Luca Fichera scite author profile

Luca Fichera

5Publications

62Citation Statements Received

98Citation Statements Given

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139

Affiliations

University of Catania

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Carbon Quantum Dots as Fluorescence Nanochemosensors for Selective Detection of Amino Acids

Tuccitto

Fichera

Ruffino

et al. 2021

ACS Appl. Nano Mater.

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Fluorescent carbon quantum dots (CDs) are synthesized and employed as fluorescent nanochemosensors for selective detection of amino acids. A detailed investigation of excitation−emission maps revealed that the fluorescence properties of CDs are intensely and strongly influenced by the interaction at the surface with different amino acids. The discrimination capability was demonstrated by tensor rank decomposition of the differences induced by the surface reaction in the excitation−emission maps and by means of a common machine learning approach based on artificial neural networks.

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Fluorescent nanoparticle-based Internet of things

2020

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Reduction of Graphene Oxide by Laser Scribing in Different Atmospheres and Application in Humidity Sensing

Scardaci

Fichera

Fragalà

et al. 2020

Journal of Nanomaterials

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Laser scribing, by far proposed as a method for efficiently transforming graphene oxide into reduced graphene, has been employed, using a CW laser beam, to study the modifications of graphene oxide scribed under different controlled atmospheres, including air, N2, Ar, and a 95 : 5 (v/v) Ar/H2 mixture. We have found that laser scribing effects, including chemical composition, order degree, and electrical properties, strongly depend upon the atmosphere during the irradiation. The electrical properties of the various materials, obtained in different atmospheres, have been evaluated with respect to the sensing properties towards humidity, the materials produced in pure Argon yielding the highest sensitivity and the fastest response, while related Raman microspectroscopy measurements showed that both Ar and Ar-H2 mixture produce the highest order among the various samples. The results stress the importance and the potentialities of controlling the irradiation atmosphere in order to tune the composition and electrical properties of the laser-scribed graphene oxide materials.

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Self-assembled carbon nanoparticles as messengers for artificial chemical communication

et al. 2019

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Reactive nanomessengers for artificial chemical communication

Fichera

Destri

Ruffino

et al. 2019

Phys. Chem. Chem. Phys.

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Luca Fichera

Carbon Quantum Dots as Fluorescence Nanochemosensors for Selective Detection of Amino Acids

Fluorescent nanoparticle-based Internet of things

Reduction of Graphene Oxide by Laser Scribing in Different Atmospheres and Application in Humidity Sensing

Self-assembled carbon nanoparticles as messengers for artificial chemical communication

Reactive nanomessengers for artificial chemical communication

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