Your search keyword '"Di Santo, Giovanni"' showing total 29 results

1. Achieving High Substitutional Incorporation in Mn-Doped Graphene.

Author

Villarreal R, Zarkua Z, Kretschmer S, Hendriks V, Hillen J, Tsai HC, Junge F, Nissen M, Saha T, Achilli S, Hofsäss HC, Martins M, De Ninno G, Lacovig P, Lizzit S, Di Santo G, Petaccia L, De Feyter S, De Gendt S, Brems S, Van de Vondel J, Krasheninnikov AV, and Pereira LMC

Abstract

Despite its broad potential applications, substitution of carbon by transition metal atoms in graphene has so far been explored only to a limited extent. We report the realization of substitutional Mn doping of graphene to a record high atomic concentration of 0.5%, which was achieved using ultralow-energy ion implantation. By correlating the experimental data with the results of ab initio Born-Oppenheimer molecular dynamics calculations, we infer that direct substitution is the dominant mechanism of impurity incorporation. Thermal annealing in ultrahigh vacuum provides efficient removal of surface contaminants and additional implantation-induced disorder, resulting in Mn-doped graphene that, aside from the substitutional Mn impurities, is essentially as clean and defect-free as the as-grown layer. We further show that the Dirac character of graphene is preserved upon substitutional Mn doping, even in this high concentration regime, making this system ideal for studying the interaction between Dirac conduction electrons and localized magnetic moments. More generally, these results show that ultralow energy ion implantation can be used for controlled functionalization of graphene with substitutional transition-metal atoms, of relevance for a wide range of applications, from magnetism and spintronics to single-atom catalysis.

Published

2024

2. Charge Transfer and Orbital Reconstruction at an Organic-Oxide Interface.

Author

Caputo M, Studniarek M, Guedes EB, Schio L, Baiseitov K, Daffé N, Bachellier N, Chikina A, Di Santo G, Verdini A, Goldoni A, Muntwiler M, Piamonteze C, Floreano L, Radovic M, and Dreiser J

Abstract

The two-dimensional electron system (2DES) located at the surface of strontium titanate (STO) and at several other STO-based interfaces has been an established platform for the study of novel physical phenomena since its discovery. Here we report how the interfacing of STO and tetracyanoquinodimethane (TCNQ) results in a charge transfer that depletes the number of free carriers at the STO surface, with a strong impact on its electronic structure. Our study paves the way for efficient tuning of the electronic properties, which promises novel applications in the framework of oxide/organic-based electronics.

Published

2023

3. Sublattice Ferrimagnetism in Quasifreestanding Graphene.

Author

Rybkin AG, Tarasov AV, Rybkina AA, Usachov DY, Petukhov AE, Eryzhenkov AV, Pudikov DA, Gogina AA, Klimovskikh II, Di Santo G, Petaccia L, Varykhalov A, and Shikin AM

Subjects

Environment, Fruit, Graphite

Abstract

We show that graphene can be magnetized by coupling to a ferromagnetic Co film through a Au monolayer. The presence of dislocation loops under graphene leads to a ferrimagnetic ordering of moments in the two C sublattices. It is shown that the band gap of ∼80  meV in the K[over ¯] point has a magnetic nature and exists for ferrimagnetic ordering. Interplay between Rashba and exchange couplings is evidenced by spin splitting asymmetry in spin-ARPES measurements and fully supported by DFT calculation of a (9×9) unit cell. Owing to sign-opposite Berry curvatures for K[over ¯] and K[over ¯]^{'} valleys, the synthesized system is promising for the realization of a circular dichroism Hall effect.

Published

2022

4. Anomalies at the Dirac Point in Graphene and Its Hole-Doped Compositions.

Author

Pramanik A, Thakur S, Singh B, Willke P, Wenderoth M, Hofsäss H, Di Santo G, Petaccia L, and Maiti K

Abstract

We study the properties of the Dirac states in SiC-graphene and its hole-doped compositions employing angle-resolved photoemission spectroscopy and density functional theory. The symmetry-selective measurements for the Dirac bands reveal their linearly dispersive behavior across the Dirac point which was termed as the anomalous region in earlier studies. No gap is observed even after boron substitution that reduced the carrier concentration significantly from 3.7×10^{13}  cm^{-2} in SiC-graphene to 0.8×10^{13}  cm^{-2} (5% doping). The anomalies at the Dirac point are attributed to the spectral width arising from the lifetime and momentum broadening in the experiments. The substitution of boron at the graphitic sites leads to a band renormalization and a shift of the Dirac point towards the Fermi level. The internal symmetries appear to be preserved in SiC-graphene even after significant boron substitutions. These results suggest that SiC-graphene is a good platform to realize exotic science as well as advanced technology where the carrier properties like concentration, mobility, etc., can be tuned keeping the Dirac fermionic properties protected.

