Your search keyword '"V. PELLEGRINI"' showing total 5 results

1. Sulfonated NbS 2 -based proton-exchange membranes for vanadium redox flow batteries.

Author

Beydaghi H, Bellani S, Najafi L, Oropesa-Nuñez R, Bianca G, Bagheri A, Conticello I, Martín-García B, Kashefi S, Serri M, Liao L, Sofer Z, Pellegrini V, and Bonaccorso F

Abstract

In this work, novel proton-exchange membranes (PEMs) based on sulfonated poly(ether ether ketone) (SPEEK) and two-dimensional (2D) sulfonated niobium disulphide (S-NbS 2 ) nanoflakes are synthesized by a solution-casting method and used in vanadium redox flow batteries (VRFBs). The NbS 2 nanoflakes are produced by liquid-phase exfoliation of their bulk counterpart and chemically functionalized with terminal sulfonate groups to improve dimensional and chemical stabilities, proton conductivity ( σ ) and fuel barrier properties of the as-produced membranes. The addition of S-NbS 2 nanoflakes to SPEEK decreases the vanadium ion permeability from 5.42 × 10 -7 to 2.34 × 10 -7 cm 2 min -1 . Meanwhile, it increases the membrane σ and selectivity up to 94.35 mS cm -2 and 40.32 × 10 4 S min cm -3 , respectively. The cell assembled with the optimized membrane incorporating 2.5 wt% of S-NbS 2 nanoflakes (SPEEK:2.5% S-NbS 2 ) exhibits high efficiency metrics, i.e. , coulombic efficiency between 98.7 and 99.0%, voltage efficiency between 90.2 and 73.2% and energy efficiency between 89.3 and 72.8% within the current density range of 100-300 mA cm -2 , delivering a maximum power density of 0.83 W cm -2 at a current density of 870 mA cm -2 . The SPEEK:2.5% S-NbS 2 membrane-based VRFBs show a stable behavior over 200 cycles at 200 mA cm -2 . This study opens up an effective avenue for the production of advanced SPEEK-based membranes for VRFBs.

Published

2022

2. An integrated and multi-technique approach to characterize airborne graphene flakes in the workplace during production phases.

Author

Tombolini F, Boccuni F, Ferrante R, Natale C, Marasco L, Mantero E, Del Rio Castillo AE, Leoncino L, Pellegrini V, Sabella S, and Iavicoli S

Abstract

Graphene is a one-atom-thick sheet of carbon atoms arranged in a honeycomb pattern and its unique and amazing properties make it suitable for a wide range of applications ranging from electronic devices to food packaging. However, the biocompatibility of graphene is dependent on the complex interplay of its several physical and chemical properties. The main aim of the present study is to highlight the importance of integrating different characterization techniques to describe the potential release of airborne graphene flakes in a graphene processing and production research laboratory. Specifically, the production and processing (i.e., drying) of few-layer graphene (FLG) through liquid-phase exfoliation of graphite are analysed by integrated characterization techniques. For this purpose, the exposure measurement strategy was based on the multi-metric tiered approach proposed by the Organization for Economic Cooperation and Development (OECD) via integrating high-frequency real-time measurements and personal sampling. Particle number concentration, average diameter and lung deposition surface area time series acquired in the worker's personal breathing zone (PBZ) were compared simultaneously to background measurements, showing the potential release of FLG. Then, electron microscopy techniques and Raman spectroscopy were applied to characterize particles collected by personal inertial impactors to investigate the morphology, chemical composition and crystal structure of rare airborne graphene flakes. The gathered information provides a valuable basis for improving risk management strategies in research and industrial laboratories.

