Your search keyword '"Samuele Fanetti"' showing total 34 results

1. Addressing Open Issues about the Structural Evolution of Methane Clathrate Hydrate

Author

Samuele Fanetti, Matteo Ceppatelli, Selene Berni, ROBERTO BINI, and DEMETRIO SCELTA

Subjects

General Energy, Physical and Theoretical Chemistry, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Published

2022

2. Complexities in the structural evolution with pressure of water–ammonia mixtures

Author

Selene Berni, Demetrio Scelta, Samuele Fanetti, and Roberto Bini

Subjects

General Physics and Astronomy, Physical and Theoretical Chemistry

Abstract

The structural evolution with pressure of icy mixtures of simple molecules is a poorly explored field despite the fundamental role they play in setting the properties of the crustal icy layer of the outer planets and of their satellites. Water and ammonia are the two major components of these mixtures, and the crystal properties of the two pure systems and of their compounds have been studied at high pressures in a certain detail. On the contrary, the study of their heterogeneous crystalline mixtures whose properties, due to the strong N–H⋯O and O–H⋯N hydrogen bonds, can be substantially altered with respect to the individual species has so far been overlooked. In this work, we performed a comparative Raman study with a high spatial resolution of the lattice phonon spectrum of both pure ammonia and water–ammonia mixtures in a pressure range of great interest for modeling the properties of icy planets’ interiors. Lattice phonon spectra represent the spectroscopic signature of the molecular crystals’ structure. The activation of a phonon mode in plastic NH3-III attests to a progressive reduction in the orientational disorder, which corresponds to a site symmetry reduction. This spectroscopic hallmark allowed us to solve the pressure evolution of H2O–NH3–AHH (ammonia hemihydrate) solid mixtures, which present a remarkably different behavior from the pure crystals likely to be ascribed to the role of the strong H-bonds between water and ammonia molecules characterizing the crystallites’ surface.

Published

2023

3. Quasi-isotropic high pressure, large volume synthesis of a polymeric composite incorporating diamond-like carbon nano-threads

Author

Samuele Fanetti, Sebastiano Romi, Wilson Crichton, Anja Rosenthal, Demetrio Scelta, Frederico Alabarse, Roberto Bini, and Mario Santoro

Subjects

Mechanical Engineering, Materials Chemistry, General Chemistry, Electrical and Electronic Engineering, Electronic, Optical and Magnetic Materials

Published

2023

4. Synthesis of double core chromophore-functionalized nanothreads by compressing azobenzene in a diamond anvil cell

Author

Roberto Bini, Samuele Fanetti, Frederico G. Alabarse, Antonio M. Mio, and Sebastiano Romi

Subjects

Azobenzene, Carbon, Chromophores, Crystal atomic structure, Crystals, Electronic properties, High pressure engineering, high-pressure, ultrahard materials, diamond wires, Materials science, Heteroatom, chemistry.chemical_element, Nanotechnology, General Chemistry, Chromophore, Characterization (materials science), Crystal, Chemistry, chemistry.chemical_compound, Monomer, chemistry, Molecule

Abstract

Carbon nanothreads are likely the most attracting new materials produced under high pressure conditions. Their synthesis is achieved by compressing crystals of different small aromatic molecules, while also exploiting the applied anisotropic stress to favor nontopochemical paths. The threads are nanometric hollow structures of saturated carbon atoms, reminiscent of the starting aromatic molecule, gathered in micron sized bundles. The examples collected so far suggest that their formation can be a general phenomenon, thus enabling the design of functionalities and properties by suitably choosing the starting monomer on the basis of its chemical properties and crystal arrangement. The presence of heteroatoms or unsaturation within the thread is appealing for improving the processability and tuning the electronic properties. Suitable simple chromophores can fulfill these requirements and their controlled insertion along the thread would represent a considerable step forward in tailoring the optical and electronic properties of these mechanically extraordinary materials. Here, we report the synthesis and extensive characterization of double core nanothreads linked by azo groups. This is achieved by compressing azobenzene in a diamond anvil cell, the archetype of a wide class of dyes, and represents a fundamental step in the realization of nanothreads with tailored photochemical and photophysical properties., One-step high-pressure synthesis of 2D crystalline double nanothreads linked by azo groups.

Published

2021

5. Growth Dynamics of Crystalline Ar Hydrate

Author

Roberto Bini, Samuele Fanetti, and Demetrio Scelta

Subjects

Sapphire, Materials science, Clathrate hydrate, Hydration, macromolecular substances, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Diamond anvil cell, Dynamics, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Crystal, General Energy, Chemical physics, Physical and Theoretical Chemistry, 0210 nano-technology, Hydrate

Abstract

The formation of a clathrate hydrate crystal is characterized by several steps, each of them distinguished by a different structural arrangement and temporal duration. A precise definition of these different forms is a challenging task, because the entirety of the formation dynamics spans over a time interval ranging from few nanoseconds to several days. Computational methods are powerful and essential to define the nucleation step, but they fail in providing a reliable picture of the long-range order establishment. On the other side, the experimental methods employed in the study of the growth dynamics usually monitor the hydrate growth at the interface with the fluid and thus are limited by the diffusion of the guest molecules through the newly formed hydrate phase. This problem is overcome here by the confinement of an argon hydrate sample in a sapphire anvil cell, allowing monitoring of the melting and crystallization of hydrates under moderate pressures by FTIR and Raman spectroscopies. This approach, besides providing a spectroscopic characterization of this hydrate, allowed the time windows characteristic of the formation of a macroscopic amorphous phase to be identified, possibly coincident with the so-called blob, and its rapid evolution toward the achievement of the local structure. Long-range ordering takes place on a longer time scale, most of it is realized in few hours but still evolving for weeks. No hints for supporting the so-called memory effect are gained through this study.