Published

2022

5. Correction to Doping Graphene with Substitutional Mn.

Author

Lin PC, Villarreal R, Achilli S, Bana H, Nair MN, Tejeda A, Verguts K, De Gendt S, Auge M, Hofsäss H, De Feyter S, Di Santo G, Petaccia L, Brems S, Fratesi G, and Pereira LMC

Published

2022

6. Orbital Mapping of Semiconducting Perylenes on Cu(111).

Author

Di Santo G, Miletić T, Schwendt M, Zhou Y, Kariuki BM, Harris KDM, Floreano L, Goldoni A, Puschnig P, Petaccia L, and Bonifazi D

Abstract

Semiconducting O-doped polycyclic aromatic hydrocarbons constitute a class of molecules whose optoelectronic properties can be tailored by acting on the π-extension of the carbon-based frameworks and on the oxygen linkages. Although much is known about their photophysical and electrochemical properties in solution, their self-assembly interfacial behavior on solid substrates has remained unexplored so far. In this paper, we have focused our attention on the on-surface self-assembly of O-doped bi-perylene derivatives. Their ability to assemble in ordered networks on Cu(111) single-crystalline surfaces allowed a combination of structural, morphological, and spectroscopic studies. In particular, the exploitation of the orbital mapping methodology based on angle-resolved photoemission spectroscopy, with the support of scanning tunneling microscopy and low-energy electron diffraction, allowed the identification of both the electronic structure of the adsorbates and their geometric arrangement. Our multi-technique experimental investigation includes the structure determination from powder X-ray diffraction data for a specific compound and demonstrates that the electronic structure of such large molecular self-assembled networks can be studied using the reconstruction methods of molecular orbitals from photoemission data even in the presence of segregated chiral domains., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021

7. Turning Low-Nanoscale Intrinsic Silicon Highly Electron-Conductive by SiO 2 Coating.

Author

König D, Frentzen M, Wilck N, Berghoff B, Píš I, Nappini S, Bondino F, Müller M, Gonzalez S, Di Santo G, Petaccia L, Mayer J, Smith S, and Knoch J

Abstract

Impurity doping in silicon (Si) ultra-large-scale integration is one of the key challenges which prevent further device miniaturization. Using ultraviolet photoelectron spectroscopy and X-ray absorption spectroscopy in the total fluorescence yield mode, we show that the lowest unoccupied and highest occupied electronic states of ≤3 nm thick SiO 2 -coated Si nanowells shift by up to 0.2 eV below the conduction band and ca. 0.7 eV below the valence band edge of bulk silicon, respectively. This nanoscale electronic structure shift induced by anions at surfaces (NESSIAS) provides the means for low-nanoscale intrinsic Si (i-Si) to be flooded by electrons from an external (bigger, metallic) reservoir, thereby getting highly electron- (n-) conductive. While our findings deviate from the behavior commonly believed to govern the properties of silicon nanowells, they are further confirmed by the fundamental energy gap as per nanowell thickness when compared against published experimental data. Supporting our findings further with hybrid density functional theory calculations, we show that other group IV semiconductors (diamond, Ge) do respond to the NESSIAS effect in accord with Si. We predict adequate nanowire cross-sections (X-sections) from experimental nanowell data with a recently established crystallographic analysis, paving the way to undoped ultrasmall silicon electronic devices with significantly reduced gate lengths, using complementary metal-oxide-semiconductor-compatible materials.

