Your search keyword '"Andrew Teren"' showing total 5 results

1. Overdamping of vibration resonances by liquid crystal elastomers

Author

Waiel Elmadih, Andrew Terentjev, Hsin-Ling Liang, and Eugene Terentjev

Subjects

Vibration, Resonance, Damping, Liquid crystal elastomers, Medicine, Science

Abstract

Abstract This work aims to compare the capability of vibration attenuation by standard elastomeric polymers, and by the new anomalously damping nematic liquid crystal elastomer. We use the most mainstream materials in both categories, and design two testing platforms: the ASTM-standard constrained layer plate resonance geometry, and the attenuation of resonances in a commercial device (electric drill) where the damping polymers were inserted into the casing. In the standard plate resonance testing, we find that LCE outperforms all standard damping materials, moreover, it brings the vibrating plate into the overdamped condition, which is unique for a non-fluid dissipative system. In the attenuation of high-frequency vibrations of a device, we also found LCE dissipates these vibrations much better, although we did not find the optimal insertion configuration for the damping polymer, and did not reach overdamping.

Published

2024

2. Momentum transfer on impact damping by liquid crystalline elastomers

Author

Hongye Guo, Andrew Terentjev, Mohand O. Saed, and Eugene M. Terentjev

Subjects

Medicine, Science

Abstract

Abstract The effect of elastomeric damping pads, softening the collision of hard objects, is investigated comparing the reference silicone elastomer and the polydomain nematic liquid crystalline elastomer, which has a far superior internal dissipation mechanism. We specifically focus not just on the energy dissipation, but also on the momentum conservation and transfer during the collision, because the latter determines the force exerted on the target and/or the impactor—and it is the force that does the damage during the short time of an impact, while the energy might be dissipated on a much longer time scale. To better assess the momentum transfer, we compare the collision with a very heavy object and the collision with a comparable mass, when some of the impact momentum is retained in the target receding away from the collision. We also propose a method to estimate the optimal thickness of an elastomer damping pad for minimising the energy in impactor rebound. It has been found that thicker pads introduce a large elastic rebound and the optimal thickness is therefore the thinnest possible pad that does not suffer from mechanical failure. We find good agreement between our estimate of the minimal thickness of the elastomer before the puncture through occurs and the experimental observations.

Published

2023

3. Thermal and Electrical Characterization of Materials for Phase-Change Memory Cells

Author

Claudia Wiemer, Andrea Gotti, Jean-Luc Battaglia, S. Cocco, Enrico Varesi, Raimondo Cecchini, Roberto Fallica, Andrew Teren, Marco Fanciulli, and Cristiano Monguzzi

Subjects

Phase transition, Chemistry, Chalcogenide, General Chemical Engineering, Physics::Optics, Mineralogy, General Chemistry, Thermal conduction, Condensed Matter::Disordered Systems and Neural Networks, Amorphous solid, Phase-change memory, Condensed Matter::Materials Science, chemistry.chemical_compound, Thermal conductivity, Electrical resistivity and conductivity, Thermal, Composite material

Abstract

The thermal properties of the phase-change chalcogenide alloy Ge2Sb2Te5 in its three phases (amorphous, cubic, and hexagonal) and of Si3N4 and SiO2 have been studied to obtain reliable values for device modeling. Thermal conductivity was determined, along with a quantitative estimation of the thermal resistances of the layers’ interfaces, not negligible for highly scaled devices. Electrical resistivity of the chalcogenide material has also been investigated during the phase transition by in situ measurement at constant heating rate.

Published

2009

4. Impact damping and vibration attenuation in nematic liquid crystal elastomers

Author

Mohand O. Saed, Waiel Elmadih, Andrew Terentjev, Dimitrios Chronopoulos, David Williamson, and Eugene M. Terentjev

Subjects

Science

Abstract

Nematic liquid crystal elastomers (LCE). exhibit unique mechanical properties such as large loss behaviour, which makes these materials interesting for damping applications. Here, the authors investigate the effect of anomalous damping in LCEs by comparing impact dissipation in shaped samples with elastic wave transmission and resonance.

Published

2021

5. Thermal and Electrical Characterization of Materials for Phase-Change Memory Cells†.

Author

Roberto Fallica, Jean-Luc Battaglia, Simone Cocco, Cristiano Monguzzi, Andrew Teren, Claudia Wiemer, Enrico Varesi, Raimondo Cecchini, Andrea Gotti, and Marco Fanciulli

Published

2009