalists to define the optimal FA density and the more appropriate mode of anchoring to the carrier, according to the final purpose of the nanoconjugate.

Published
2023

17. Mechanism of sustainable photocatalysis based on doped-titanium dioxide nanoparticles for UV to visible light induced PET-RAFT photo-polymerization

Author

Bellotti, V, Daldossi, C, Perilli, D, D'Arienzo, M, Stredansky, M, Di Valentin, C, Simonutti, R, Bellotti V., Daldossi C., Perilli D., D'Arienzo M., Stredansky M., Di Valentin C., Simonutti R., Bellotti, V, Daldossi, C, Perilli, D, D'Arienzo, M, Stredansky, M, Di Valentin, C, Simonutti, R, Bellotti V., Daldossi C., Perilli D., D'Arienzo M., Stredansky M., Di Valentin C., and Simonutti R.

Abstract

Heterogeneous catalysis is an essential aspect for actual industrialization of chemical processes. Here a TiO2-based powder, typically used in photocatalysis, is exploited for the first time for visible-light-regulated Photoinduced Electron/Energy (PET)-reversible addition–fragmentation chain-transfer (RAFT). Titania is a non-toxic, low-cost, and heterogeneous catalyst that can offer several advantages in terms of sustainable polymerization and photocatalyst (PC) recovery. In this work, we aim not only at unraveling the mechanism of photopolymerization and the important interactions involved, but also at red-shifting the absorption region to achieve vis-light polymerization. The combination of the experimental investigation with Density Functional Theory (DFT) calculations provides new insights into the interactions between the chain transfer agents (CTAs) and the TiO2 surface, unveiling their pivotal role on the reaction rate and polymerization control. Moreover, to shift the polymerization under the less energetic blue light, high-surface area N-doped TiO2 nanoparticles are employed, avoiding the CTA degradation often observed with UV irradiation and increasing the overall sustainability of the process.

Published
2023

18. Improving the Oxygen Evolution Reaction on Fe3O4(001) with Single-Atom Catalysts

Author

Bianchetti, E, Perilli, D, Di Valentin, C, Bianchetti E., Perilli D., Di Valentin C., Bianchetti, E, Perilli, D, Di Valentin, C, Bianchetti E., Perilli D., and Di Valentin C.

Abstract

Doping magnetite surfaces with transition-metal atoms is a promising strategy to improve the catalytic performance toward the oxygen evolution reaction (OER), which governs the overall efficiency of water electrolysis and hydrogen production. In this work, we investigated the Fe3O4(001) surface as a support material for single-atom catalysts of the OER. First, we prepared and optimized models of inexpensive and abundant transition-metal atoms, such as Ti, Co, Ni, and Cu, trapped in various configurations on the Fe3O4(001) surface. Then, we studied their structural, electronic, and magnetic properties through HSE06 hybrid functional calculations. As a further step, we investigated the performance of these model electrocatalysts toward the OER, considering different possible mechanisms, in comparison with the pristine magnetite surface, on the basis of the computational hydrogen electrode model developed by Nørskov and co-workers. Cobalt-doped systems were found to be the most promising electrocatalytic systems among those considered in this work. Overpotential values (∼0.35 V) were in the range of those experimentally reported for mixed Co/Fe oxide (0.2-0.5 V).

Published
2023

19. Trends in excitonic, vibrational and polaronic properties of graphitic carbon nitride polymorphs

Author

Ugolotti, A, Di Valentin, C, Ugolotti A., Di Valentin C., Ugolotti, A, Di Valentin, C, Ugolotti A., and Di Valentin C.

Abstract

Although graphitic-carbon nitride (gCN) is a highly investigated inorganic semiconductor, especially in the field of photocatalysis, it is still the object of many controversial discussions. The possibility to easily synthesize a homogeneous heterostructure through the condensation and the polymerization of simple molecules allows the growth of a variety of structures with different electronic and optical properties. With the aim of driving the development of the catalyst toward improved performances or newer applications, it is paramount to understand the optically-driven excitation process within each polymer. In this work, we focus on two models of melem-based gCN, i.e. the fully and the partially polymerized structures, and we perform a computational investigation, based on hybrid density functional theory calculations, of their optical properties in terms of vibrational and electronic excitations. First, we determine the normal modes of the ground state and we interpret the IR absorption spectrum. Then, we simulate the electronic excited state with an electron–hole pair model and we determine the exciton binding energy, the self-trapping energy and the photo-emission energy. We compare these numerical results with the experimental data available in literature and in addition we discuss the role of the different polymeric arrangements.

Published
2023

20. Spatial segregation of substitutional B atoms in graphene patterned by the moiré superlattice on Ir(111)

Author

Cuxart, M, Perilli, D, Tomekce, S, Deyerling, J, Haag, F, Muntwiler, M, Allegretti, F, Di Valentin, C, Auwarter, W, Cuxart M. G., Perilli D., Tomekce S., Deyerling J., Haag F., Muntwiler M., Allegretti F., Di Valentin C., Auwarter W., Cuxart, M, Perilli, D, Tomekce, S, Deyerling, J, Haag, F, Muntwiler, M, Allegretti, F, Di Valentin, C, Auwarter, W, Cuxart M. G., Perilli D., Tomekce S., Deyerling J., Haag F., Muntwiler M., Allegretti F., Di Valentin C., and Auwarter W.

