Sentence examples similar to electromechanical size from inspiring English sources

Flexoelectricity and the concomitant emergence of electromechanical size-effects at the nanoscale have been recently exploited to propose tantalizing concepts such as the creation of "apparently piezoelectric" materials without piezoelectric materials, e.g. graphene, emergence of "giant" piezoelectricity at the nanoscale, enhanced energy harvesting, among others.

In nanotechnology, a nanomachine is a mechanical or electromechanical device with nanometer size dimensions.

These findings can provide effective guidance for the explanation of certain physical phenomenon about size-dependent electromechanical characteristics and experimental design of piezoelectric devices in nanoscale.

(2016), the size-dependent electromechanical properties of piezoelectric superlattices made of BaTiO3 (BTO) and PbTiO3 (PTO) layers are investigated systematically in the present work.

Each case should be treated independently, since the need in electricity depends on different factors: sea water characteristics, values taken for RO sizing parameters, electromechanical components efficiency... and, last but not least, choice of the system for hydraulic energy recovery of the concentrate.

Over the last 20 years, researchers have perfected a host of techniques to carve silicon and other materials into electromechanical devices just micrometers in size.

As a result, a strong size dependence of electromechanical properties is predicted for the piezoelectric BTO PTO superlattices.

To conclude, the suitability of the proposed methodology is illustrated with the preliminary sizing of an electromechanical actuator for an aircraft primary flight control surface (aileron).

In this article we present a theory describing the influence of the magnetostrictive component size on magnetically tuned electromechanical resonance frequencies (EMRs) for ferromagnetic piezoelectric heterostructures.

This phenomenon opens a way for generation of the high frequency electromagnetic waves by using the electromechanical systems with emitters of nanometer size.

This flexibility can be exploited for numerous tribological applications, ranging in sizes from nano-scale electromechanical systems to meso-scale engine parts and components.