Published

2021

8. Doping Graphene with Substitutional Mn.

Author

Lin PC, Villarreal R, Achilli S, Bana H, Nair MN, Tejeda A, Verguts K, De Gendt S, Auge M, Hofsäss H, De Feyter S, Di Santo G, Petaccia L, Brems S, Fratesi G, and Pereira LMC

Abstract

We report the incorporation of substitutional Mn atoms in high-quality, epitaxial graphene on Cu(111), using ultralow-energy ion implantation. We characterize in detail the atomic structure of substitutional Mn in a single carbon vacancy and quantify its concentration. In particular, we are able to determine the position of substitutional Mn atoms with respect to the Moiré superstructure ( i . e ., local graphene-Cu stacking symmetry) and to the carbon sublattice; in the out-of-plane direction, substitutional Mn atoms are found to be slightly displaced toward the Cu surface, that is, effectively underneath the graphene layer. Regarding electronic properties, we show that graphene doped with substitutional Mn to a concentration of the order of 0.04%, with negligible structural disorder (other than the Mn substitution), retains the Dirac-like band structure of pristine graphene on Cu(111), making it an ideal system in which to study the interplay between local magnetic moments and Dirac electrons. Our work also establishes that ultralow-energy ion implantation is suited for substitutional magnetic doping of graphene. Given the flexibility, reproducibility, and scalability inherent to ion implantation, our work creates numerous opportunities for research on magnetic functionalization of graphene and other two-dimensional materials.

Published

2021

9. Interface Chemistry of Graphene/Cu Grafted By 3,4,5-Tri-Methoxyphenyl.

Author

Ambrosio G, Drera G, Di Santo G, Petaccia L, Daukiya L, Brown A, Hirsch B, De Feyter S, Sangaletti L, and Pagliara S

Abstract

Chemical reaction with diazonium molecules has revealed to be a powerful method for the surface chemical modification of graphite, carbon nanotubes and recently also of graphene. Graphene electronic structure modification using diazonium molecules is strongly influenced by graphene growth and by the supporting materials. Here, carrying on a detailed study of core levels and valence band photoemission measurements, we are able to reconstruct the interface chemistry of trimethoxybenzenediazonium-based molecules electrochemically grafted on graphene on copper. The band energy alignment at the molecule-graphene interface has been traced revealing the energy position of the HOMO band with respect to the Fermi level.

Published

2020

10. Origin of the Flat Band in Heavily Cs-Doped Graphene.

Author

Ehlen N, Hell M, Marini G, Hasdeo EH, Saito R, Falke Y, Goerbig MO, Di Santo G, Petaccia L, Profeta G, and Grüneis A

Abstract

A flat energy dispersion of electrons at the Fermi level of a material leads to instabilities in the electronic system and can drive phase transitions. Here we show that the flat band in graphene can be achieved by sandwiching a graphene monolayer by two cesium (Cs) layers. We investigate the flat band by a combination of angle-resolved photoemission spectroscopy experiment and the calculations. Our work highlights that charge transfer, zone folding of graphene bands, and the covalent bonding between C and Cs atoms are the origin of the flat energy band formation. Analysis of the Stoner criterion for the flat band suggests the presence of a ferromagnetic instability. The presented approach is an alternative route for obtaining flat band materials to twisting bilayer graphene which yields thermodynamically stable flat band materials in large areas.

Published

2020

11. Electronic structure of MAPbI 3 and MAPbCl 3 : importance of band alignment.

Author

Caputo M, Cefarin N, Radivo A, Demitri N, Gigli L, Plaisier JR, Panighel M, Di Santo G, Moretti S, Giglia A, Polentarutti M, De Angelis F, Mosconi E, Umari P, Tormen M, and Goldoni A

Abstract

Since their first appearance, organic-inorganic perovskite absorbers have been capturing the attention of the scientific community. While high efficiency devices highlight the importance of band level alignment, very little is known on the origin of the strong n-doping character observed in the perovskite. Here, by means of a highly accurate photoemission study, we shed light on the energy alignment in perovskite-based devices. Our results suggest that the interaction with the substrate may be the driver for the observed doping in the perovskite samples.