Published

2020

6. Pressure induced modification of the electronic properties of stilbene by two-photon spectroscopy

Author

Samuele Fanetti, Milo Agati, and ROBERTO BINI

Subjects

General Physics and Astronomy, Physical and Theoretical Chemistry

Abstract

Carbon nanothreads are the most exciting carbon based nanomaterials recently discovered. Obtained by compressing aromatics around 20 GPa, they are characterized by potentially exceptional mechanical properties. The reaction mechanisms have been partly elucidated through computational studies and x-ray diffraction experiments. However, in all these studies, the electronic modifications to which the molecule is subjected with increasing pressure are neglected as also if, and to which extent, the electronic excited states are involved in the high-pressure reactivity. In fact, the pressure increase induces remarkable changes in the electronic properties of molecular crystals, which are often directly related to the reaction’s onset and path. We report the pressure evolution of the two-photon induced emission spectrum of crystalline stilbene, the archetype of a class of molecules from which double-core nanothreads are obtained, with the twofold purpose of gaining insight into the reaction mechanism and monitoring if the structural changes observed in x-ray diffraction studies have a detectable counterpart in the electronic properties of the system. The freezing of the spectral diffusion observed on rising pressure is ascribed to a hampered conformational rearrangement because of the larger stiffness of the local environment. The transition to the high pressure phase where the nanothreads form is revealed by the slope change of the pressure shift of all spectral components, while the progressive intensification with pressure of the 0-0 transition suggests a strengthening of the ethylenic bond favoring the charge delocalization on the benzene moieties, which is likely the trigger of the chemical instability.

Published

2023

7. Modulating the H-bond strength by varying the temperature for the high pressure synthesis of nitrogen rich carbon nanothreads

Author

Samuele Fanetti, Berretti Enrico, Mario Santoro, Roberto Bini, and Frederico G. Alabarse

Subjects

Materials science, Yield (engineering), Absorption spectroscopy, Hydrogen bond, Crystal structure, chemistry.chemical_element, Infrared spectroscopy, Molecules, Crystals, Carbon, High pressure engineering, Crystal, chemistry, Polymerization, Chemical physics, Molecule, General Materials Science

Abstract

Carbon nanothreads are among the most attractive new materials produced under high pressure conditions. Their synthesis can be achieved by compressing the crystals of aromatic molecules exploiting both the anisotropic stress produced by the unidirectional applied force and that intrinsic to the crystal arrangement. We explored here the transformation of pyridine into a nitrogen rich carbon nanothread crystal by varying the pressure and temperature conditions with the twofold purpose of disclosing the microscopic mechanism of transformation and optimizing the yield and quality of the produced crystalline nanothreads. The best conditions for the synthesis were identified in the 14-18 GPa range at temperatures between 400 and 500 K with a product yield greater than 30%. The comparison of experiments performed under different P-T conditions allowed us to understand the role of high temperature, which is necessary to weaken or even destroy the complex H-bond network characterizing the pyridine crystal and preventing the correct approach of the aromatic rings for nanothread formation. X-ray diffraction data confirm the excellent 2D hexagonal packing of the nanothreads over several tens of microns, whereas the sharp absorption lines observed in the IR spectrum strongly support a substantial order along the threads. Diffraction results suggest a polytwistane structure of the threads derived from a Diels-Alder [4 + 2] polymerization involving molecules arranged in a slipped parallel configuration along the pyridine crystal a and b axes. Electron microscopy evidences an arrangement of the nanothreads in bundles of tens of nanometers.

Published

2020

8. Structure and Reactivity of the Ionic Liquid 1-Allyl-3-methylimidazolium Iodide under High Pressure

Author

Marcelo M. Nobrega, Naomi Falsini, Roberto Bini, Samuele Fanetti, Luiz F. O. Faria, Mauro C. C. Ribeiro, and Marcia L. A. Temperini

Subjects

chemistry.chemical_classification, Materials science, 010304 chemical physics, Double bond, Iodide, LÍQUIDOS IÔNICOS, Polymer, 010402 general chemistry, 01 natural sciences, Chemical reaction, Diamond anvil cell, 0104 chemical sciences, Surfaces, Coatings and Films, Condensed Matter::Soft Condensed Matter, Crystal, chemistry.chemical_compound, chemistry, 0103 physical sciences, Ionic liquid, Materials Chemistry, Physical chemistry, Reactivity (chemistry), Physical and Theoretical Chemistry

Abstract

Poly(ionic liquid)s are an interesting class of compounds because of their unique chemical and physical properties gathering the characteristics of ionic liquids and polymers. Pressure and temperature have been demonstrated to be alternative parameters to obtain polymers from monomeric species using only physical tools. In this work, we investigate the reaction under high pressure and room temperature of the ionic liquid 1-allyl-3-methylimidazolium iodide by using the diamond anvil cell technique in combination with synchrotron X-ray diffraction and electronic and vibrational spectroscopies. The results indicate a chemical reaction happening through the terminal double bond of the allyl group both in crystalline and glassy phases with the onset of the reaction around ∼7 GPa. Vibrational spectra present evidence for an oligomerization reaction in both the phases. The reaction occurring both in glassy and crystal phases indicates a mechanism not driven by collective motions and likely related to local topological arrangements. The results presented herein extend our understanding of ionic liquid instability boundaries under high pressure and contribute to the development of alternative synthetic routes to achieve poly(ionic liquids).