Abstract

Fabrication of ordered structures at the nanoscale limit poses a cornerstone challenge for modern technologies. In this work we show how naturally occurring moiré patterns in Ir(111)-supported graphene template the formation of 2D ordered arrays of substitutional boron species. A complementary experimental and theoretical approach provides a comprehensive description of the boron species distribution, bonding configurations, interfacial interaction with Ir(111) and the impact on graphene's electronic structure. Atomically-resolved scanning tunnelling microscopy images and density functional theory calculations reveal that boron preferably forms small aggregates of substitutional defects in geometrically low regions of the moiré superlattice of graphene, by inducing local bending of graphene towards the underlying Ir(111). Surprisingly, calculations reveal that the incorporation of electron deficient boron does not lead to an enhanced p-type doping, as the local rippling of the graphene layer prompts electron uptake from the iridium substrate that compensates the initial electron loss due to substitutional boron. Scanning tunnelling spectroscopy and angle-resolved photoemission spectroscopy measurements corroborate that the arrays of boron species do not modify the electronic structure of graphene near the Fermi level, hence preserving the slight p-type doping induced by Ir(111).

Published
2023

22. Multi-scale modeling of folic acid-functionalized TiO$_{2}$ nanoparticles for active targeting of tumor cells

Author

Donadoni, E, Siani, P, Frigerio, G, Di Valentin, C, Donadoni E., Siani P., Frigerio G., Di Valentin C., Donadoni, E, Siani, P, Frigerio, G, Di Valentin, C, Donadoni E., Siani P., Frigerio G., and Di Valentin C.

Abstract

Strategies based on the active targeting of tumor cells are emerging as smart and efficient nanomedical procedures. Folic acid (FA) is a vitamin and a well-established tumor targeting agent because of its strong affinity for the folate receptor (FR), which is an overexpressed protein on the cell membranes of the tumor cells. FA can be successfully anchored to several nanocarriers, including inorganic nanoparticles (NPs) based on transition metal oxides. Among them, TiO2 is extremely interesting because of its excellent photoabsorption and photocatalytic properties, which can be exploited in photodynamic therapy. However, it is not yet clear in which respects direct anchoring of FA to the NP or the use of spacers, based on polyethylene glycol (PEG) chains, are different and whether one approach is better than the other. In this work, we combine Quantum Mechanics (QM) and classical Molecular Dynamics (MD) to design and optimize the FA functionalization on bare and PEGylated TiO2 models and to study the dynamical behavior of the resulting nanoconjugates in a pure water environment and in physiological conditions. We observe that they are chemically stable, even under the effect of increasing temperature (up to 500 K). Using the results from long MD simulations (100 ns) and from free energy calculations, we determine how the density of FA molecules on the TiO2 NP and the presence of PEG spacers impact on the actual exposure of the ligands, especially by affecting the extent of FA-FA intermolecular interactions, which are detrimental for the targeting ability of FA towards the folate receptor. This analysis provides a solid and rational basis for experimentalists to define the optimal FA density and the more appropriate mode of anchoring to the carrier, according to the final purpose of the nanoconjugate.

Published
2022

23. Binding group of oligonucleotides on TiO2 surfaces: Phosphate anions or nucleobases?

Author

Soria, F, Di Valentin, C, Soria F. A., Di Valentin C., Soria, F, Di Valentin, C, Soria F. A., and Di Valentin C.

Abstract

Although the immobilization of oligonucleotides (nucleic acid) on mineral surfaces is at the basis of different biotechnological applications, an atomistic understanding of the interaction of the nucleic acid components with the titanium dioxide surfaces has not yet been achieved. Here, the adsorption of the phosphate anion, of the four DNA bases (adenine, guanine, thymine, and cytosine) and of some entire nucleotides and dinucleotides on the TiO2 anatase (1 0 1) surface is studied through dispersion-corrected hybrid density functional theory (DFT) calculations. Several adsorption configurations are identified for the separated entities (phosphate anion or base) and then considered when studying the adsorption of the entire nucleotides. The analysis shows that both the phosphate anion and each base may anchor the nucleotides to the surface in a collaborative and synergistic adsorption mode. The tendency is that the nucleotides containing the guanine base present the strongest adsorption while those made up with the thymine base have the lowest adsorption energies. Nucleotides based on adenine and cytosine have a similar intermediate behavior. Finally, we investigated the adsorption of competing water molecules to understand whether in the presence of the aqueous solvent, the nucleotides would remain bonded to the surface or desorb.

Published
2022

24. Molecular dynamics simulations of doxorubicin in phospholipid membranes

Author

Donadoni, E, Siani, P, Di Valentin, C, Donadoni, E., SIani, P., Di Valentin, C., Donadoni, E, Siani, P, Di Valentin, C, Donadoni, E., SIani, P., and Di Valentin, C.

