Your search keyword '"Filippo Franceschini"' showing total 2 results

1. Electrodes for Paracetamol Sensing Modified with Bismuth Oxide and Oxynitrate Heterostructures: An Experimental and Computational Study

Author

Filippo Franceschini, Mattia Bartoli, Alberto Tagliaferro, and Sandro Carrara

Subjects

Technology, paracetamol, screen-printed electrode, electrochemical sensor, QD415-436, Biochemistry, Analytical Chemistry, sensor, nitrate, bismuth, Electrochemistry, electron transfer rate, POLLUTANTS, Physical and Theoretical Chemistry, electrochemical oxidation, Instruments & Instrumentation, nanomaterials, acetaminophen, NANOMATERIALS, Science & Technology, ELECTROCHEMICAL OXIDATION, Chemistry, Analytical, SENSOR, biosensors, Chemistry, pollutants, Physical Sciences, BIOSENSORS, ACETAMINOPHEN, Bismuth, Electrochemical sensor, Electron transfer rate, Paracetamol, Screen-printed electrode, NITRATE

Abstract

In this work, novel platforms for paracetamol sensing were developed by the deposition of Bi2O3, Bi5O7NO3 and their heterostructures onto screen-printed carbon-paste electrodes. An easy and scalable solid state synthesis route was employed, and by setting the calcination temperatures at 500 °C and 525 °C we induced the formation of heterostructures of Bi2O3 and Bi5O7NO3. Cyclic voltammetry measurements highlighted that the heterostructure produced at 500 °C provided a significant enhancement in performance compared to the monophases of Bi2O and Bi5O7NO3, respectively. That heterostructure showed a mean peak-to-peak separation Ep of 411 mV and a sensitivity increment of up to 70% compared to bare electrodes. A computational study was also performed in order to evaluate the geometrical and kinetic parameters of representative clusters of bismuth oxide and subnitrate when they interact with paracetamol.

Published

2021

2. A Comprehensive Review on Raman Spectroscopy Applications

Author

Massimo Rovere, Mattia Bartoli, Cristian Muscas, Filippo Franceschini, Alberto Tagliaferro, Andrea Orlando, and Solomiya Pidkova

Subjects

Materials science, SERS, Material analysis, Nanotechnology, material characterization, QD415-436, Raman spectroscopy, qualitative analysis, Tip-enhanced Raman spectroscopy, Biochemistry, Biological materials, Analytical Chemistry, symbols.namesake, Qualitative analysis, symbols, Physical and Theoretical Chemistry

Abstract

Raman spectroscopy is a very powerful tool for material analysis, allowing for exploring the properties of a wide range of different materials. Since its discovery, Raman spectroscopy has been used to investigate several features of materials such carbonaceous and inorganic properties, providing useful information on their phases, functions, and defects. Furthermore, techniques such as surface and tip enhanced Raman spectroscopy have extended the field of application of Raman analysis to biological and analytical fields. Additionally, the robustness and versatility of Raman instrumentations represent a promising solution for performing on-field analysis for a wide range of materials. Recognizing the many hot applications of Raman spectroscopy, we herein overview the main and more recent applications for the investigation of a wide range of materials, such as carbonaceous and biological materials. We also provide a brief but exhaustive theoretical background of Raman spectroscopy, also providing deep insight into the analytical achievements.

Published

2021