Published

2019

9. Crystal Structure and Non-Hydrostatic Stress-Induced Phase Transition of Urotropine Under High Pressure

Author

Kamil Dziubek, Anna Olejniczak, Volodymyr Svitlyk, Piotr A. Guńka, Roberto Bini, Ines E. Collings, and Samuele Fanetti

Subjects

Diffraction, Phase transition, 010405 organic chemistry, Chemistry, Organic Chemistry, high-pressure chemistry, Thermodynamics, General Chemistry, Crystal structure, urotropine, 010402 general chemistry, 01 natural sciences, Catalysis, 0104 chemical sciences, Bond length, Tetragonal crystal system, Hirshfeld atom refinement, IR spectroscopy, Molecular vibration, Phase (matter), X-ray crystallography

Abstract

High-pressure behavior of hexamethylenetetramine (urotropine) was studied in situ using angle-dispersive single-crystal synchrotron X-ray diffraction (XRD) and Fourier-transform infrared absorption (FTIR) spectroscopy. Experiments were conducted in various pressure-transmitting media to study the effect of deviatoric stress on phase transformations. Up to 4 GPa significant damping of molecular librations and atomic thermal motion was observed. A first-order phase transition to a tetragonal structure was observed with an onset at approximately 12.5 GPa and characterized by sluggish kinetics and considerable hysteresis upon decompression. However, it occurs only in non-hydrostatic conditions, induced by deviatoric or uniaxial stress in the sample. This behavior finds analogies in similar cubic crystals built of highly symmetric cage-like molecules and may be considered a common feature of such systems. DFT computations were performed to model urotropine equation of state and pressure dependence of vibrational modes. The first successful Hirshfeld atom refinements carried out for high-pressure diffraction data are reported. The refinements yielded more realistic C-H bond lengths than the independent atom model even though the high-pressure diffraction data are incomplete.

Published

2020

10. Crystal structure and non-hydrostatic stress-induced phase transition of urotropine under high pressure

Author

Kamil F. Dziubek, Volodymyr Svitlyk, Ines E. Collings, Roberto Bini, Samuele Fanetti, Anna Olejniczak, and Piotr A. Guńka

Abstract

High-pressure behavior of hexamthyleneteramine (urotropine) was studied in situ using angle-dispersive single-crystal synchrotron X-ray diffraction (XRD) and Fourier transform infrared absorption (FTIR) spectroscopy. Experiments were conducted in various pressure transmitting media (helium and neon for XRD, nitrogen and KBr for FTIR experiments) to study the effect of deviatoric stress on phase transformations. Contrary to As4O6 arsenolite, a material of similar cage-like molecular structure, no pressure-induced helium penetration into the crystal structure was observed. Instead, two pressure-induced structural changes are observed. The first one is suggested by the following occurrences: (i) gradual quenching of the magnitudes of atomic displacement parameters, (ii) diminishing libration contribution to the experimental C−N bond length, (iii) discontinuity in calculated IR-active vibrational modes and (iv) asymptotically vanishing discrepancy between the experimental and DFT‑calculated unit cell volume. All these features reach a plateau at ~4 GPa and can be attributed to a damping of molecular librations and atomic thermal motion, pointing to the existence of a second-order isostructural phase transition. The second transformation, with an onset at ~12.5 GPa is a first-order phase transition to a tetragonal structure, characterized by sluggish kinetics and considerable hysteresis upon decompression. However, it occurs only in non-hydrostatic conditions, induced by a deviatoric stress in the sample. This behavior finds analogies in similar cubic crystals built of highly symmetric cage-like molecules and may be considered a common feature of such systems. Last but not least, it is worth noting successful Hirshfeld atom refinements, carried out for the incomplete high-pressure diffraction data up to 14 GPa, yielded more realistic C−H bond lengths than the independent atom model.

Published

2020

11. Crystal structure and non-hydrostatic stress-induced phase transition of urotropine under high pressure

Author

Samuele Fanetti, Ines E. Collings, Volodymyr Svitlyk, Anna Olejniczak, Piotr A. Guńka, Roberto Bini, and Kamil Dziubek

Subjects

Bond length, Phase transition, Tetragonal crystal system, Materials science, Molecular vibration, Phase (matter), Atom, Thermodynamics, Crystal structure, Spectroscopy

Abstract

High-pressure behavior of hexamthyleneteramine (urotropine) was studied in situ using angle-dispersive single-crystal synchrotron X-ray diffraction (XRD) and Fourier transform infrared absorption (FTIR) spectroscopy. Experiments were conducted in various pressure transmitting media (helium and neon for XRD, nitrogen and KBr for FTIR experiments) to study the effect of deviatoric stress on phase transformations. Contrary to As4O6 arsenolite, a material of similar cage-like molecular structure, no pressure-induced helium penetration into the crystal structure was observed. Instead, two pressure-induced structural changes are observed. The first one is suggested by the following occurrences: (i) gradual quenching of the magnitudes of atomic displacement parameters, (ii) diminishing libration contribution to the experimental C−N bond length, (iii) discontinuity in calculated IR-active vibrational modes and (iv) asymptotically vanishing discrepancy between the experimental and DFT‑calculated unit cell volume. All these features reach a plateau at ~4 GPa and can be attributed to a damping of molecular librations and atomic thermal motion, pointing to the existence of a second-order isostructural phase transition. The second transformation, with an onset at ~12.5 GPa is a first-order phase transition to a tetragonal structure, characterized by sluggish kinetics and considerable hysteresis upon decompression. However, it occurs only in non-hydrostatic conditions, induced by a deviatoric stress in the sample. This behavior finds analogies in similar cubic crystals built of highly symmetric cage-like molecules and may be considered a common feature of such systems. Last but not least, it is worth noting successful Hirshfeld atom refinements, carried out for the incomplete high-pressure diffraction data up to 14 GPa, yielded more realistic C−H bond lengths than the independent atom model.