Abstract

Doxorubicin (DOX) is one of the most efficient antitumor drugs employed in numerous cancer therapies. Its incorporation into lipid-based nanocarriers, such as liposomes, improves the drug targeting into tumor cells and reduces drug side effects. The carriers' lipid composition is expected to affect the interactions of DOX and its partitioning into liposomal membranes. To get a rational insight into this aspect and determine promising lipid compositions, we use numerical simulations, which provide unique information on DOX- membrane interactions at the atomic level of resolution. In particular, we combine classical molecular dynamics simulations and free energy calculations to elucidate the mechanism of penetration of a protonated Doxorubicin molecule (DOX+) into potential liposome membranes, here modeled as lipid bilayers based on mixtures of phosphatidylcholine (PC), sphingomyelin (SM) and cholesterol lipid molecules, of different compositions and lipid phases. Moreover, we analyze DOX+ partitioning into relevant regions of SM-based lipid bilayer systems using a combination of free energy methods. Our results show that DOX+ penetration and partitioning are facilitated into less tightly packed SM-based membranes and are dependent on lipid composition. This work paves the way to further investigations of optimal formulations for lipid-based carriers, such as those associated with pH-responsive membranes.

Published
2022

25. Mechanism of spin ordering in Fe3O4 nanoparticles by surface coating with organic acids

Author

Bianchetti, E, Di Valentin, C, Bianchetti E., Di Valentin C., Bianchetti, E, Di Valentin, C, Bianchetti E., and Di Valentin C.

Abstract

Saturation magnetization values close to the bulk have been reported for coated magnetite nanoparticles with organic acids. The mechanism of this effect is not yet understood. Here, we show that a previously proposed rationalization in Nano Letters 12 (2021) 2499–2503 was based on electronic structure properties that are not consistent with several existing density functional theory studies. Our study is based on a wide set of Hubbard-corrected density-functional tight-binding (DTFB + U) and hybrid density functional theory (HSE06) calculations on Fe3O4 nanocubes of more than 400 atoms. We provide a new explanation for the spin ordering in coated nanoparticles, through the investigation of spin-flipping phenomena. In particular, we show that the spin-flip of d electrons at octahedral Fe3+ sites, which is confirmed to be more favorable near the surface, especially where atomic reorganization can take place such as at corner sites, can be hampered by the presence of adsorbed organic acids because they do not only limit the surface reconstruction but also allow for additional ferromagnetic superexchange interaction between octahedral Fe sites as a consequence of the carboxylates bridging binding mode. The proof-of-concept of this mechanism is given by a simplified model of the Fe(III) tert-butoxide dimer.

Published
2022

26. Effect of dopamine-functionalization, charge and pH on protein corona formation around TiO2 nanoparticles

Author

Siani, P, Di Valentin, C, Siani P., Di Valentin C., Siani, P, Di Valentin, C, Siani P., and Di Valentin C.

Abstract

Inorganic nanoparticles (NPs) are gaining increasing attention in nanomedicine because of their stimuli responsiveness, which allows combining therapy with diagnosis. However, little information is known about their interaction with intracellular or plasma proteins when they are introduced in a biological environment. Here we present atomistic molecular dynamics (MD) simulations investigating the case study of dopamine-functionalized TiO2 nanoparticles and two proteins that are overexpressed in cancer cells, i.e. PARP1 and HSP90, since experiments proved them to be the main components of the corona in cell cultures. The mechanism and the nature of the interaction (electrostatic, van der Waals, H-bonds, etc.) is unravelled by defining the protein residues that are more frequently in contact with the NPs, the extent of contact surface area and the variations in the protein secondary structures, at different pH and ionic strength conditions of the solution where they are immersed to simulate a realistic biological environment. The effects of the NP surface functionalization and charge are also considered. Our MD results suggest that less acidic intracellular pH conditions in the presence of cytosolic ionic strength enhance PARP1 interaction with the nanoparticle, whereas the HSP90 contribution is partly weakened, providing a rational explanation to existing experimental observations.

Published
2022

27. Molecular Dynamics for the Optimal Design of Functionalized Nanodevices to Target Folate Receptors on Tumor Cells

Author

Donadoni, E, Frigerio, G, Siani, P, Motta, S, Vertemara, J, De Gioia, L, Bonati, L, Di Valentin, C, Donadoni, Edoardo, Frigerio, Giulia, Siani, Paulo, Motta, Stefano, Vertemara, Jacopo, De Gioia, Luca, Bonati, Laura, Di Valentin, Cristiana, Donadoni, E, Frigerio, G, Siani, P, Motta, S, Vertemara, J, De Gioia, L, Bonati, L, Di Valentin, C, Donadoni, Edoardo, Frigerio, Giulia, Siani, Paulo, Motta, Stefano, Vertemara, Jacopo, De Gioia, Luca, Bonati, Laura, and Di Valentin, Cristiana

