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Your search keyword '"N. M. Pugno"' showing total 14 results
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14 results on '"N. M. Pugno"'

1. Modeling of Virus Survival Time in Respiratory Droplets on Surfaces: A New Rational Approach for Antivirus Strategies

Author

N. G. Di Novo, A. R. Carotenuto, G. Mensitieri, M. Fraldi, N. M. Pugno, Di Novo, N. G., Carotenuto, A. R., Mensitieri, G., Fraldi, M., and Pugno, N. M.

Subjects
Technology, 0303 health sciences, Materials science, SARS-CoV-2, droplet evaporation, 030306 microbiology, Vapor pressure, Materials Science (miscellaneous), COVID-19, SARS-CoV-2, droplet evaporation, virus viability, surfaces design, Evaporation, COVID-19, surfaces design, Function (mathematics), Surface energy, Contact angle, 03 medical and health sciences, Volume (thermodynamics), Relative humidity, virus viability, Biological system, Constant (mathematics), 030304 developmental biology
Abstract

The modeling of the viability decay of viruses in sessile droplets is addressed considering a droplet sitting on a smooth surface characterized by a specific contact angle. To investigate, at prescribed temperature, how surface energy of the material and ambient humidity cooperate to determine the virus viability, we propose a model which involves the minimum number of thermodynamically relevant parameters. In particular, by considering a saline water droplet (one salt) as the simplest approximation of real solutions (medium and natural/artificial saliva), the evaporation is described by a first-order time-dependent nonlinear differential equation properly rearranged to obtain the contact angle evolution as the sole unknown function. The analyses were performed for several contact angles and two typical droplet sizes of interest in real situations by assuming constant ambient temperature and relative humidity in the range 0–100%. The results of the simulations, given in terms of time evolution of salt concentration, vapor pressure, and droplet volume, elucidate some previously not yet well-understood dynamics, demonstrating how three main regimes—directly implicated in nontrivial trends of virus viability and to date only highlighted experimentally—can be recognized as the function of relative humidity. By recalling the concept of cumulative dose of salts (CD), to account for the effect of the exposition of viruses to salt concentration on virus viability, we show how the proposed approach could suggest a chart of a virus fate by predicting its survival time at a given temperature as a function of the relative humidity and contact angle. We found a good agreement with experimental data for various enveloped viruses and predicted in particular for the Phi6 virus, a surrogate of coronavirus, the characteristic U-shaped dependence of viability on relative humidity. Given the generality of the model and once experimental data are available that link the vulnerability of a certain virus, such as SARS-CoV-2, to the concentrations of salts or other substances in terms of CD, it is felt that this approach could be employed for antivirus strategies and protocols for the prediction/reduction of human health risks associated with SARS-CoV-2 and other viruses. © Copyright © 2021 Di Novo, Carotenuto, Mensitieri, Fraldi and Pugno.

Published
2021
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2. Multi-Physics of Dynamic Elastic Metamaterials and Earthquake Systems

Author

A. A. Yakovleva, I. B. Movchan, D. Misseroni, N. M. Pugno, and A. B. Movchan

Subjects
Materials Science (miscellaneous), Cloaking, 02 engineering and technology, seismic analysis, 01 natural sciences, lcsh:Technology, Seismic analysis, 0103 physical sciences, Aerospace engineering, 010306 general physics, Dispersion (water waves), business.industry, Event (computing), lcsh:T, elastic waves, Metamaterial, 021001 nanoscience & nanotechnology, elastic waves, dispersion, metamaterials, seismic analysis, hydrofracture, Vibration, Range (mathematics), metamaterials, dispersion, 0210 nano-technology, business, hydrofracture, Energy (signal processing)
Abstract

Microstructured materials, namely metamaterials, are one of the most relevant topics of the recent period due to their interdisciplinary nature. Driven by their wide range of applications, we provide an overview of a class of elastic solids which embed dynamic microstructures capable of trapping energy when subject to dynamic loads. Based on the recently developed modeling approaches, we show several applications related to wave cloaking, filtering and also multi-structured surfaces, often referred to as meta-surfaces. These culminate in the analysis of a practical example, based on a real-life recent seismic event induced by a hydrofracture exploration. The latter shows the viability of the vibration analysis in the assessment of the seismic response, and also the role of meta-surfaces as localisers of vibrations, e.g. suggesting non-periodic earthquake tolerant design strategies of housing estates.

Published
2021
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3. Air-encapsulating elastic mechanism of submerged

Author

M C, Pugno, D, Misseroni, and N M, Pugno

Subjects
Dandelion, Taraxacum, Full Length Article, Air-entrapping, Compliant mechanisms, Fractal
Abstract

In this article, we report the observation of an air-encapsulating elastic mechanism of Dandelion spherical seed heads, namely blowballs, when submerged underwater. This peculiarity seems to be fortuitous since Taraxacum is living outside water; nevertheless, it could become beneficial for a better survival under critical conditions, e.g. of temporary flooding. The scaling of the volume of the air entrapped suggests its fractal nature with a dimension of 2.782 and a fractal air volume fraction of 4.82 × 10−2 m0.218, resulting in nominal air volume fractions in the range of 14–23%. This aspect is essential for the optimal design of bioinspired materials made up of Dandelion-like components. The miniaturization of such components leads to an increase in the efficiency of the air encapsulation up to the threshold (efficiency = 1) achieved for an optimal critical size. Thus, the optimal design is accomplished using small elements, with the optimal size, rather than using larger elements in a lower number. The described phenomenon, interesting per se, also brings bioinspired insights toward new related technological solutions for underwater air-trapping and air-bubbles transportation, e.g. the body surface of a man could allow an apnea (air consumption of 5–10 l/min) of about 10 min if it is covered by a material made up of a periodic repetition of Dandelion components of diameter ≅18 μm and having a total thickness of about 3–6 cm., Graphical abstract Image 1

Published
2020

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