Published

2020

12. Crystal Structure of Urotropine Under High Pressure and Non-Hydrostatic Stress-Induced Phase Transitions in Cage Compounds

Author

Piotr Gunka, Anna Olejniczak, Samuele Fanetti, Roberto Bini, Ines E. Collings, Volodymyr Svitlyk, and Kamil F. Dziubek

Abstract

High-pressure behavior of hexamthyleneteramine (urotropine) was studied in situ using angle-dispersive single-crystal synchrotron X-ray diffraction (XRD) and Fourier transform infrared absorption (FTIR) spectroscopy. Experiments were conducted in various pressure transmitting media (helium and neon for XRD, nitrogen and KBr for FTIR experiments) to study the effect of deviatoric stress on phase transformations. Contrary to As4O6 arsenolite, a material of similar cage-like molecular structure, no pressure-induced helium penetration into the crystal structure was observed. Instead, two pressure-induced structural changes are observed. The first one is suggested by the following occurrences: (i) gradual quenching of the magnitudes of atomic displacement parameters, (ii) diminishing libration contribution to the experimental C−N bond length, (iii) discontinuity in calculated IR-active vibrational modes and (iv) asymptotically vanishing discrepancy between the experimental and DFT‑calculated unit cell volume. All these features reach a plateau at ~4 GPa and can be attributed to a damping of molecular librations and atomic thermal motion, pointing to the existence of a second-order isostructural phase transition. The second transformation, with an onset at ~12.5 GPa is a first-order phase transition to a tetragonal structure, characterized by sluggish kinetics and considerable hysteresis upon decompression. However, it occurs only in non-hydrostatic conditions, induced by a deviatoric stress in the sample. This behavior finds analogies in similar cubic crystals built of highly symmetric cage-like molecules and may be considered a common feature of such systems. Last but not least, it is worth noting successful Hirshfeld atom refinements, carried out for the incomplete high-pressure diffraction data up to 14 GPa, yielded more realistic C−H bond lengths than the independent atom model.

Published

2020

13. Effect of Structural Anisotropy in High-Pressure Reaction of Aniline

Author

Roberto Bini, Erico Teixeira-Neto, Marcelo M. Nobrega, Samuele Fanetti, and Marcia L. A. Temperini

Subjects

Materials science, CINÉTICA, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Crystal, chemistry.chemical_compound, Crystallography, General Energy, Aniline, chemistry, High pressure, Phase (matter), Molecule, Reactivity (chemistry), sense organs, Physical and Theoretical Chemistry, 0210 nano-technology, Anisotropy

Abstract

The pressure-induced reactivity of aromatic molecules in the crystal phase has been recently demonstrated to be a practicable route for the synthesis of crystalline nanothreads. The formation of th...

Published

2018

14. Topochemical Polymerization of Phenylacetylene Macrocycles under Pressure

Author

Samuele Fanetti, Jean-François Morin, Simon Rondeau-Gagné, Charles-Olivier Gilbert, Roberto Bini, Margherita Citroni, and Andrea Lapini

Subjects

chemistry.chemical_classification, Materials science, 010405 organic chemistry, Alkyne, 010402 general chemistry, Photochemistry, 01 natural sciences, Diamond anvil cell, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, General Energy, Polymerization, Phenylacetylene, chemistry, Covalent bond, Physical and Theoretical Chemistry, Absorption (chemistry), Ambient pressure, Visible spectrum

Abstract

Self-assembly of organic macrocycles has been exploited as a preliminary step in the synthesis of soluble and tailorable carbon-based nanostructures. Functionalized nanotubes have been prepared using, as core building blocks, nearly planar ring structures containing several alkyne units, exploiting the geometry achieved in the spontaneous preassembling step driven by π interaction. Covalent cross-linking between these units was achieved by thermal or photochemical activation with UV light. Here, we apply a moderate pressure in a sapphire anvil cell (1.0 GPa) to facilitate the preassembling and induce the cross-linking under pressure either with visible light, absorbed by two-photon absorption, or thermally. We observe a high yield of enhanced quality cross-linked nanotubes in a sample, showing, at ambient pressure, only side-chain decomposition. These results show that moderate pressures, easily achievable in large volume cells, are able to selectively favor topochemical reactions in such complex organic ...

Published

2018

15. The Photochemistry of Crystalline Nitromethane under Static Pressure

Author

Margherita Citroni, Roberto Bini, Naomi Falsini, and Samuele Fanetti

Subjects

Reaction mechanism, Materials science, Nitromethane, Absorption spectroscopy, Analytical chemistry, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, General Energy, chemistry, Absorption edge, Reactivity (chemistry), Irradiation, Physical and Theoretical Chemistry, Fourier transform infrared spectroscopy, 0210 nano-technology, Excitation

Abstract

The high-pressure chemical reactivity of nitromethane, under irradiation with visible and near-UV laser light, was investigated by in situ FTIR spectroscopy in a diamond anvil cell. The reactivity was probed at different pressures (0.2, 1.2, 5.0, 15.3, and 28.0 GPa) with different excitation wavelengths (514, 458, and 350 nm), with all absorbed through a two-photon process. Insight into the reaction mechanism was gained by measuring the near-UV absorption spectrum of nitromethane as a function of pressure to 32 GPa, the threshold pressure above which it reacts spontaneously in the absence of electronic excitation. We were thus able to determine the pressure evolution of the two lowest-energy transitions (σ → π* and a singlet–triplet transition). The information obtained from the absorption spectra together with the reactivity data allowed us to locate the red absorption edge of the higher-energy π → π* transition and its pressure shift. The excitation of the σ → π* transition was not able to induce any ph...