Published

2019

12. Iron Phthalocyanine and Ferromagnetic Thin Films: Magnetic Behavior of Single and Double Interfaces.

Author

Annese E, Di Santo G, Choueikani F, Otero E, and Ohresser P

Abstract

Metal-phthalocyanines are quasi-planar heterocyclic macrocycle molecules with a highly conjugated structure. They can be engineered at the molecular scale (central atom, ligand) to tailor new properties for organic spintronics devices. In this study, we evaluated the magnetic behavior of FePc in a ∼1 nm molecular film sandwiched between two ferromagnetic films: cobalt (bottom) and nickel (top). In the single interface, FePc in contact with a Co film is magnetically coupled with the inorganic film magnetization, though the relatively small Fe(Pc) X-ray magnetic circular dichroism (XMCD) signal in remanence, with respect to that observed in applied field of 6 T, suggests that a fraction of molecules in the organometallic film have their magnetic moment not aligned or antiparallel with respect to Co. When in contact with two interfaces, Fe(Pc) XMCD doubles, indicating that part of the Fe(Pc) are now aligned with the Ni topmost layer, saturated at 1 T. We discussed the relevance of the finding in terms of understanding and developing hybrid organic/inorganic spin devices., Competing Interests: The authors declare no competing financial interest.

Published

2019

13. Resonance Raman Spectrum of Doped Epitaxial Graphene at the Lifshitz Transition.

Author

Hell MG, Ehlen N, Senkovskiy BV, Hasdeo EH, Fedorov A, Dombrowski D, Busse C, Michely T, di Santo G, Petaccia L, Saito R, and Grüneis A

Abstract

We employ ultra-high vacuum (UHV) Raman spectroscopy in tandem with angle-resolved photoemission (ARPES) to investigate the doping-dependent Raman spectrum of epitaxial graphene on Ir(111). The evolution of Raman spectra from pristine to heavily Cs doped graphene up to a carrier concentration of 4.4 × 10 14 cm -2 is investigated. At this doping, graphene is at the onset of the Lifshitz transition and renormalization effects reduce the electronic bandwidth. The optical transition at the saddle point in the Brillouin zone then becomes experimentally accessible by ultraviolet (UV) light excitation, which achieves resonance Raman conditions in close vicinity to the van Hove singularity in the joint density of states. The position of the Raman G band of fully doped graphene/Ir(111) shifts down by ∼60 cm -1 . The G band asymmetry of Cs doped epitaxial graphene assumes an unusual strong Fano asymmetry opposite to that of the G band of doped graphene on insulators. Our calculations can fully explain these observations by substrate dependent quantum interference effects in the scattering pathways for vibrational and electronic Raman scattering.

Published

2018

14. Intrinsic ultrasmall nanoscale silicon turns n-/p-type with SiO 2 /Si 3 N 4 -coating.

Author

König D, Hiller D, Wilck N, Berghoff B, Müller M, Thakur S, Di Santo G, Petaccia L, Mayer J, Smith S, and Knoch J

Abstract

Impurity doping of ultrasmall nanoscale (usn) silicon (Si) currently used in ultralarge scale integration (ULSI) faces serious miniaturization challenges below the 14 nm technology node such as dopant out-diffusion and inactivation by clustering in Si-based field-effect transistors (FETs). Moreover, self-purification and massively increased ionization energy cause doping to fail for Si nano-crystals (NCs) showing quantum confinement. To introduce electron- (n-) or hole- (p-) type conductivity, usn-Si may not require doping, but an energy shift of electronic states with respect to the vacuum energy between different regions of usn-Si. We show in theory and experiment that usn-Si can experience a considerable energy offset of electronic states by embedding it in silicon dioxide (SiO 2 ) or silicon nitride (Si 3 N 4 ), whereby a few monolayers (MLs) of SiO 2 or Si 3 N 4 are enough to achieve these offsets. Our findings present an alternative to conventional impurity doping for ULSI, provide new opportunities for ultralow power electronics and open a whole new vista on the introduction of p- and n-type conductivity into usn-Si.

Published

2018

15. Synthesis and spectroscopic characterization of alkali-metal intercalated ZrSe 2 .

Author

Nikonov K, Ehlen N, Senkovskiy B, Saigal N, Fedorov A, Nefedov A, Wöll C, Di Santo G, Petaccia L, and Grüneis A

Abstract

We report on the synthesis and spectroscopic characterization of alkali metal intercalated ZrSe 2 single crystals. ZrSe 2 is produced by chemical vapour transport and then Li is intercalated. Intercalation is performed from the liquid phase (via butyllithium) and from the vapour phase. Raman spectroscopy of intercalated ZrSe 2 reveals phonon energy shifts of the Raman active A 1g and E g phonon modes, the disappearance of two-phonon modes and new low wavenumber Raman modes. Angle-resolved photoemission spectroscopy is used to perform a mapping of the Fermi surface revealing an electron concentration of 4.7 × 10 14 cm -2 . We also perform vapour phase intercalation of K and Cs into ZrSe 2 and observe similar changes in the Raman modes as for the Li case.

