An inverse (water in oil) miniemulsion technique was successfully implemented for the first time for the synthesis of crystalline pure and doped CuS nanostructures to be applied in photothermal therapy. Different copper and sulfur sources were tested for the preparation of the targeted compounds. The successful formation at room temperature of the covellite crystalline phase was revealed by means of X-Ray Diffraction, Selected Area Electron Diffraction and X-ray Absorption Spectroscopy. The nanostructures morphology was assessed by Scanning and Transmission Electron Microscopies, while the surface composition was determined by X-ray Photoelectron Spectroscopy. Further investigations aimed at obtaining a characterization as detailed as possible were performed by combining the outcomes of complementary techniques. Droplet size variations as function of sonication time and/or mode were studied using Dynamic Light Scattering measurements. A high microscopic photothermal conversion efficiency – a relevant property for photothermal therapy and photoacoustic imaging – was determined by calibrated optoacoustic measurements. The photothermal efficiency of diluted aqueous dispersions of the CuS nanostructures was 0.72 by using a laser excitation at 1064 nm.
Room temperature crystallization of CuS nanostructures for photothermal applications through a nanoreactor approach / Morgese, Giulia; Dolcet, Paolo; Feis, Alessandro; Gellini, Cristina; Gialanella, Stefano; Speghini, Adolfo; Badocco, Denis; Pastore, Paolo; Casarin, Maurizio; Gross, Silvia. - In: EUROPEAN JOURNAL OF INORGANIC CHEMISTRY. - ISSN 1099-0682. - STAMPA. - 2017:(2017), pp. 2745-2754. [10.1002/ejic.201601435]
Room temperature crystallization of CuS nanostructures for photothermal applications through a nanoreactor approach
FEIS, ALESSANDRO;GELLINI, CRISTINA;
2017
Abstract
An inverse (water in oil) miniemulsion technique was successfully implemented for the first time for the synthesis of crystalline pure and doped CuS nanostructures to be applied in photothermal therapy. Different copper and sulfur sources were tested for the preparation of the targeted compounds. The successful formation at room temperature of the covellite crystalline phase was revealed by means of X-Ray Diffraction, Selected Area Electron Diffraction and X-ray Absorption Spectroscopy. The nanostructures morphology was assessed by Scanning and Transmission Electron Microscopies, while the surface composition was determined by X-ray Photoelectron Spectroscopy. Further investigations aimed at obtaining a characterization as detailed as possible were performed by combining the outcomes of complementary techniques. Droplet size variations as function of sonication time and/or mode were studied using Dynamic Light Scattering measurements. A high microscopic photothermal conversion efficiency – a relevant property for photothermal therapy and photoacoustic imaging – was determined by calibrated optoacoustic measurements. The photothermal efficiency of diluted aqueous dispersions of the CuS nanostructures was 0.72 by using a laser excitation at 1064 nm.File | Dimensione | Formato | |
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