Published
2023

30. Formation of diphenyl-bipyridine units by surface assisted cross coupling in Pd-cyclometalled complexes

Author

Eduardo Barcelon, J, Stojkovska, M, Perilli, D, Carraro, G, Smerieri, M, Vattuone, L, Rocca, M, Bracco, G, Dell'Angela, M, Costantini, R, Cossaro, A, Vaghi, L, Papagni, A, DI VALENTIN, C, Savio, L, Jose Eduardo Barcelon, Marija Stojkovska, Daniele Perilli, Giovanni Carraro, Marco Smerieri, Luca Vattuone, Mario Rocca, Gianangelo Bracco, Martina Dell'Angela, Roberto Costantini, Albano Cossaro, Luca Vaghi, Antonio Papagni, Cristiana Di Valentin, Letizia Savio, Eduardo Barcelon, J, Stojkovska, M, Perilli, D, Carraro, G, Smerieri, M, Vattuone, L, Rocca, M, Bracco, G, Dell'Angela, M, Costantini, R, Cossaro, A, Vaghi, L, Papagni, A, DI VALENTIN, C, Savio, L, Jose Eduardo Barcelon, Marija Stojkovska, Daniele Perilli, Giovanni Carraro, Marco Smerieri, Luca Vattuone, Mario Rocca, Gianangelo Bracco, Martina Dell'Angela, Roberto Costantini, Albano Cossaro, Luca Vaghi, Antonio Papagni, Cristiana Di Valentin, and Letizia Savio

Published
2023

31. Chemistry of the interaction and retention of TcVII and TcIV species at the Fe3O4(001) surface

Author

Bianchetti, E., (0000-0002-0805-3081) Faria Oliveira, A., (0000-0002-6608-5428) Scheinost, A., Di Valentin, C., Seifert, G., Bianchetti, E., (0000-0002-0805-3081) Faria Oliveira, A., (0000-0002-6608-5428) Scheinost, A., Di Valentin, C., and Seifert, G.

Abstract

The pertechnetate ion TcVIIO4− is a nuclear fission product whose major issue is the high mobility in the environment. Experimentally, it is well-known that Fe3O4 can reduce TcVIIO4− to TcIV species and retain such products quickly and completely, but the exact nature of the redox process and products is not completely understood. Therefore, we investigated the chemistry of TcVIIO4− and TcIV species at the Fe3O4(001) surface through a hybrid DFT functional (HSE06) method. We studied a possible initiation step of the TcVII reduction process. The interaction of the TcVIIO4− ion with magnetite surface leads to the formation of a reduced TcVI species without any change in the Tc coordination sphere, through an electron transfer that is favored by the magnetite surfaces with a higher FeII content. Furthermore, we explored various model structures for the immobilized TcIV final products. TcIV can be incorporated into a subsurface octahedral site or adsorbed on the surface in the form of TcIVO2·xH2O chains. We propose and discuss three model structures for the adsorbed TcIVO2·2H2O chains in terms of relative energies and simulated EXAFS spectra. Our results suggest that the periodicity of the Fe3O4(001) surface matches that of the TcO2·2H2O chains. The EXAFS analysis suggests that in experiments TcO2·xH2O chains were probably not formed as an inner-shell adsorption complex with the Fe3O4(001) surface.

Published
2023

32. Modeling Zeta Potential for Nanoparticles in Solution: Water Flexibility Matters

Author

Siani, P, Frigerio, G, Donadoni, E, Di Valentin, C, Siani, Paulo, Frigerio, Giulia, Donadoni, Edoardo, Di Valentin, Cristiana, Siani, P, Frigerio, G, Donadoni, E, Di Valentin, C, Siani, Paulo, Frigerio, Giulia, Donadoni, Edoardo, and Di Valentin, Cristiana

Abstract

Nonequilibrium molecular dynamics simulations were performed to study the electrokinetic properties of five mainstream TIPxP water models (namely, TIP3P-FB, TIP3Pm, TIP4P-FB, TIP4P-Ew, and TIP4P/2005) in NaCl aqueous solutions in the presence of a negatively charged TiO2 surface. The impact of solvent flexibility and system geometry on the electro-osmotic (EO) mobility and flow direction was systematically assessed and compared. We found that lack of water flexibility decelerates the forward EO flow of aqueous solutions at moderate (0.15 M) or high (0.30 M) NaCl concentrations, in some special cases to such an extent that EO flow reversal occurs. Zeta potential (ZP) values were then determined from the bulk EO mobilities using the Helmholtz-Smoluchowski formula. The straight comparison against available experimental data strongly suggests that water flexibility improves the ZP determination of NaCl solutions adjacent to a realistic TiO2 surface under neutral pH conditions.

Published
2023

33. Metadynamics simulations for the investigation of drug loading on functionalized inorganic nanoparticles

Author

Motta, S, Siani, P, Donadoni, E, Frigerio, G, Bonati, L, Di Valentin, C, Motta, Stefano, Siani, Paulo, Donadoni, Edoardo, Frigerio, Giulia, Bonati, Laura, Di Valentin, Cristiana, Motta, S, Siani, P, Donadoni, E, Frigerio, G, Bonati, L, Di Valentin, C, Motta, Stefano, Siani, Paulo, Donadoni, Edoardo, Frigerio, Giulia, Bonati, Laura, and Di Valentin, Cristiana

Abstract

Inorganic nanoparticles show promising properties that allow them to be efficiently used as drug carriers. The main limitation in this type of application is currently the drug loading capacity, which can be overcome with a proper functionalization of the nanoparticle surface. In this study, we present, for the first time, a computational approach based on metadynamics to estimate the binding free energy of the doxorubicin drug (DOX) to a functionalized TiO2 nanoparticle under different pH conditions. On a thermodynamic basis, we demonstrate the robustness of our approach to capture the overall mechanism behind the pH-triggered release of DOX due to environmental pH changes. Notably, binding free energy estimations align well with what is expected for a pH-sensitive drug delivery system. Based on our results, we envision the use of metadynamics as a promising computational tool for the rational design and in silico optimization of organic ligands with improved drug carrier properties.