Published

2018

16. Publisher Correction: Multi-orbital charge transfer at highly oriented organic/metal interfaces.

Author

Zamborlini G, Lüftner D, Feng Z, Kollmann B, Puschnig P, Dri C, Panighel M, Di Santo G, Goldoni A, Comelli G, Jugovac M, Feyer V, and Schneider CM

Abstract

The original version of this Article contained an error in the spelling of the author Claus Michael Schneider, which was incorrectly given as Claus Michael Schneidery. This has now been corrected in both the PDF and HTML versions of the Article.

Published

2017

17. Reply to "Comment on 'Spin-Orbit Coupling Induced Gap in Graphene on Pt(111) with Intercalated Pb Monolayer'".

Author

Klimovskikh II, Otrokov MM, Voroshnin VY, Sostina D, Petaccia L, Di Santo G, Thakur S, Chulkov EV, and Shikin AM

Published

2017

18. Multi-orbital charge transfer at highly oriented organic/metal interfaces.

Author

Zamborlini G, Lüftner D, Feng Z, Kollmann B, Puschnig P, Dri C, Panighel M, Di Santo G, Goldoni A, Comelli G, Jugovac M, Feyer V, and Schneider CM

Abstract

The molecule-substrate interaction plays a key role in charge injection organic-based devices. Charge transfer at molecule-metal interfaces strongly affects the overall physical and magnetic properties of the system, and ultimately the device performance. Here, we report theoretical and experimental evidence of a pronounced charge transfer involving nickel tetraphenyl porphyrin molecules adsorbed on Cu(100). The exceptional charge transfer leads to filling of the higher unoccupied orbitals up to LUMO+3. As a consequence of this strong interaction with the substrate, the porphyrin's macrocycle sits very close to the surface, forcing the phenyl ligands to bend upwards. Due to this adsorption configuration, scanning tunneling microscopy cannot reliably probe the states related to the macrocycle. We demonstrate that photoemission tomography can instead access the Ni-TPP macrocycle electronic states and determine the reordering and filling of the LUMOs upon adsorption, thereby confirming the remarkable charge transfer predicted by density functional theory calculations.Charge transfer at molecule-metal interfaces affects the overall physical and magnetic properties of organic-based devices, and ultimately their performance. Here, the authors report evidence of a pronounced charge transfer involving nickel tetraphenyl porphyrin molecules adsorbed on copper.

Published

2017

19. Spectroscopic observation of oxygen dissociation on nitrogen-doped graphene.

Author

Scardamaglia M, Susi T, Struzzi C, Snyders R, Di Santo G, Petaccia L, and Bittencourt C

Abstract

Carbon nanomaterials' reactivity towards oxygen is very poor, limiting their potential applications. However, nitrogen doping is an established way to introduce active sites that facilitate interaction with gases. This boosts the materials' reactivity for bio-/gas sensing and enhances their catalytic performance for the oxygen reduction reaction. Despite this interest, the role of differently bonded nitrogen dopants in the interaction with oxygen is obscured by experimental challenges and has so far resisted clear conclusions. We study the interaction of molecular oxygen with graphene doped via nitrogen plasma by in situ high-resolution synchrotron techniques, supported by density functional theory core level simulations. The interaction leads to oxygen dissociation and the formation of carbon-oxygen single bonds on graphene, along with a band gap opening and a rounding of the Dirac cone. The change of the N 1 s core level signal indicates that graphitic nitrogen is involved in the observed mechanism: the adsorbed oxygen molecule is dissociated and the two O atoms chemisorb with epoxy bonds to the nearest carbon neighbours of the graphitic nitrogen. Our findings help resolve existing controversies and offer compelling new evidence of the ORR pathway.

