Your search keyword '"Ambrosini F"' showing total 6 results

1. Photoluminescence of radiation-induced color centers in lithium fluoride thin films for advanced diagnostics of proton beams.

Author

Piccinini, M., Ambrosini, F., Ampollini, A., Picardi, L., Ronsivalle, C., Bonfigli, F., Libera, S., Nichelatti, E., Vincenti, M. A., and Montereali, R. M.

Subjects

*LITHIUM fluoride, *PHOTOLUMINESCENCE, *COLOR centers (Crystals), *PROTON beams, *THIN films analysis, *LIGHT absorption

Abstract

Systematic irradiation of thermally evaporated 0.8 μm thick polycrystalline lithium fluoride films on glass was performed by proton beams of 3 and 7MeV energies, produced by a linear accelerator, in a fluence range from 1011 to 1015 protons/cm². The visible photoluminescence spectra of radiationinduced F2 and F3+ laser active color centers, which possess almost overlapping absorption bands at about 450 nm, were measured under laser pumping at 458 nm. On the basis of simulations of the linear energy transfer with proton penetration depth in LiF, it was possible to obtain the behavior of the measured integrated photoluminescence intensity of proton irradiated LiF films as a function of the deposited dose. The photoluminescence signal is linearly dependent on the deposited dose in the interval from 10³ to about 106 Gy, independently from the used proton energies. This behavior is very encouraging for the development of advanced solid state radiation detectors based on optically transparent LiF thin films for proton beam diagnostics and two-dimensional dose mapping. [ABSTRACT FROM AUTHOR]

Published

2015

2. Solid state detectors based on point defects in lithium fluoride for advanced proton beam diagnostics.

Author

Piccinini, M., Ambrosini, F., Ampollini, A., Carpanese, M., Picardi, L., Ronsivalle, C., Bonfigli, F., Libera, S., Vincenti, M.A., and Montereali, R.M.

Subjects

*SOLID state chemistry, *LITHIUM fluoride, *PROTON beams, *LINEAR accelerators, *THIN films, *PHOTOLUMINESCENCE

Abstract

Proton beams of 3 and 7 MeV energies, produced by a linear accelerator, were used to irradiate lithium fluoride crystals and thermally evaporated LiF thin films in the fluence range of 10 11 –10 15 protons/cm 2 . The irradiation induces the formation of stable colour centres, mainly the primary F centre and the aggregate F 2 and F 3 + defects. By optical pumping in the blue spectral region, the F 2 and F 3 + centres emit broad photoluminescence bands in the visible spectral range. By conventional fluorescence microscopy, the integrated photoluminescence intensity was carefully measured in LiF crystals and thin films as a function of the irradiation fluence: a linear optical response was obtained in a large range of fluence, which is dependent on the used LiF samples and the selected beam energy. It was possible to record the transversal proton beam intensity profile by acquiring the photoluminescence image of the irradiated spots on LiF films by a standard optical microscope. Using LiF films grown on silicon substrates irradiated in a particular geometry, the same optical reading microscopy technique allowed one to measure the distribution of colour centres photoluminescence along the depth and direct imaging the Bragg peak position, which gives a rough estimation of the initial proton beam energy. [ABSTRACT FROM AUTHOR]

Published

2014

3. Optical spectroscopy and imaging of colour centres in lithium fluoride crystals and thin films irradiated by 3MeV proton beams.

Author

Piccinini, M., Ambrosini, F., Ampollini, A., Carpanese, M., Picardi, L., Ronsivalle, C., Bonfigli, F., Libera, S., Vincenti, M.A., and Montereali, R.M.

Subjects

*OPTICAL spectroscopy, *IMAGING systems, *COLOR centers (Crystals), *LITHIUM fluoride, *THIN films, *PROTON beams, *PHOTOLUMINESCENCE

Abstract

Abstract: Lithium fluoride is a well-known dosimeter material and it is currently under investigation also for high-resolution radiation imaging detectors based on colour centre photoluminescence. In order to extend their applications, proton beams of 3MeV energy, produced by a linear accelerator, were used to irradiate LiF crystals and thin films in the fluence range of 1010–1015 protons/cm2. The irradiation induces the formation of colour centres, mainly the primary F centre and the aggregate F2 and defects, which are stable at room temperature. By optical pumping in the blue spectral region, the F2 and centres emit broad photoluminescence bands in the visible spectral range. By conventional fluorescence microscopy, the integrated photoluminescence intensity was carefully measured in LiF crystals and thin films as a function of the irradiation fluence: a linear optical response was obtained in a large range of fluence, which is dependent on the used LiF samples. Colour centres concentrations were estimated in LiF crystals by optical absorption spectroscopy. It was possible to record the transversal proton beam intensity profile by acquiring the photoluminescence image of the irradiated spots on LiF films. [Copyright &y& Elsevier]

Published

2014

4. Bragg Peak Imaging In Lithium Fluoride Films By Photoluminescent Color Centers Induced By Proton Beams

Author

R. M. Montereali, A. Ampollini, Concetta Ronsivalle, Luigi Picardi, Massimo Piccinini, F. Ambrosini, Francesca Bonfigli, Vincenti, S. Libera, Enrico Nichelatti, Ronsivalle, C., Piccinini, M., Picardi, L., Nichelatti, E., Montereali, R. M., Libera, S., Bonfigli, F., Ampollini, A., Ambrosini, F., and Vincenti, M. A.