Published

2018

16. Structural and Electronic Competing Mechanisms in the Formation of Amorphous Carbon Nitride by Compressing s-Triazine

Author

Samuele Fanetti, Kamil Dziubek, Marco Pagliai, Mohamed Mezouar, Roberto Bini, Margherita Citroni, Carla Bazzicalupi, and Marcelo M. Nobrega

Subjects

Hydrogen, Chemistry, chemistry.chemical_element, Nanotechnology, Crystal structure, Nitride, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Amorphous solid, chemistry.chemical_compound, General Energy, Amorphous carbon, Chemical physics, Phase (matter), Reactivity (chemistry), Physical and Theoretical Chemistry, Carbon nitride

Abstract

The pressure-induced transformation of molecular crystals can give rise to new materials characterized by intriguing hardness or energetic properties. Mechanisms regulating these reactions at the molecular level result from a complex interplay among crystal structure, lattice dynamics, and electronic properties. Here, we show that the formation of a three-dimensional amorphous carbon nitride by compressing phase II s-triazine is controlled by the competition between two different mechanisms, one entirely structural and the other electronic, representing the first example where such occurrence is demonstrated. Temperature drives the reactivity below 8 GPa by ruling the lattice dynamics, whereas above 8 GPa the electronic modifications, uniquely governed by pressure, trigger the chemical transformation. The amorphous material synthesized has a bonding structure characterized by a bulk typical of a strongly conjugated three-dimensional carbon nitride with hydrogen atoms migrated to saturate C and N terminations.

Published

2015

17. First result on biased CMOS MAPs-on-diamond devices

Author

Stefano Lagomarsino, Margherita Citroni, Giuliano Parrini, Silvio Sciortino, L. Servoli, Keida Kanxheri, Arianna Morozzi, Samuele Fanetti, and Daniele Passeri

Subjects

Physics, Nuclear and High Energy Physics, CMOS sensor, Pixel, business.industry, Diamond, Biasing, engineering.material, Laser, Signal, Photodiode, law.invention, Diamond substrates, CMOS, law, Charged particle detection, Diamond detectors, Diamond substrates, Charged particle detection, engineering, Optoelectronics, business, Diamond detectors, Instrumentation

Abstract

Recently a new type of device, the MAPS-on-diamond, obtained bonding a thinned to 25 μm CMOS Monolithic Active Pixel Sensor to a standard 500 μm pCVD diamond substrate, has been proposed and fabricated, allowing a highly segmented readout (10×10 μm pixel size) of the signal produced in the diamond substrate. The bonding between the two materials has been obtained using a new laser technique to deliver the needed energy at the interface. A biasing scheme has been adopted to polarize the diamond substrate to allow the charge transport inside the diamond without disrupting the functionalities of the CMOS Monolithic Active Pixel Sensor. The main concept of this class of devices is the capability of the charges generated in the diamond by ionizing radiation to cross the silicon–diamond interface and to be collected by the MAPS photodiodes. In this work we demonstrate that such passage occurs and measure its overall efficiency. This study has been carried out first calibrating the CMOS MAPS with monochromatic X-rays, and then testing the device with charged particles (electrons) either with and without biasing the diamond substrate, to compare the amount of signal collected.

Published

2015

18. Tuning the Aromaticity of s-Triazine in the Crystal Phase by Pressure

Author

Margherita Citroni, Roberto Bini, and Samuele Fanetti

Subjects

Materials science, Aromaticity, Molecular physics, Diamond anvil cell, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Crystal, General Energy, Excited state, Phase (matter), Reactivity (chemistry), Emission spectrum, Physical and Theoretical Chemistry, Excitation

Abstract

The effect of pressure on the electronic properties of crystalline s-triazine has been studied up to 14 GPa by using two-photon induced fluorescence. Emission and excitation spectra have been measured as a function of pressure on samples compressed in a diamond anvil cell. The different two-photon absorption cross sections to the nπ* and ππ* excited states account for the selectivity in the excitation wavelength observed in the high pressure photoinduced reactivity. The comparison between excitation and emission spectra highlights a remarkable red shift with rising pressure of the higher electronic excited states having ππ* character, which contrasts with the pressure insensitivity of the lowest nπ* states. Pressure is therefore extremely efficient at progressively destabilizing the π bonding orbitals, causing a reduction of the ring aromaticity, and driving the high pressure reactivity.

Published

2014

19. Pressure and Laser-Induced Reactivity in Crystalline s-Triazine

Author

Margherita Citroni, Roberto Bini, and Samuele Fanetti

Subjects

Materials science, chemistry.chemical_element, Photochemistry, Laser, Nitrogen, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, General Energy, chemistry, Amorphous carbon, law, High pressure, Reactivity (chemistry), Physical and Theoretical Chemistry, Fourier transform infrared spectroscopy, Triazine

Abstract

The high-pressure transformation of s-triazine to an extended amorphous carbon incorporating a large amount of nitrogen has been studied by Fourier transform infrared spectroscopy. The reaction, oc...

Published

2014

20. Towards one-pot green synthesis of nanoporous carbon nitrides

Author

Michael Hanfland, Marcelo M. Nobrega, Roberto Bini, Margherita Citroni, Andrea Sella, Paul F. McMillan, Kamil Dziubek, and Samuele Fanetti

Subjects

Inorganic Chemistry, Materials science, Chemical engineering, Structural Biology, Nanoporous carbon, General Materials Science, Physical and Theoretical Chemistry, Nitride, Condensed Matter Physics, Biochemistry

Published

2019

21. Crystal structure compression and pressure-induced polymerization of arene-perfluoroarene co-crystals leading to columnar hydrofluorocarbons

Author

Todd B. Marder, Stewart J. Clark, Julio Pellicer-Porres, Roberto Bini, Alexandra Friedrich, Michael Hanfland, Daniel Sieh, Ines E. Collings, Kamil Dziubek, Samuele Fanetti, Javier Ruiz-Fuertes, and Krzysztof Radacki

Subjects

Inorganic Chemistry, Crystallography, Materials science, Polymerization, Structural Biology, General Materials Science, Crystal structure, Physical and Theoretical Chemistry, Condensed Matter Physics, Compression (physics), Biochemistry

Published

2019

22. Electrical properties of laser-bonded Silicon-On-Diamond samples

Author

Emanuele Pace, A. De Sio, L. Servoli, L. Tozzetti, Stefano Lagomarsino, Andrea Scorzoni, Silvio Sciortino, Daniele Passeri, Fernando Brandi, Margherita Citroni, Riccardo Carzino, G. Parrini, and Samuele Fanetti