Published

2017

20. Spin-Orbit Coupling Induced Gap in Graphene on Pt(111) with Intercalated Pb Monolayer.

Author

Klimovskikh II, Otrokov MM, Voroshnin VY, Sostina D, Petaccia L, Di Santo G, Thakur S, Chulkov EV, and Shikin AM

Abstract

Graphene is one of the most promising materials for nanoelectronics owing to its unique Dirac cone-like dispersion of the electronic state and high mobility of the charge carriers. However, to facilitate the implementation of the graphene-based devices, an essential change of its electronic structure, a creation of the band gap should controllably be done. Brought about by two fundamentally different mechanisms, a sublattice symmetry breaking or an induced strong spin-orbit interaction, the band gap appearance can drive graphene into a narrow-gap semiconductor or a 2D topological insulator phase, respectively, with both cases being technologically relevant. The later case, characterized by a spin-orbit gap between the valence and conduction bands, can give rise to the spin-polarized topologically protected edge states. Here, we study the effect of the spin-orbit interaction enhancement in graphene placed in contact with a lead monolayer. By means of angle-resolved photoemission spectroscopy, we show that intercalation of the Pb interlayer between the graphene sheet and the Pt(111) surface leads to formation of a gap of ∼200 meV at the Dirac point of graphene. Spin-resolved measurements confirm the splitting to be of a spin-orbit nature, and the measured near-gap spin structure resembles that of the quantum spin Hall state in graphene, proposed by Kane and Mele [ Phys. Rev. Lett. 2005 , 95 , 226801 ]. With a bandstructure tuned in this way, graphene acquires a functionality going beyond its intrinsic properties and becomes more attractive for possible spintronic applications.

Published

2017

21. Water Formation for the Metalation of Porphyrin Molecules on Oxidized Cu(111).

Author

Verdini A, Shinde P, Montanari GL, Suran-Brunelli ST, Caputo M, Di Santo G, Pignedoli CA, Floreano L, Passerone D, and Goldoni A

Abstract

Herein the formation of water molecules in the intermediate step of the redox reaction of porphyrins self-metalation on O/Cu(111) is demonstrated. Photoemission measurements show that the temperature on which porphyrins pick-up a substrate metal atom on O/Cu(111) is reduced by about 185±15 K with respect to the pure Cu(111). DFT calculations clearly indicate that the formation of a water molecule is less expensive than the formation of H2 on the O/Cu(111) substrate and, in some cases, it can be also exothermic., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2016

22. Adsorption geometry, conformation, and electronic structure of 2H-octaethylporphyrin on Ag(111) and Fe metalation in ultra high vacuum.

Author

Borghetti P, Di Santo G, Castellarin-Cudia C, Fanetti M, Sangaletti L, Magnano E, Bondino F, and Goldoni A

Abstract

Due to the growing interest in the ferromagnetic properties of Fe-octaethylporphyrins (Fe-OEP) for applications in spintronics, methods to produce stable Fe-porphyrins with no Cl atoms are highly demanded. Here, we demonstrate the formation of Fe-OEP layers on Ag(111) single crystal by the ultra high vacuum in situ metalation of the free-base 2H-2,3,7,8,12,13,17,18-octaethylporphyrin (2H-OEP) molecules. The metalation proceeds exactly as in the case of 2H-5,10,15,20-tetraphenylporphyrin (2H-TPP) on the same substrate. An extensive surface characterization by means of X-ray photoemission spectroscopy, valence band photoemission, and NEXAFS with synchrotron radiation light provides information on molecular conformation and electronic structure in the monolayer and multilayer cases. We demonstrate that the presence of the ethyl groups affects the tilt of the adsorbed molecules, the conformation of the macrocycle, and the polarization screening in multilayers, but has only a minor effect in the metalation process with respect to 2H-TPP.

