The Interaction of C60 on Si(111) 7â€‰Ã—â€‰7 Studied by Supersonic Molecular Beams: Interplay between Precursor Kinetic Energy and Substrate Temperature in Surface Activated Processes

Aversa, Lucrezia; Taioli, Simone; Nardi, Marco Vittorio; Tatti, Roberta; Verucchi, Roberto; Iannotta, Salvatore

doi:10.3389/fmats.2015.00046

Cited by 5 publications

(5 citation statements)

References 29 publications

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“…Usually, the terms appearing in the total energy expression are parameterized to reproduce accurately high-level electronic structure calculations for several different bonding conditions. In this way, the transferability of these precalculated terms (the so-called Slater–Koster matrix elements) to different chemical environments and physical conditions as well as a considerable reduction (around 2 orders of magnitude) of the computational cost of this approach with respect to full DFT simulations , are generally obtained. Because of this substantial speed gain, DFTB can be used to simulate systems larger than those accessible by full DFT, to follow their dynamics for longer time scales, and to test how the tuning of the DFTB parameters affects the impact dynamics at an affordable computational cost.…”

Section: Methodsmentioning

confidence: 99%

“…From a methodological point of view, approaches beyond molecular dynamics (MD) based on classical force fields have not yet been widely used for studying the impact properties of 2D nanomaterials owing to their high computational cost with increasing size of the system. Notable exceptions have been reported in modeling analogous problems, in which intermediate kinetic energy regimes (around tens of eV) were used to achieve the epitaxial growth of silicon carbide − and graphene , via buckyball beams impacting on silicon or metallic substrates.…”

Section: Introductionmentioning

confidence: 99%

“…Notable exceptions have been reported in modeling analogous problems, in which intermediate kinetic energy regimes (around tens of eV) were used to achieve the epitaxial growth of silicon carbide [27][28][29] and graphene 30,31 via buckyball beams impacting on silicon or metallic substrates.…”

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confidence: 99%

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2D Material Armors Showing Superior Impact Strength of Few Layers

Signetti

Taioli

Pugno

2017

ACS Appl. Mater. Interfaces

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We study the ballistic properties of two-dimensional (2D) materials upon the hypervelocity impacts of C fullerene molecules combining ab initio density functional tight binding and finite element simulations. The critical penetration energy of monolayer membranes is determined using graphene and the 2D allotrope of boron nitride as case studies. Furthermore, the energy absorption scaling laws with a variable number of layers and interlayer spacing are investigated, for homogeneous or hybrid configurations (alternated stacking of graphene and boron nitride). At the nanolevel, a synergistic interaction between the layers emerges, not observed at the micro- and macro-scale for graphene armors. This size-scale transition in the impact behavior toward higher dimensional scales is rationalized in terms of scaling of the damaged volume and material strength. An optimal number of layers, between 5 and 10, emerges demonstrating that few-layered 2D material armors possess impact strength even higher than their monolayer counterparts. These results provide fundamental understanding for the design of ultralightweight multilayer armors using enhanced 2D material-based nanocomposites.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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2D Material Armors Showing Superior Impact Strength of Few Layers

Signetti

Taioli

Pugno

2017

ACS Appl. Mater. Interfaces

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“…For these scattering problems, it is customary to divide the space into left-hand, center, and right-hand regions, where the former and latter represent the “leads” and the central part is the “device”. Owing to the much lower computational cost of DFTB with respect to other ab initio methods, − larger supercells can be used to perform the calculation of charge transport properties. The device region is a 6 × 2 × 1 supercell, having 144 atoms, obtained by using the unit cell lattice vectors computed by Dolgonos et al and optimizing the atomic positions.…”

Section: Computational Methodsmentioning

confidence: 99%

Multiscale Investigation of Oxygen Vacancies in TiO₂ Anatase and Their Role in Memristor’s Behavior

Paris

Taioli

2016

J. Phys. Chem. C

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The structure, energetics, and transport properties of TiO2 anatase with different densities of oxygen vacancies are studied by computer simulations using a variety of techniques, ranging from first-principles to Monte Carlo methods, to span different time scales. This work is motivated by the recent development of memristive electronic devices, usually made of metal oxides in which arrays of defects control the resistance switching mechanism. Anatase, in particular, emerged as one of the most promising candidates for memristor design. However, the microscopic behavior of these multivacancy systems is not yet entirely understood. In this regard, electronic and transport properties of TiO2 anatase containing neutral and charged oxygen vacancies are investigated within density functional theory (DFT) by adding a Hubbard-like term to the generalized gradient approximation of the electron density (GGA+U). Calculated observables are the formation energy of oxygen defects, the cohesion energy of multivacancy systems, and the energy profiles of oxygen diffusion pathways, computed through the nudged-elastic band (NEB) approach. Furthermore, a kinetic Monte Carlo model (KMC) of the conductive channel formation in bulk anatase, based on the corresponding diffusion rates, is discussed. Finally, to demonstrate the relation between energetically stable structures and the conductive phase of memristors, we study electron transport within a tight-binding approximation to DFT, using the nonequilibrium Green’s function (NEGF) formalism.