Subjects

Nuclear and High Energy Physics, Silicon, Laser bonding, Diamond detectors, Silicon-On-Diamond, Charge collection efficiency, Hybrid silicon laser, chemistry.chemical_element, Nanotechnology, engineering.material, law.invention, law, Instrumentation, Ohmic contact, Physics, business.industry, Diamond, Laser, Semiconductor detector, chemistry, engineering, Optoelectronics, business, Laser drilling

Abstract

In this work we report preliminary tests aimed at the implementation of a Silicon-On-Diamond (SOD) radiation sensor. SOD materials have been prepared by continuously scanning a 20 ps pulsed 355 nm laser beam on the silicon–diamond interface. A pixel monolithic sensor has also been bonded to diamond with the same technique and tested to show that a complex electronic chip can undergo the process without any damage. Through silicon vias have been fabricated by laser drilling on the silicon side of the SOD samples and their insulation from the silicon bulk has been tested. The charge collection efficiency of a diamond sensor with laser-written graphitic contacts has been measured, to demonstrate a reliable and simple way to fabricate ohmic contacts on the diamond side of the SOD devices. Finally, a SOD material with electric contacts on the silicon and on the diamond sides has been tested as a particle sensor to demonstrate the electrical continuity of the silicon–diamond interface after the bonding.

Published

2013

23. Photoinduced Reactivity of Red Phosphorus and Ethanol at High Pressure

Author

Samuele Fanetti, Roberto Bini, and Matteo Ceppatelli

Subjects

Ethanol, Ethylene, Inorganic chemistry, Photochemistry, Chemical reaction, Dissociation (chemistry), Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, symbols.namesake, General Energy, chemistry, Alkoxy group, symbols, Physical and Theoretical Chemistry, Diethyl ether, Raman spectroscopy, Phosphine

Abstract

Dissociation of ethanol by two-photon absorption of UVML laser emission centered at 350 nm was employed to trigger a chemical reaction at ambient temperature with red phosphorus for pressures ranging between 0.2 and 1.5 GPa. The reaction products, identified by infrared and Raman spectroscopy, indicate a quite selective reactivity ascribable to the two main dissociation channels involving the splitting of the O-H and C-O bonds of ethanol. The ethoxy radical, obtained through the splitting of the O-H bond, has been identified as the main responsible for the phosphorus reactivity, giving rise to triethylphosphate. The same dissociation channel is also responsible for the formation of a consistent amount of molecular hydrogen, phosphine, and diethyl ether, whereas ethane and ethylene, the latter observed only in traces, likely derive from the C-O dissociation. The reaction is accelerated by increasing pressure from 0.2 to 0.6 GPa but is not favored, as also observed in pure ethanol, by a further pressure increase. The reaction proceeds until ethanol is completely consumed, and further irradiation determines the decomposition of the products, especially of diethyl ether, leading to the formation of CO2, methane, and ethane.

Published

2013

24. High-Pressure Optical Properties and Chemical Stability of Picene

Author

Lorenzo Malavasi, Gianluca A. Artioli, Samuele Fanetti, Margherita Citroni, Roberto Bini, and Paolo Postorino

Subjects

Absorption spectroscopy, Chemistry, Band gap, Doping, Molecular physics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry.chemical_compound, General Energy, Picene, Atomic electron transition, Excited state, Physical and Theoretical Chemistry, Atomic physics, Ground state, Excitation

Abstract

Picene is a polycyclic aromatic hydrocarbon belonging to the class of phenacenes which have been recently found to behave as high-temperature superconductors upon alkali metal doping. The electronic properties of organic crystals can be finely and largely modified by the density changes obtained by the application of an external pressure. In this work, the role of pressure in tuning the optical properties of crystalline picene has been investigated from room conditions up to 15 GPa through the measurement of UV-visible absorption spectra, two-photon excitation profiles, and one- and two-photon excited fluorescence spectra in a diamond anvil cell. The pressure dependence of the optical band gap was determined, and the frequencies of several vibronic bands belonging to electronic transitions from the ground state (S-0) to the four lowest-energy excited singlet states (S-1 to S-4) were determined as a function of pressure. We evidence a very different density dependence of the transition energy of S-0 -> S-1, which undergoes a remarkable red shift of similar to 400 cm(-1)/GPa, and of the transitions from S-0 to the higher excited states, which remain constant in the whole investigated range. This is consistent with a S-1 state of L-1(a) character in solid picene. The high-pressure chemical stability of solid picene was investigated through visible absorption and Fourier transform infrared spectroscopy (FTIR). A chemical transformation involving the bulk picene crystal occurs above similar to 23 GPa, giving rise to a disordered material similar to the amorphous hydrogenated carbon obtained in the pressure-induced reactivity of benzene. The combination of electronic and vibrational data allows us to identify the presence of reaction intermediates at similar to 10 GPa, preferentially forming at crystal defects.

Published

2013

25. Pressure-Induced Fluorescence of Pyridine

Author

Margherita Citroni, Samuele Fanetti, and Roberto Bini

Subjects

Intermolecular force, Analytical chemistry, Excimer, Fluorescence, Surfaces, Coatings and Films, Crystal, chemistry.chemical_compound, chemistry, Excited state, Pyridine, Materials Chemistry, Physical and Theoretical Chemistry, Lone pair, Excitation

Abstract

Two-photon excitation profiles and fluorescence spectra have been measured as a function of pressure in a diamond anvil cell up to 15.5 GPa in crystal phases I and II and in the glassy form of pyridine. The fluorescence emission intensity increases by about 6 orders of magnitude in going from the liquid to the crystalline phases at 3 GPa and further increases with pressure. This is explained by an energy inversion of the lowest (1)B(1) (nπ*) and (1)B(2) (ππ*) excited states likely due to the involvement of the lone pair of the N atom in intermolecular CH···N bonds. These interactions characterize the crystal phases and are stabilized by pressure. The glassy form, accordingly, is characterized by a much weaker fluorescence. Excimer emission is also observed. Comparison of the emission of several samples with different compression and annealing histories, the lack of reversibility in the excimer emission with decompression, and the larger relative intensity of the excimer band in the glassy form suggest that excimer formation occurs at crystal defects. This results support the conclusions of a previous investigation proposing that pressure-induced reactivity of pyridine is limited to crystal defects and agrees with the present knowledge of the solid-state chemistry of aromatic crystals.