Published

2013

23. Room temperature metalation of 2H-TPP monolayer on iron and nickel surfaces by picking up substrate metal atoms.

Author

Goldoni A, Pignedoli CA, Di Santo G, Castellarin-Cudia C, Magnano E, Bondino F, Verdini A, and Passerone D

Abstract

Here, it is demonstrated, using high-resolution X-ray spectroscopy and density functional theory calculations, that 2H-tetraphenyl porphyrins metalate at room temperature by incorporating a surface metal atom when a (sub)monolayer is deposited on 3d magnetic substrates, such as Fe(110) and Ni(111). The calculations demonstrate that the redox metalation reaction would be exothermic when occurring on a Ni(111) substrate with an energy gain of 0.89 eV upon embedding a Ni adatom in the macrocycle. This is a novel way to form, via chemical modification and supramolecular engineering, 3d-metal-organic networks on magnetic substrates with an intimate bond between the macrocycle molecular metal ion and the substrate atoms. The achievement of a complete metalation by Fe and Ni can be regarded as a test case for successful preparation of spintronic devices by means of molecular-based magnets and inorganic magnetic substrates.

Published

2012

24. Changes of the molecule-substrate interaction upon metal inclusion into a porphyrin.

Author

Di Santo G, Sfiligoj C, Castellarin-Cudia C, Verdini A, Cossaro A, Morgante A, Floreano L, and Goldoni A

Abstract

Metal-dependent conformations: a change in the adaptation of tetraphenylporphyrins (TPPs) on Ag(111) was observed in the presence of a metal ion in the macrocycle. Upon annealing at T>575 K, 2H-TPP molecules increase the overlap of the phenyl π orbitals with the substrate, thus reducing the distance. The presence of Co creates a strong bond between Co dz(2) and the Ag sp states, leaving the porphyrin macrocycle at a larger distance to the surface., (Copyright © 2012 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2012

25. FM-AFM constant height imaging and force curves: high resolution study of DNA-tip interactions.

Author

Cerreta A, Vobornik D, Di Santo G, Tobenas S, Alonso-Sarduy L, Adamcik J, and Dietler G

Subjects

Bacteriophage phi X 174 genetics, Base Sequence, Biomechanical Phenomena, DNA, Bacterial ultrastructure, DNA, Viral ultrastructure, Nucleic Acid Conformation, Plasmids chemistry, DNA, Bacterial chemistry, DNA, Viral chemistry, Microscopy, Atomic Force

Abstract

Interaction of the atomic force microscopy (AFM) tip with the sample can be invasive for soft samples. Frequency Modulation (FM) AFM is gentler because it allows scanning in the non-contact regime where only attractive forces exist between the tip and the sample, and there is no sample compression. Recently, FM-AFM was used to resolve the atomic structure of single molecules of pentacene and of carbon nanotubes. We are testing similar FM-AFM-based approaches to study biological samples. We present FM-AFM experiments on dsDNA deposited on 3-aminopropyltriethoxysilane modified mica in ultra high vacuum. With flexible samples such as DNA, the substrate flatness is a sub-molecular resolution limiting factor. Non-contact topographic images of DNA show variations that have the periodicity of the right handed helix of B-form DNA - this is an unexpected result as dehydrated DNA is thought to assume the A-form structure. Frequency shift maps at constant height allow working in the non-monotonic frequency shift range, show a rich contrast that changes significantly with the tip-sample separation, and show 0.2 to 0.4 nm size details on DNA. Frequency shift versus distance curves acquired on DNA molecules and converted in force curves show that for small molecules (height < 2.5 nm), there is a contribution to the interaction force from the substrate when the tip is on top of the molecules. Our data shine a new light on dehydrated and adsorbed DNA behavior. They show a longer tip-sample interaction distance. These experiments may have an impact on nanotechnological DNA applications in non-physiological environments such as DNA based nanoelectronics and nanotemplating., (Copyright © 2012 John Wiley & Sons, Ltd.)

Published

2012

26. Supramolecular engineering through temperature-induced chemical modification of 2H-tetraphenylporphyrin on Ag(111): flat phenyl conformation and possible dehydrogenation reactions.

Author

Di Santo G, Blankenburg S, Castellarin-Cudia C, Fanetti M, Borghetti P, Sangaletti L, Floreano L, Verdini A, Magnano E, Bondino F, Pignedoli CA, Nguyen MT, Gaspari R, Passerone D, and Goldoni A

Abstract

Scratching the surface: Formation of a monolayer of 2H-tetraphenylporphyrins (2H-TPP) on Ag(111), either by sublimation of a multilayer in the range 525-600 K or by annealing (at the same temperature) a monolayer deposited at room temperature, induces a chemical modification of the molecules. Rotation of the phenyl rings into a flat conformation is observed and tentatively explained, by using DFT calculations, as a peculiar reaction due to molecular dehydrogenation., (Copyright © 2011 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2011

27. Substrate influence for the Zn-tetraphenyl-porphyrin adsorption geometry and the interface-induced electron transfer.