Published
2023

34. In-Plane Hydrogen Bonds and Out-of-Plane Dipolar Interactions in Self-Assembled Melem Networks

Author

Ugolotti, A, Lanzilotto, V, Grazioli, C, Schio, L, Zamalloa-Serrano, J, Stredansky, M, Zhang, T, de Simone, M, Ferraro, L, Floreano, L, Coreno, M, Puglia, C, Di Valentin, C, Ugolotti, Aldo, Lanzilotto, Valeria, Grazioli, Cesare, Schio, Luca, Zamalloa-Serrano, Jorge Manuel, Stredansky, Matus, Zhang, Teng, de Simone, Monica, Ferraro, Lorenzo, Floreano, Luca, Coreno, Marcello, Puglia, Carla, Di Valentin, Cristiana, Ugolotti, A, Lanzilotto, V, Grazioli, C, Schio, L, Zamalloa-Serrano, J, Stredansky, M, Zhang, T, de Simone, M, Ferraro, L, Floreano, L, Coreno, M, Puglia, C, Di Valentin, C, Ugolotti, Aldo, Lanzilotto, Valeria, Grazioli, Cesare, Schio, Luca, Zamalloa-Serrano, Jorge Manuel, Stredansky, Matus, Zhang, Teng, de Simone, Monica, Ferraro, Lorenzo, Floreano, Luca, Coreno, Marcello, Puglia, Carla, and Di Valentin, Cristiana

Abstract

Melem (2,6,10-triamino-s-heptazine) is the building block of melon, a carbon nitride (CN) polymer that is proven to produce H2from water under visible illumination. With the aim of bringing additional insight into the electronic structure of CN materials, we performed a spectroscopic characterization of gas-phase melem and of a melem-based self-assembled 2D H-bonded layer on Au(111) by means of ultraviolet and X-ray photoemission spectroscopy (UPS, XPS) and near-edge X-ray absorption fine structure (NEXAFS) spectroscopy. In parallel, we performed density functional theory (DFT) simulations of the same systems to unravel the molecular charge density redistribution caused by the in-plane H-bonds. Comparing the experimental results with the spectroscopic DFT simulations, we can correlate the induced charge accumulation on the Naminoatoms to the red-shift of the corresponding N 1s binding energy (BE) and of the Namino1s → LUMO+n transitions. Moreover, when introducing a supporting Au(111) surface in the computational simulations, we observe a molecule-substrate interaction that almost exclusively involves the out-of-plane molecular orbitals, leaving those engaged in the in-plane H-bonded network rather unperturbed.

Published
2023

35. Adsorption and Inactivation of SARS-CoV‐2 on the Surface of Anatase TiO2(101)

Author

Kohantorabi, M, Wagstaffe, M, Creutzburg, M, Ugolotti, A, Kulkarni, S, Jeromin, A, Krekeler, T, Feuerherd, M, Herrmann, A, Ebert, G, Protzer, U, Guédez, G, Löw, C, Thuenauer, R, Schlueter, C, Gloskovskii, A, Keller, T, Di Valentin, C, Stierle, A, Noei, H, Keller, TF, Kohantorabi, M, Wagstaffe, M, Creutzburg, M, Ugolotti, A, Kulkarni, S, Jeromin, A, Krekeler, T, Feuerherd, M, Herrmann, A, Ebert, G, Protzer, U, Guédez, G, Löw, C, Thuenauer, R, Schlueter, C, Gloskovskii, A, Keller, T, Di Valentin, C, Stierle, A, Noei, H, and Keller, TF

Abstract

We investigated the adsorption of severe acute respiratory syndrome corona virus 2 (SARS-CoV-2), the virus responsible for the current pandemic, on the surface of the model catalyst TiO2(101) using atomic force microscopy, transmission electron microscopy, fluorescence microscopy, and X-ray photoelectron spectroscopy, accompanied by density functional theory calculations. Three different methods were employed to inactivate the virus after it was loaded on the surface of TiO2(101): (i) ethanol, (ii) thermal, and (iii) UV treatments. Microscopic studies demonstrate that the denatured spike proteins and other proteins in the virus structure readsorb on the surface of TiO2 under thermal and UV treatments. The interaction of the virus with the surface of TiO2 was different for the thermally and UV treated samples compared to the sample inactivated via ethanol treatment. AFM and TEM results on the UV-treated sample suggested that the adsorbed viral particles undergo damage and photocatalytic oxidation at the surface of TiO2(101) which can affect the structural proteins of SARS-CoV-2 and denature the spike proteins in 30 min. The role of Pd nanoparticles (NPs) was investigated in the interaction between SARS-CoV-2 and TiO2(101). The presence of Pd NPs enhanced the adsorption of the virus due to the possible interaction of the spike protein with the NPs. This study is the first investigation of the interaction of SARS-CoV-2 with the surface of single crystalline TiO2(101) as a potential candidate for virus deactivation applications. Clarification of the interaction of the virus with the surface of semiconductor oxides will aid in obtaining a deeper understanding of the chemical processes involved in photoinactivation of microorganisms, which is important for the design of effective photocatalysts for air purification and self-cleaning materials.

