Your search keyword '"F. Bosia"' showing total 5 results

1. Refractive index variation in a free-standing diamond thin film induced by irradiation with fully transmitted high-energy protons

Author

S. Lagomarsino, S. Calusi, M. Massi, N. Gelli, S. Sciortino, F. Taccetti, L. Giuntini, A. Sordini, M. Vannoni, F. Bosia, D. Gatto Monticone, P. Olivero, B. A. Fairchild, P. Kashyap, A. D. C. Alves, M. A. Strack, S. Prawer, and A. D. Greentree

Subjects

Medicine, Science

Abstract

Abstract Ion irradiation is a widely employed tool to fabricate diamond micro- and nano-structures for applications in integrated photonics and quantum optics. In this context, it is essential to accurately assess the effect of ion-induced damage on the variation of the refractive index of the material, both to control the side effects in the fabrication process and possibly finely tune such variations. Several partially contradictory accounts have been provided on the effect of the ion irradiation on the refractive index of single crystal diamond. These discrepancies may be attributable to the fact that in all cases the ions are implanted in the bulk of the material, thus inducing a series of concurrent effects (volume expansion, stress, doping, etc.). Here we report the systematic characterization of the refractive index variations occurring in a 38 µm thin artificial diamond sample upon irradiation with high-energy (3 MeV and 5 MeV) protons. In this configuration the ions are fully transmitted through the sample, while inducing an almost uniform damage profile with depth. Therefore, our findings conclusively identify and accurately quantify the change in the material polarizability as a function of ion beam damage as the primary cause for the modification of its refractive index.

Published

2017

2. Author Correction: Prey localization in spider orb webs using modal vibration analysis.

Author

Lott M, Poggetto VFD, Greco G, Pugno NM, and Bosia F

Published

2022

3. Prey localization in spider orb webs using modal vibration analysis.

Author

Lott M, Poggetto VFD, Greco G, Pugno NM, and Bosia F

Subjects

Animals, Vibration, Predatory Behavior physiology, Silk chemistry, Spiders physiology

Abstract

Spider webs are finely tuned multifunctional structures, widely studied for their prey capture functionalities such as impact strength and stickiness. However, they are also sophisticated sensing tools that enable the spider to precisely determine the location of impact and capture the prey before it escapes. In this paper, we suggest a new mechanism for this detection process, based on potential modal analysis capabilities of the spider, using its legs as distinct distributed point sensors. To do this, we consider a numerical model of the web structure, including asymmetry in the design, prestress, and geometrical nonlinearity effects. We show how vibration signals deriving from impacts can be decomposed into web eigenmode components, through which the spider can efficiently trace the source location. Based on this numerical analysis, we discuss the role of the web structure, asymmetry, and prestress in the imaging mechanism, confirming the role of the latter in tuning the web response to achieve an efficient prey detection instrument. The results can be relevant for efficient distributed impact sensing applications., (© 2022. The Author(s).)

Published

2022

4. Proof of concept of a frequency-preserving and time-invariant metamaterial-based nonlinear acoustic diode.

Author

Gliozzi AS, Miniaci M, Krushynska AO, Morvan B, Scalerandi M, Pugno NM, and Bosia F

Abstract

Acoustic filters and metamaterials have become essential components for elastic wave control in applications ranging from ultrasonics to noise abatement. Other devices have been designed in this field, emulating their electromagnetic counterparts. One such case is an acoustic diode or rectifier, which enables one-way wave transmission by breaking the wave equation-related reciprocity. Its achievement, however, has proved to be rather problematic, and current realizations display a number of shortcomings in terms of simplicity and versatility. Here, we present the design, fabrication and characterization of a device able to work as an acoustic diode, a switch and a transistor-like apparatus, exploiting symmetry-breaking nonlinear effects like harmonic generation and wave mixing, and the filtering capabilities of metamaterials. This device presents several advantages compared with previous acoustic diode realizations, including versatility, time invariance, frequency preserving characteristics and switchability. We numerically evaluate its efficiency and demonstrate its feasibility in a preliminary experimental realization. This work may provide new opportunities for the practical realization of structural components with one-way wave propagation properties.

Published

2019

5. Refractive index variation in a free-standing diamond thin film induced by irradiation with fully transmitted high-energy protons.

Author

Lagomarsino S, Calusi S, Massi M, Gelli N, Sciortino S, Taccetti F, Giuntini L, Sordini A, Vannoni M, Bosia F, Monticone DG, Olivero P, Fairchild BA, Kashyap P, Alves AD, Strack MA, Prawer S, and Greentree AD

Subjects

Optics and Photonics, Protons, Refractometry, Diamond chemistry, Diamond radiation effects, Optical Phenomena

Abstract

Ion irradiation is a widely employed tool to fabricate diamond micro- and nano-structures for applications in integrated photonics and quantum optics. In this context, it is essential to accurately assess the effect of ion-induced damage on the variation of the refractive index of the material, both to control the side effects in the fabrication process and possibly finely tune such variations. Several partially contradictory accounts have been provided on the effect of the ion irradiation on the refractive index of single crystal diamond. These discrepancies may be attributable to the fact that in all cases the ions are implanted in the bulk of the material, thus inducing a series of concurrent effects (volume expansion, stress, doping, etc.). Here we report the systematic characterization of the refractive index variations occurring in a 38 µm thin artificial diamond sample upon irradiation with high-energy (3 MeV and 5 MeV) protons. In this configuration the ions are fully transmitted through the sample, while inducing an almost uniform damage profile with depth. Therefore, our findings conclusively identify and accurately quantify the change in the material polarizability as a function of ion beam damage as the primary cause for the modification of its refractive index.

Published

2017