Subjects

Photoluminescence, Materials science, Proton, business.industry, Bragg peak, LiF films, Color centers, Proton beams, Lithium fluoride, Linear particle accelerator, Proton beam, Optical pumping, Condensed Matter::Materials Science, chemistry.chemical_compound, chemistry, Optoelectronics, Color center, LiF film, Irradiation, business, Beam (structure)

Abstract

LiF films grown on glass and Si(100) substrates by thermal evaporation were used as radiation imaging detectors to evaluate the Bragg peak position of a 3 MeV proton beam produced by a linear accelerator. The proton irradiation of LiF films induces the formation of stable color centers, mainly the primary F centers and the aggregate F2 and F3 + defects, whose local concentrations are proportional to the deposited energy. Under optical pumping in the blue spectral region, F2 and F3 + color centers emit broad photoluminescence bands located at 678 and 541 nm, respectively, which can be detected by conventional fluorescence microscopy. Photoluminescence images of the top surface of the exposed LiF films allowed obtaining the Bragg peak position of the proton beam, whose evaluation is in satisfactory agreement with software simulations.

Published

2015

5. Solid state detectors based on luminescent point defects in lithium fluoride for proton beam diagnostics

Author

Francesca Bonfigli, S. Libera, Maria Aurora Vincenti, Massimo Piccinini, A. Ampollini, R. M. Montereali, Concetta Ronsivalle, Luigi Picardi, F. Ambrosini, Montereali, R. M., Libera, S., Bonfigli, F., Ronsivalle, C., Picardi, L., Ampollini, A., Ambrosini, F., and Piccinini, M.

Subjects

Photoluminescence, Materials science, Proton, Thin films, Analytical chemistry, alkali halides, colour centres, photoluminescence, proton beams, thin films, Bragg peak, Colour centre, Fluence, law.invention, Proton beam, chemistry.chemical_compound, Colour centres, law, Microscopy, Alkali halides, Irradiation, Thin film, business.industry, Lithium fluoride, Laser, Proton beams, chemistry, Optoelectronics, business

Abstract

Proton beams of energy 3 and 7 MeV, produced by a linear accelerator for protontherapy under development at ENEA Frascati, were used to irradiate lithium fluoride (LiF) crystals and 1 μm thick LiF films grown by thermal evaporation on glass substrates, in a fluence range from 10 11 to 10 15 protons/cm 2 . The irradiation of LiF induced the stable formation of aggregate visible-emitting F 2 and F 3 + color centers, which possess almost overlapping absorption bands around 450 nm and, under optical pumping in this spectral region, they simultaneously emit broad photoluminescence bands, peaked at 678 nm and 541 nm, respectively. Their laser excited emission spectra were acquired and the integrated photoluminescence signal was measured using a fluorescence optical microscope equipped with a cooled s-CMOS camera. The photoluminescence of proton irradiated LiF crystals and films shows an interesting linear response as a function of the irradiation fluence. By optical fluorescence microscopy, it was possible to record the transversal proton beam intensity profile by acquiring the photoluminescence image of irradiated LiF. Moreover, using cleaved LiF films grown on silicon substrates irradiated in a particular geometry allowed one to measure the colour centres photoluminescence distribution with proton penetration depth and provided a direct imaging of the Bragg peak.

Published

2014

6. Optical spectroscopy and imaging of colour centres in lithium fluoride crystals and thin films irradiated by 3 MeV proton beams

Author

Luigi Picardi, M. Carpanese, Maria Aurora Vincenti, Francesca Bonfigli, Massimo Piccinini, S. Libera, R. M. Montereali, Concetta Ronsivalle, A. Ampollini, F. Ambrosini, Montereali, R. M., Vincenti, M. A., Libera, S., Bonfigli, F., Ronsivalle, C., Picardi, L., Carpanese, M., Ampollini, A., Ambrosini, F., and Piccinini, M.

Subjects

Nuclear and High Energy Physics, Photoluminescence, Materials science, Absorption spectroscopy, Physics::Instrumentation and Detectors, Thin films, Physics::Medical Physics, Physics::Optics, Colour centre, Fluence, Proton beam, Condensed Matter::Materials Science, chemistry.chemical_compound, Colour centres, Alkali halides, Irradiation, Thin film, Spectroscopy, Instrumentation, colour centres, THIN FILMS, Proton beams, business.industry, Lithium fluoride, Alkali halide, chemistry, Optoelectronics, High Energy Physics::Experiment, business

Abstract

Lithium fluoride is a well-known dosimeter material and it is currently under investigation also for high-resolution radiation imaging detectors based on colour centre photoluminescence. In order to extend their applications, proton beams of 3 MeV energy, produced by a linear accelerator, were used to irradiate LiF crystals and thin films in the fluence range of 1010–1015 protons/cm2. The irradiation induces the formation of colour centres, mainly the primary F centre and the aggregate F2 and F 3 + defects, which are stable at room temperature. By optical pumping in the blue spectral region, the F2 and F 3 + centres emit broad photoluminescence bands in the visible spectral range. By conventional fluorescence microscopy, the integrated photoluminescence intensity was carefully measured in LiF crystals and thin films as a function of the irradiation fluence: a linear optical response was obtained in a large range of fluence, which is dependent on the used LiF samples. Colour centres concentrations were estimated in LiF crystals by optical absorption spectroscopy. It was possible to record the transversal proton beam intensity profile by acquiring the photoluminescence image of the irradiated spots on LiF films.

Published

2014