Published
2023

38. Mechanistic Insigths from Molecular Dynamics in Nanomedicine Research

Author

Siani, P, Donadoni, E, Frigerio, G, DI VALENTIN, C, Paulo Siani, Edoardo Donadoni, Giulia Frigerio, Cristiana Di Valentin, Siani, P, Donadoni, E, Frigerio, G, DI VALENTIN, C, Paulo Siani, Edoardo Donadoni, Giulia Frigerio, and Cristiana Di Valentin

Abstract

Molecular dynamics simulation techniques have been in the spotlight of recent nanomedicine research, becoming an indispensable tool for unveiling complex molecular mechanisms that are sometimes unreachable by experimental methods. Here, I will exemplify how MD simulations can complement existing experimental knowledge or provide new mechanistic insights into relevant aspects of nanoscale devices designed for nanomedicine. Through some case studies - from how thermodynamic variables (e.g., pH and ionic strength) affect the protein corona formation onto organic-functionalized nanoparticles to the impact of lipid composition in the permeation process of anti-tumoral drugs in membranes - this presentation will address how classical MD simulations can be helpful bridging the simulated microscopic behavior to their corresponding macroscopic manifestation.

Published
2023

40. Computational modeling of complex nanosystems for drug delivery, targeting and imaging

Author

Di Valentin, C and Di Valentin, C

Abstract

Inorganic nanoparticles are excellent tools to create smart bioinorganic nanodevices for drug delivery, targeting and imaging. To investigate these complex systems, we use multiscale approaches ranging from first-principles calculations to atomistic molecular dynamics simulations, metadynamics, umbrella sampling and machine learning.

Published
2023

43. Tuning graphene doping by carbon monoxide intercalation at the Ni(111) interface

Author

Del Puppo, S, Carnevali, V, Perilli, D, Zarabara, F, Rizzini, A, Fornasier, G, Zupanic, E, Fiori, S, Patera, L, Panighel, M, Bhardwaj, S, Zou, Z, Comelli, G, Africh, C, Cepek, C, Di Valentin, C, Peressi, M, Del Puppo S., Carnevali V., Perilli D., Zarabara F., Rizzini A. L., Fornasier G., Zupanic E., Fiori S., Patera L. L., Panighel M., Bhardwaj S., Zou Z., Comelli G., Africh C., Cepek C., Di Valentin C., Peressi M., Del Puppo, S, Carnevali, V, Perilli, D, Zarabara, F, Rizzini, A, Fornasier, G, Zupanic, E, Fiori, S, Patera, L, Panighel, M, Bhardwaj, S, Zou, Z, Comelli, G, Africh, C, Cepek, C, Di Valentin, C, Peressi, M, Del Puppo S., Carnevali V., Perilli D., Zarabara F., Rizzini A. L., Fornasier G., Zupanic E., Fiori S., Patera L. L., Panighel M., Bhardwaj S., Zou Z., Comelli G., Africh C., Cepek C., Di Valentin C., and Peressi M.

Abstract

Under near-ambient pressure conditions, carbon monoxide molecules intercalate underneath an epitaxial graphene monolayer grown on Ni(111), getting trapped into the confined region at the interface. On the basis of ab-initio density functional theory calculations, we provide here a full investigation of the intercalated CO pattern, highlighting the modifications induced on the graphene electronic structure. For a CO coverage as low as 0.14 monolayer (ML), the graphene layer is spatially decoupled from the metallic substrate, with a significant C 1s core level shift towards lower binding energies. The most relevant signature of the CO intercalation is a clear switching of the graphene doping state, which changes from n-type, when strongly interacting with the metal surface, to p-type. The shift of the Dirac cone linearly depends on the CO coverage, reaching about 0.9 eV for the saturation value of 0.57 ML. Theoretical predictions are compared with the results of scanning tunnelling microscopy, low-energy electron diffraction and photoemission spectroscopy experiments, which confirm the proposed scenario for the nearly saturated intercalated CO system. This result opens the way to the application of the graphene/Ni(111) interface as gas sensor to easily detect and quantify the presence of carbon monoxide.

Published
2021

44. Operando visualization of the hydrogen evolution reaction with atomic-scale precision at different metal–graphene interfaces

Author

Kosmala, T, Baby, A, Lunardon, M, Perilli, D, Liu, H, Durante, C, Di Valentin, C, Agnoli, S, Granozzi, G, Kosmala T., Baby A., Lunardon M., Perilli D., Liu H., Durante C., Di Valentin C., Agnoli S., Granozzi G., Kosmala, T, Baby, A, Lunardon, M, Perilli, D, Liu, H, Durante, C, Di Valentin, C, Agnoli, S, Granozzi, G, Kosmala T., Baby A., Lunardon M., Perilli D., Liu H., Durante C., Di Valentin C., Agnoli S., and Granozzi G.