Author

Castellarin-Cudia C, Borghetti P, Di Santo G, Fanetti M, Larciprete R, Cepek C, Vilmercati P, Sangaletti L, Verdini A, Cossaro A, Floreano L, Morgante A, and Goldoni A

Abstract

In molecular devices, the importance of interfaces cannot be neglected as they determine charge injection and charge flow and, therefore, the device performance. Herein we report on the interaction of one single layer of Zn-tetraphenyl-porphyrin with Ag(110) and Si(111). Photoemission, near-edge X-ray absorption, and resonant photoemission are used to study the bonding nature, the adsorption geometry as well as the dynamics of electron transfer between the molecules and the metal or semiconductor surfaces. Molecule-substrate charge transfer is driven by the overlap with the molecular pi orbitals. In particular, the coupling of the phenyl legs with the substrate and the relative excited charge injection are dramatically different for the two surfaces considered.

Published

2010

28. Temperature-controlled assembly of high ordered/disordered dodecylamine layers on HOPG: consequences for DNA patterning.

Author

Adamcik J, Tobenas S, Di Santo G, Klinov D, and Dietler G

Subjects

Adsorption, Crystallization, Electrochemistry methods, Ethanol chemistry, Microscopy, Atomic Force methods, Molecular Conformation, Molecular Structure, Oxygen chemistry, Silicon, Surface Properties, Temperature, Time Factors, Amines chemistry, DNA chemistry, Graphite chemistry

Abstract

It is shown that temperature-controlled ordered layers of dodecylamine, self-assembled on highly oriented pyrolytic graphite (HOPG), are an appropriate substrate for aligning individual DNA molecules. High resolution atomic force microscopy (AFM) permits visualization of the lamellar structure of dodecylamine on HOPG. The DNA adsorbed on ordered dodecylamine layers is stretched and oriented along the lamellae, while DNA on disordered dodecylamine layers is found to be in a random conformation. Small DNA bubbles appear in the case of partially denaturated linear double stranded DNA (dsDNA) adsorbed on ordered layers of dodecylamine.

Published

2009

29. Cathodic electrografting of versatile ligands on Si(100) as a low-impact approach for establishing a Si--C bond: a surface-coordination study of substituted 2,2'-bipyridines with CuI ions.

Author

Aurora A, Cattaruzza F, Coluzza C, Della Volpe C, Di Santo G, Flamini A, Mangano C, Morpurgo S, Pallavicini P, and Zanoni R

Abstract

Three distinct wet chemistry recipes were applied to hydrogen-terminated n- and p-Si(100) surfaces in a comparative study of the covalent grafting of two differently substituted 2,2'-bipyridines. The applied reactions require the use of heat, or visible light under a controlled atmosphere, or a suitable potential in an electrochemical cell. In this last case, hydrogen-terminated silicon is the working electrode in a cathodic electrografting (CEG) reaction, in which it is kept under reduction conditions. The resulting Si--C bound hybrids were characterized by a combination of AFM, dynamic contact-angle, and XPS analysis, with the help of theoretical calculations. The three distinct approaches were found to be suitable for obtaining ligand-functionalized Si surfaces. CEG resulted in the most satisfactory anchoring procedure, because of its better correlation between high coverage and preservation of the Si surface from both oxidation and contamination. The corresponding Si-bipyridine hybrid was reacted in a solution of CH3CN containing CuI ions coordinatively bound to the anchored ligands, as evidenced from the XPS binding-energy shift of the N atom donor functions. The reaction gave a 1:2 Cu-bipyridine surface complex, in which two ligands couple to a single CuI ion. The surface complex was characterized by the Cu Auger parameter and Cu/N XPS atomic-ratio values coincident with those for pure, unsupported CuI complex with the same 2,2'-bipyridine. Further support for such a specific metal-ligand interaction at the functionalized Si surface came from the distinct values of Cu2p binding energy and the Cu Auger parameter, which were obtained for the species resulting from CuI ion uptake on hydrogen-terminated Si(100).

Published

2007