Published

2011

26. Connecting the Water Phase Diagram to the Metastable Domain: High-Pressure Studies in the Supercooled Regime

Author

Roberto Righini, Margherita Citroni, Samuele Fanetti, Marco Pagliai, Andrea Lapini, Roberto Bini, and Sandro Scandolo

Subjects

Molecular dynamics, Materials science, Metastability, Polyamorphism, Intermolecular force, Thermodynamics, Molecule, General Materials Science, Physical and Theoretical Chemistry, Supercooling, Phase diagram, Amorphous solid

Abstract

Pressure is extremely efficient to tune intermolecular interactions, allowing the study of the mechanisms regulating, at the molecular level, the structure and dynamics of condensed phases. Among the simplest molecules, water represents in many respects a mystery despite its primary role in ruling most of the biological, physical, and chemical processes occurring in nature. Here we report a careful characterization of the dynamic regime change associated with low-density and high-density forms of liquid water by measuring the line shape of the OD stretching mode of HOD in liquid water along different isotherms as a function of pressure. Remarkably, the high-pressure studies have been here extended down to 240 K, well inside the supercooled regime. Supported by molecular dynamics simulations, a correlation among amorphous and crystalline solids and the two different liquid water forms is attempted to provide a unified picture of the metastable and thermodynamic regimes of water.

Published

2015

27. Structure and Dynamics of Low-Density and High-Density Liquid Water at High Pressure

Author

Margherita Citroni, Mariangela Di Donato, Roberto Righini, Marco Pagliai, Roberto Bini, Andrea Lapini, Sandro Scandolo, and Samuele Fanetti

Subjects

Physics, Range (particle radiation), Hydrogen bond, Infrared spectroscopy, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Diamond anvil cell, 0104 chemical sciences, Molecular dynamics, 13. Climate action, Chemical physics, Tetrahedron, Molecule, Physical chemistry, General Materials Science, Physical and Theoretical Chemistry, 0210 nano-technology, Earth (classical element)

Abstract

Liquid water has a primary role in ruling life on Earth in a wide temperature and pressure range as well as a plethora of chemical, physical, geological, and environmental processes. Nevertheless, a full understanding of its dynamical and structural properties is still lacking. Water molecules are associated through hydrogen bonds, with the resulting extended network characterized by a local tetrahedral arrangement. Two different local structures of the liquid, called low-density (LDW) and high-density (HDW) water, have been identified to potentially affect many different chemical, biological, and physical processes. By combining diamond anvil cell technology, ultrafast pump-probe infrared spectroscopy, and classical molecular dynamics simulations, we show that the liquid structure and orientational dynamics are intimately connected, identifying the P-T range of the LDW and HDW regimes. The latter are defined in terms of the speeding up of the orientational dynamics, caused by the increasing probability of breaking and reforming the hydrogen bonds.

Published

2015

28. HP–HT behavior of urea, a precursor to photocatalytic materials

Author

Samuele Fanetti, Roberto Bini, Andrew B. Cairns, Kamil Dziubek, and Margherita Citroni

Subjects

Inorganic Chemistry, chemistry.chemical_compound, chemistry, Structural Biology, Urea, Photocatalysis, General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry, Nuclear chemistry

Published

2017

29. Melting dynamics of ices by time-resolved light scattering

Author

Paolo Foggi, Roberto Bini, Margherita Citroni, Naomi Falsini, and Samuele Fanetti

Subjects

Inorganic Chemistry, Materials science, Structural Biology, Dynamics (mechanics), General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry, Molecular physics, Light scattering

Published

2017

30. HOMO-LUMO transitions in solvated and crystalline picene

Author

Margherita Citroni, Lorenzo Malavasi, Roberto Bini, Samuele Fanetti, Gianluca A. Artioli, and Paolo Postorino

Subjects

Crystal, chemistry.chemical_compound, Picene, Chemistry, General Physics and Astronomy, Vibronic spectroscopy, Crystal structure, Physical and Theoretical Chemistry, Atomic physics, Absorption (chemistry), Fluorescence, HOMO/LUMO, Excitation

Abstract

The optical properties of picene at ambient conditions have been investigated through the measurement of UV/Vis absorption and fluorescence spectra and of excitation profiles, using one-and two-photon excitation, in solution and in the crystal phase. For solvated picene an assignment of the vibronic structure of the transitions to the four lowest-energy excited singlet states (S-1-S-4) has been obtained from the absorption data, and the vibronic structure of the fluorescence spectra has been assigned. The absorption and fluorescence spectra of the solid phase can be interpreted according to the single molecule analysis. Nevertheless, the strong increase of the optical density in the spectral region of the lowest HOMO-LUMO transitions and the frequency shift of absorption and fluorescence bands may be explained by a mixing of the states of adjacent molecules in the crystal. Moreover, peculiar emission features depending on the crystal dimensions (10(-1) to 10(2) mu m) are observed. (C) 2012 American Institute of Physics. [http://dx.doi.org/10.1063/1.4770265]

Published

2012

31. Changing the dissociative character of the lowest excited state of ethanol by pressure

Author

Margherita Citroni, Roberto Bini, Samuele Fanetti, and Matteo Ceppatelli

Subjects

Ethanol, Photochemistry, Chemical reaction, Dissociation (chemistry), Surfaces, Coatings and Films, Isotopomers, chemistry.chemical_compound, symbols.namesake, chemistry, Excited state, Materials Chemistry, symbols, Physical and Theoretical Chemistry, Fourier transform infrared spectroscopy, Raman spectroscopy, Excitation