Abstract

The development of catalysts for the hydrogen evolution reaction is pivotal for the hydrogen economy. Thin iron films covered with monolayer graphene exhibit outstanding catalytic activity, surpassing even that of platinum, as demonstrated by a method based on evaluating the noise in the tunnelling current of electrochemical scanning tunnelling microscopy. Using this approach, we mapped with atomic-scale precision the electrochemical activity of the graphene–iron interface, and determined that single iron atoms trapped within carbon vacancies and curved graphene areas on step edges are exceptionally active. Density functional theory calculations confirmed the sequence of activity obtained experimentally. This work exemplifies the potential of electrochemical scanning tunnelling microscopy as the only technique able to determine both the atomic structure and relative catalytic performance of atomically well-defined sites in electrochemical operando conditions and provides a detailed rationale for the design of novel catalysts based on cheap and abundant metals such as iron. [Figure not available: see fulltext.].

Published
2021

45. New Insights into Crystal Defects, Oxygen Vacancies, and Phase Transition of Ir-TiO2

Author

Kumaravel, V, Bianchetti, E, Mathew, S, Hinder, S, Bartlett, J, Di Valentin, C, Pillai, S, Kumaravel V., Bianchetti E., Mathew S., Hinder S. J., Bartlett J., Di Valentin C., Pillai S. C., Kumaravel, V, Bianchetti, E, Mathew, S, Hinder, S, Bartlett, J, Di Valentin, C, Pillai, S, Kumaravel V., Bianchetti E., Mathew S., Hinder S. J., Bartlett J., Di Valentin C., and Pillai S. C.

Abstract

The impact of iridium (Ir) doping on the oxygen vacancies, relative stability, crystallite size, surface area, and anatase-to-rutile transition of TiO2was comprehensively investigated in this study. Ir-doped TiO2(Ir-TiO2) was synthesized through a sol-gel technique, and the samples were annealed in the temperature range of 400-700 °C. Density functional theory calculations showed that the energy cost of an oxygen vacancy formation for Ir-TiO2was lower, as compared to that of the pristine TiO2, with the formation of Ir3+states in the band gap. Ir could provide more rutile nucleation sites and accelerate the rutile formation through the crystal strain relaxation. The entropy of mixing was reduced by the incorporation of Ir, which could induce the rutile formation with an increase in Gibbs free energy at temperatures below the normal phase transition temperature for pure TiO2. The rutile formation of Ir-TiO2could take place at a low annealing temperature (400 °C) compared to pristine TiO2(600 °C), indicating that the activation energy for phase transition could be decreased by incorporating Ir. XPS revealed the spin-orbit coupling of Ir 4f peaks, Ir 4f7/2(61.96 eV) and Ir 4f5/2(64.77 eV), due to the presence of Ir3+. Raman studies indicated the formation of charge-compensating oxygen vacancies and the presence of d states by Ir doping. It is concluded that the defects originated because the incorporation of Ir could facilitate rutile nucleation sites and thereby accelerate the phase transition through strain relaxation.

Published
2021

46. Copper single-atoms embedded in 2D graphitic carbon nitride for the CO2 reduction

Author

Cometto, C, Ugolotti, A, Grazietti, E, Moretto, A, Bottaro, G, Armelao, L, Di Valentin, C, Calvillo, L, Granozzi, G, Cometto C., Ugolotti A., Grazietti E., Moretto A., Bottaro G., Armelao L., Di Valentin C., Calvillo L., Granozzi G., Cometto, C, Ugolotti, A, Grazietti, E, Moretto, A, Bottaro, G, Armelao, L, Di Valentin, C, Calvillo, L, Granozzi, G, Cometto C., Ugolotti A., Grazietti E., Moretto A., Bottaro G., Armelao L., Di Valentin C., Calvillo L., and Granozzi G.

Abstract

We report the study of two-dimensional graphitic carbon nitride (GCN) functionalized with copper single atoms as a catalyst for the reduction of CO2 (CO2RR). The correct GCN structure, as well as the adsorption sites and the coordination of the Cu atoms, was carefully determined by combining experimental techniques, such as X-ray diffraction, transmission electron microscopy, X-ray absorption, and X-ray photoemission spectroscopy, with DFT theoretical calculations. The CO2RR products in KHCO3 and phosphate buffer solutions were determined by rotating ring disk electrode measurements and confirmed by 1H-NMR and gas chromatography. Formate was the only liquid product obtained in bicarbonate solution, whereas only hydrogen was obtained in phosphate solution. Finally, we demonstrated that GCN is a promising substrate able to stabilize metal atoms, since the characterization of the Cu-GCN system after the electrochemical work did not show the aggregation of the copper atoms.

Published
2021

47. Ab-initio spectroscopic characterization of melem-based graphitic carbon nitride polymorphs

Author

Ugolotti, A, Di Valentin, C, Ugolotti A., Di Valentin C., Ugolotti, A, Di Valentin, C, Ugolotti A., and Di Valentin C.

