Singlet oxygen has attracted great attention in physical, chemical, as well as biological studies, mainly due to its high reactivity and strong oxidising properties. In this context, hybrid nanosystems comprised of (inor- ganic) X-ray absorbing nanostructures and (organic) light-sensitive material (photosensitizers) can poten- tially overcome the limitations of visible light penetration in matter. A deep investigation of the interface of such hybrid nanosystems for X-ray induced generation of singlet oxygen is key to better understand the processes at the hybrid interface, and to control the energy transfer from inorganic to organic counter- parts, which ultimately leads to enhanced singlet oxygen generation. Here, we demonstrate that SiC/SiOx core/shell nanowires functionalized with the tetrakisIJpentafluorophenyl)porphyrin can act as a highly prom- ising and viable strategy to generate singlet oxygen, making this novel hybrid nanosystem attractive for ap- plications in photocatalysis and nanomedical applications. Using different excitation sources (i.e., electrons, visible light, and X-rays) our findings prove that SiC/SiOx core/shell nanowires show X-ray excited optical luminescence, and that optical emission of the photosensitizer is largely enhanced by the nanowires, yield- ing an efficient energy transfer. A consequent singlet oxygen production of the functionalized nanowires is demonstrated after X-ray excitation in a clinical linear accelerator. These findings will provide an insight in developing an effective route to the molecular functionalization of SiC/SiOx core/shell nanowires and their potential use as singlet oxygen generators.
Functionalization of SiC/SiOx nanowires with a porphyrin derivative: a hybrid nanosystem for X-ray induced singlet oxygen generation / Tatti, R.; Timpel, M.; Nardi, M. V.; Fabbri, F.; Rossi, R.; Pasquardini, L.; Chiasera, A.; Aversa, L.; Koshmak, K.; Giglia, A.; Pasquali, Luca; Rimoldi, T.; Cristofolini, L.; Attolini, G.; Varas, S.; Iannotta, S.; Verucchi, R.; Salviati, G.. - In: MOLECULAR SYSTEMS DESIGN & ENGINEERING. - ISSN 2058-9689. - 2:2(2017), pp. 165-172. [10.1039/C7ME00005G]
Functionalization of SiC/SiOx nanowires with a porphyrin derivative: a hybrid nanosystem for X-ray induced singlet oxygen generation
PASQUALI, Luca;
2017
Abstract
Singlet oxygen has attracted great attention in physical, chemical, as well as biological studies, mainly due to its high reactivity and strong oxidising properties. In this context, hybrid nanosystems comprised of (inor- ganic) X-ray absorbing nanostructures and (organic) light-sensitive material (photosensitizers) can poten- tially overcome the limitations of visible light penetration in matter. A deep investigation of the interface of such hybrid nanosystems for X-ray induced generation of singlet oxygen is key to better understand the processes at the hybrid interface, and to control the energy transfer from inorganic to organic counter- parts, which ultimately leads to enhanced singlet oxygen generation. Here, we demonstrate that SiC/SiOx core/shell nanowires functionalized with the tetrakisIJpentafluorophenyl)porphyrin can act as a highly prom- ising and viable strategy to generate singlet oxygen, making this novel hybrid nanosystem attractive for ap- plications in photocatalysis and nanomedical applications. Using different excitation sources (i.e., electrons, visible light, and X-rays) our findings prove that SiC/SiOx core/shell nanowires show X-ray excited optical luminescence, and that optical emission of the photosensitizer is largely enhanced by the nanowires, yield- ing an efficient energy transfer. A consequent singlet oxygen production of the functionalized nanowires is demonstrated after X-ray excitation in a clinical linear accelerator. These findings will provide an insight in developing an effective route to the molecular functionalization of SiC/SiOx core/shell nanowires and their potential use as singlet oxygen generators.File | Dimensione | Formato | |
---|---|---|---|
MolSysDesEng_Nardi_XEOL_ 2017_doi.pdf
Accesso riservato
Descrizione: Articolo principale
Tipologia:
Versione pubblicata dall'editore
Dimensione
3.65 MB
Formato
Adobe PDF
|
3.65 MB | Adobe PDF | Visualizza/Apri Richiedi una copia |
Pubblicazioni consigliate
I metadati presenti in IRIS UNIMORE sono rilasciati con licenza Creative Commons CC0 1.0 Universal, mentre i file delle pubblicazioni sono rilasciati con licenza Attribuzione 4.0 Internazionale (CC BY 4.0), salvo diversa indicazione.
In caso di violazione di copyright, contattare Supporto Iris