Abstract

Syntheses based on physical methods, such as pressure and light, are extremely attractive to prepare novel materials from pure molecular systems in condensed phases. The structural and electronic modifications induced by selective optical excitation can trigger unexpected chemical reactions by exploiting the high density conditions realized at high pressure. The identification of the microscopic mechanisms regulating this reactivity, mandatory to design synthetic environments appealing for practical applications, requires a careful characterization of both structural and electronic properties as a function of pressure. Here, we report a spectroscopic study, by FTIR and Raman techniques, of the ambient temperature photoinduced reactivity of liquid C(2)H(5)OD up to 1 GPa. The results have been interpreted by comparison with those relative to the fully hydrogenated isotopomer. The dissociation along the O-H (D) coordinate is the primary reactive channel, but the different reactivity of the two isotopomers with rising pressure highlights a dramatic pressure effect on the energy surface of the first electronic excited state. Dissociation along the O-H (D) coordinate becomes the reaction rate-limiting step due to an increase with pressure of the binding character along this coordinate.

Published

2011

32. High pressure chemistry of red phosphorus by photo-activated simple molecules

Author

Samuele Fanetti, Maria Caporali, Roberto Bini, Maurizio Peruzzini, and Matteo Ceppatelli

Subjects

History, Hydrogen, Phosphorus, Inorganic chemistry, chemistry.chemical_element, Infrared spectroscopy, Chemical reaction, Computer Science Applications, Education, Catalysis, chemistry, Molecule, Reactivity (chemistry), Absorption (chemistry)

Abstract

High pressure (HP) is very effective in reducing intermolecular distances and inducing unexpected chemical reactions. In addition the photo-activation of the reactants in HP conditions can lead to very efficient and selective processes. The chemistry of phosphorus is currently based on the white molecular form. The red polymeric allotrope, despite more stable and much less toxic, has not attracted much attention so far. However, switching from the white to the red form would benefit any industrial procedure, especially from an environmental point of view. On the other side, water and ethanol are renewable, environmental friendly and largely available molecules, usable as reactants and photo-activators in HP conditions. Here we report a study on the HP photo-induced reactivity of red phosphorus with water and ethanol, showing the possibility of very efficient and selective processes, leading to molecular hydrogen and valuable phosphorus compounds. The reactions have been studied by means of FTIR and Raman spectroscopy and pressure has been generated using membrane Diamond (DAC) and Sapphire (SAC) anvil cells. HP reactivity has been activated by the two-photon absorption of near-UV wavelengths and occurred in total absence of solvents, catalysts and radical initiators, at room T and mild pressure conditions (0.2–1.5 GPa).

Published

2014

33. Characterization of Silicon-On-Diamond chip with ionizing radiation

Author

Riccardo Carzino, Silvio Sciortino, Giuliano Parrini, Stefano Lagomarsino, Daniele Passeri, Andrea Scorzoni, Leonello Servoli, Fernando Brandi, Margherita Citroni, and Samuele Fanetti

Subjects

Fabrication, Materials science, Silicon, business.industry, Diamond, chemistry.chemical_element, Electronic detector readout concepts, engineering.material, Laser, Chip, Particle tracking detectors, Radiation-hard detectors, Diamond Detectors, law.invention, CMOS, chemistry, law, engineering, Optoelectronics, Wafer, Laser bonding, business, Instrumentation, Mathematical Physics

Abstract

In this work we report on the characterization with ionizing radiation sources of a CMOS active pixel radiation sensor (RAPS03) thinned down to 40um and bonded to a slice of diamond to form a rugged Silicon-On-Diamond structure. The bonding process is based on an innovative laser technique which scans the silicon-diamond interface with a 20 ps pulsed 355 nm laser beam. The goal of the work is to demonstrate that the bonding procedure does not damage the CMOS devices, paving the way for a possible alternative to bump bonding procedures between diamond substrates and readout chips. To this purpose, the Silicon-On-Diamond device and a standard (e.g. un-thinned) RAPS03 sensor have been tested in parallel with and without ionizing radiation sources (photons, electrons) to compare their characteristics and to study their differences. The Silicon-On-Diamond device has shown to be fully functional and no differences have been found between the responses of the two sensors, within the statistical variations due to the CMOS fabrication process.

Published

2014

34. Structure and reactivity of pyridine crystal under pressure

Author

Roberto Bini, Samuele Fanetti, and Margherita Citroni

Subjects

Phase transition, Molecular Structure, Spectrophotometry, Infrared, Pyridines, Chemistry, General Physics and Astronomy, Infrared spectroscopy, Spectrum Analysis, Raman, Crystallographic defect, Diamond anvil cell, law.invention, Crystal, Crystallography, symbols.namesake, law, Metastability, Pressure, symbols, Physical and Theoretical Chemistry, Crystallization, Raman spectroscopy

Abstract

In this work we have performed an extensive high pressure study of the condensed phases of pyridine by Raman and IR spectroscopy. We have evidenced three different polymorphs, two crystalline, and one glassy and established the pressure conditions in which they exist as stable or metastable phases by several compression/decompression experiments both on annealed and not annealed samples. Crystallization and phase transitions are found to be kinetically driven. The vibrational spectra are extremely complex due to the low symmetry of the crystals, which implies a large number of crystal components. This complexity required a careful analysis of both IR and Raman data that led to the identification of 20 out of 21 external modes expected for phase II. We did not find any conclusive indication of phase transitions on compressing phase II thus indicating that phase II is likely the stable phase at the onset pressure of the chemical transformation of pyridine. The latter starts at 18 GPa and relevant differences from the well characterized benzene reaction suggest that it is likely driven by crystal defects.

Published

2011