Abstract

Polymeric graphitic carbon nitride (gCN) compounds are promising materials in photoacti-vated electrocatalysis thanks to their peculiar structure of periodically spaced voids exposing reactive pyridinic N atoms. These are excellent sites for the adsorption of isolated transition metal atoms or small clusters that can highly enhance the catalytic properties. However, several polymorphs of gCN can be obtained during synthesis, differing for their structural and electronic properties that ultimately drive their potential as catalysts. The accurate characterization of the obtained material is critical for the correct rationalization of the catalytic results; however, an unambiguous experimental identification of the actual polymer is challenging, especially without any reference spectroscopic features for the assignment. In this work, we optimized several models of melem-based gCN, taking into account different degrees of polymerization and arrangement of the monomers, and we present a thorough computational characterization of their simulated XRD, XPS, and NEXAFS spectroscopic properties, based on state-of-the-art density functional theory calculations. Through this detailed study, we could identify the peculiar fingerprints of each model and correlate them with its structural and/or electronic properties. Theoretical predictions were compared with the experimental data whenever they were available.

Published
2021

48. Parametrization of the Fe-Owatercross-interaction for a more accurate Fe3O4/water interface model and its application to a spherical Fe3O4nanoparticle of realistic size

Author

Siani, P, Bianchetti, E, Liu, H, Di Valentin, C, Siani P., Bianchetti E., Liu H., Di Valentin C., Siani, P, Bianchetti, E, Liu, H, Di Valentin, C, Siani P., Bianchetti E., Liu H., and Di Valentin C.

Abstract

The accurate description of iron oxides/water interfaces requires reliable force field parameters that can be developed through comparison with sophisticated quantum mechanical calculations. Here, a set of CLASS2 force field parameters is optimized to describe the Fe-Owater cross-interaction through comparison with hybrid density functional theory (HSE06) calculations of the potential energy function for a single water molecule adsorbed on the Fe3O4 (001) surface and with density functional tight binding (DFTB+U) molecular dynamics simulations for a water trilayer on the same surface. The performance of the new parameters is assessed through the analysis of the number density profile of a water bulk (12 nm) sandwiched between two magnetite slabs of large surface area. Their transferability is tested for water adsorption on the curved surface of a spherical Fe3O4 nanoparticle of realistic size (2.5 nm).

Published
2021

49. Multiscale simulations of the hydration shells surrounding spherical Fe3O4nanoparticles and effect on magnetic properties

Author

Liu, H, Siani, P, Bianchetti, E, Zhao, J, Di Valentin, C, Liu H., Siani P., Bianchetti E., Zhao J., Di Valentin C., Liu, H, Siani, P, Bianchetti, E, Zhao, J, Di Valentin, C, Liu H., Siani P., Bianchetti E., Zhao J., and Di Valentin C.

Abstract

Iron oxide magnetic nanoparticles (NPs) are excellent systems in catalysis and in nanomedicine, where they are mostly immersed in aqueous media. Even though the NP solvation by water is expected to play an active role, the detailed structural insight at the nanostructure oxide/water interface is still missing. Here, based on our previous efforts to obtain accurate models of dehydrated Fe3O4 NPs and of their magnetic properties and through multiscale molecular dynamics simulations combining the density functional tight binding method and force field, we unravel the atomistic details of the short range (chemical) and long range (physical) interfacial effects when magnetite nanoparticles are immersed in water. The influence of the first hydration shell on the structural, electronic and magnetic properties of Fe3O4 NPs is revealed by high-level hybrid density functional calculations. Hydrated Fe3O4 NPs possess larger magnetic moment than dehydrated ones. This work bridges the large gap between experimental studies on solvated Fe3O4 NPs and theoretical investigations on flat Fe3O4 surfaces covered with water and paves the way for further study of Fe3O4 NPs in biological environments. This journal is

Published
2021

50. Single Atom Catalysts (SAC) trapped in defective and nitrogen-doped graphene supported on metal substrates

Author

Baby, A, Trovato, L, Di Valentin, C, Baby A., Trovato L., Di Valentin C., Baby, A, Trovato, L, Di Valentin, C, Baby A., Trovato L., and Di Valentin C.

Abstract

Single Atom Catalysts (SAC) in graphene have been recently gaining more and more attention. They are usually non-noble transition metal (TM) adatoms getting trapped at the carbon vacancies during the fabrication of the graphene layer, which then act as active centers for catalysis and adsorption. In this work we present a systematic and comparative investigation, by means of dispersion–corrected density functional theory (DFT) calculations, of Fe, Co, Ni, and Cu as possible SACs when they become trapped at graphene C vacancies. The stability of these TM atoms is further increased by introducing pyridinic nitrogen (N) atoms and transforming graphene into a giant porphyrin-like macrocyclic ligand. The structural, electronic and energetics properties of these systems, even under the effect of a metal substrate (weakly interacting Cu (111) or strongly interacting Ni (111)), are comparatively examined in great detail by means of crystal/ligand field theories and through ad-hoc energy decomposition analysis to highlight trends and peculiar behaviors. The position of the TM d-orbitals with respect to the Fermi level of the whole system is of considerable importance for designing prospective device applications in catalysis, electrocatalysis and sensors. To this purpose, we also examine how the reactivity of the SACs in graphene towards the hydrogen evolution reaction (HER) can be tuned with N-doping and with different substrates.

Published
2021

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