Published

2021

3. Ultralow friction of ink-jet printed graphene flakes.

Author

Buzio R, Gerbi A, Uttiya S, Bernini C, Del Rio Castillo AE, Palazon F, Siri AS, Pellegrini V, Pellegrino L, and Bonaccorso F

Abstract

We report the frictional response of few-layer graphene (FLG) flakes obtained by the liquid phase exfoliation (LPE) of pristine graphite. To this end, we inkjet print FLG on bare and hexamethyldisilazane-terminated SiO 2 substrates, producing micrometric patterns with nanoscopic roughness that are investigated by atomic force microscopy. Normal force spectroscopy and atomically-resolved morphologies indicate reduced surface contamination by solvents after a vacuum annealing process. Notably, the printed FLG flakes show ultralow friction comparable to that of micromechanically exfoliated graphene flakes. Lubricity is retained on flakes with a lateral size of a few tens of nanometres, and with a thickness as small as ∼2 nm, confirming the high crystalline quality and low defects density in the FLG basal plane. Surface exposed step edges exhibit the highest friction values, representing the preferential sites for the origin of the secondary dissipative processes related to edge straining, wear or lateral displacement of the flakes. Our work demonstrates that LPE enables fundamental studies on graphene friction to the single-flake level. The capability to deliver ultralow-friction-graphene over technologically relevant substrates, using a scalable production route and a high-throughput, large-area printing technique, may also open up new opportunities in the lubrication of micro- and nano-electromechanical systems.

Published

2017

4. Graphene-based large area dye-sensitized solar cell modules.

Author

Casaluci S, Gemmi M, Pellegrini V, Di Carlo A, and Bonaccorso F

Abstract

We demonstrate spray coating of graphene ink as a viable method for large-area fabrication of graphene-based dye-sensitized solar cell (DSSC) modules. A graphene-based ink produced by liquid phase exfoliation of graphite is spray coated onto a transparent conductive oxide substrate to realize a large area (>90 cm(2)) semi-transparent (transmittance 44%) counter-electrode (CE) replacing platinum, the standard CE material. The graphene-based CE is successfully integrated in a large-area (43.2 cm(2) active area) DSSC module achieving a power conversion efficiency of 3.5%. The approach demonstrated here paves the way to all-printed, flexible, and transparent graphene-based large-area and cost-effective photovoltaic devices on arbitrary substrates.

Published

2016

5. Science and technology roadmap for graphene, related two-dimensional crystals, and hybrid systems.

Author

Ferrari AC, Bonaccorso F, Fal'ko V, Novoselov KS, Roche S, Bøggild P, Borini S, Koppens FH, Palermo V, Pugno N, Garrido JA, Sordan R, Bianco A, Ballerini L, Prato M, Lidorikis E, Kivioja J, Marinelli C, Ryhänen T, Morpurgo A, Coleman JN, Nicolosi V, Colombo L, Fert A, Garcia-Hernandez M, Bachtold A, Schneider GF, Guinea F, Dekker C, Barbone M, Sun Z, Galiotis C, Grigorenko AN, Konstantatos G, Kis A, Katsnelson M, Vandersypen L, Loiseau A, Morandi V, Neumaier D, Treossi E, Pellegrini V, Polini M, Tredicucci A, Williams GM, Hong BH, Ahn JH, Kim JM, Zirath H, van Wees BJ, van der Zant H, Occhipinti L, Di Matteo A, Kinloch IA, Seyller T, Quesnel E, Feng X, Teo K, Rupesinghe N, Hakonen P, Neil SR, Tannock Q, Löfwander T, and Kinaret J

Abstract

We present the science and technology roadmap for graphene, related two-dimensional crystals, and hybrid systems, targeting an evolution in technology, that might lead to impacts and benefits reaching into most areas of society. This roadmap was developed within the framework of the European Graphene Flagship and outlines the main targets and research areas as best understood at the start of this ambitious project. We provide an overview of the key aspects of graphene and related materials (GRMs), ranging from fundamental research challenges to a variety of applications in a large number of sectors, highlighting the steps necessary to take GRMs from a state of raw potential to a point where they might revolutionize multiple industries. We also define an extensive list of acronyms in an effort to standardize the nomenclature in this emerging field.

Published

2015