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“…In a previous work, concerned with SiC growth induced by SuMBE of C 60 on Si(111), we demonstrated that substrate temperature has very limited effect on cage breaking mechanisms. 43 Thus, we decided to perform DFT simulations at RT. Details on these simulations and the parameters used are given in Section 2.2.1.…”

Section: Born-oppenheimer Dft and Non-adiabatic Molecular Dynamics Si...mentioning

confidence: 99%

Synthesis of single layer graphene on Cu(111) by C₆₀ supersonic molecular beam epitaxy

et al. 2016

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High-kinetic energy impacts between inorganic surfaces and molecular beams seeded by organics represent a fundamental case study in materials science, most notably when they activate chemical-physical processes leading to nanocrystals growth. Here we demonstrate single-layer graphene synthesis on copper by C60 supersonic molecular beam (SuMBE) epitaxy at 645 °C, with the possibility of further reduction. Using a variety of electron spectroscopy and microscopy techniques, and first-principles simulations, we describe the chemical-physical mechanisms activated by SuMBE resulting in graphene growth. In particular, we find a crucial role of high-kinetic energy deposition in enhancing the organic/inorganic interface interaction, to control the cage openings and to improve the growing film quality. These results, while discussed in the specific case of graphene on copper, are potentially extendable to different metallic or semiconductor substrates and where lower processing temperature is desirable.Non-adiabatic molecular dynamics, Supersonic Molecular Beam Epitaxy.of in-plane carbon-carbon bonds (~ 7.4 eV per carbon atom) and of the graphene edge-metal substrate (~ 7 eV per carbon atom), and the reversibility of the growth dynamics. 1 However, high working temperatures, 3 even in excess of 1000 ºC, are needed in CVD to obtain good quality graphene layers and to initiate the desorption of the hydrogen atoms present in the hydrocarbon precursors. Furthermore, graphene growth by CVD may be critically affected by carbon solubility within the bulk and, finally, by the bond strength between carbon atoms and metal surface. Both these factors depend on process temperature conditions and, typically, CVD single-layer graphene exhibits several defects and polycrystalline structure. 4 Thus, much effort is currently devoted to a better understanding of the growth dynamics on substrate surfaces, to achieve large single-domain dimensions, optimal grain boundary matching and lower processing temperature. 4In this work, aiming at overcoming these issues, we demonstrate the possibility of inducing C60 cage unzipping by supersonic molecular beam epitaxy (SuMBE) on single-crystal (111) and polycrystalline copper surfaces. SuMBE application to graphene growth will be studied by investigating electronic and structural properties of the synthesized C60/Cu thin films and the role of thermal energy in single-layer graphene synthesis by a variety of in-situ and ex-situ experimental methods, such as electron and Raman spectroscopy and scanning microscopy techniques.Furthermore, first-principles simulations based on density functional theory (DFT) will be used: i) to simulate the C60 impact on Cu(111) surface at several kinetic energies (KE); ii) to show the 4 crucial role of non-adiabatic effects on cage breaking; iii) finally, to follow the long-time dynamics after cage rupture leading eventually to graphene formation. RESULTS AND DISCUSSION SuMBE deposition of C60 on copper, core and valence band characterization of the filmsSuMBE has been al...

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The Interaction of C60 on Si(111) 7â€‰Ã—â€‰7 Studied by Supersonic Molecular Beams: Interplay between Precursor Kinetic Energy and Substrate Temperature in Surface Activated Processes

Cited by 5 publications

References 29 publications

2D Material Armors Showing Superior Impact Strength of Few Layers

2D Material Armors Showing Superior Impact Strength of Few Layers

Multiscale Investigation of Oxygen Vacancies in TiO₂ Anatase and Their Role in Memristor’s Behavior

Synthesis of single layer graphene on Cu(111) by C₆₀ supersonic molecular beam epitaxy

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The Interaction of C60 on Si(111) 7â€‰Ã—â€‰7 Studied by Supersonic Molecular Beams: Interplay between Precursor Kinetic Energy and Substrate Temperature in Surface Activated Processes

Cited by 5 publications

References 29 publications

2D Material Armors Showing Superior Impact Strength of Few Layers

2D Material Armors Showing Superior Impact Strength of Few Layers

Multiscale Investigation of Oxygen Vacancies in TiO2 Anatase and Their Role in Memristor’s Behavior

Synthesis of single layer graphene on Cu(111) by C60 supersonic molecular beam epitaxy

Contact Info

Product

Resources

About

Multiscale Investigation of Oxygen Vacancies in TiO₂ Anatase and Their Role in Memristor’s Behavior

Synthesis of single layer graphene on Cu(111) by C₆₀ supersonic molecular beam epitaxy