170 research outputs found
A two-step hybrid approach for modeling the nonlinear dynamic response of piezoelectric energy harvesters
An effective hybrid computational framework is described here in order to assess the nonlinear dynamic response of piezoelectric energy harvesting devices. The proposed strategy basically consists of two steps. First, fully coupled multiphysics finite element (FE) analyses are performed to evaluate the nonlinear static response of the device. An enhanced reduced-order model is then derived, where the global dynamic response is formulated in the state-space using lumped coefficients enriched with the information derived from the FE simulations. The electromechanical response of piezoelectric beams under forced vibrations is studied by means of the proposed approach, which is also validated by comparing numerical predictions with some experimental results. Such numerical and experimental investigations have been carried out with the main aim of studying the influence of material and geometrical parameters on the global nonlinear response. The advantage of the presented approach is that the overall computational and experimental efforts are significantly reduced while preserving a satisfactory accuracy in the assessment of the global behavior
Energy harvesting from earthquake for vibration-powered wireless sensors
Wireless sensor networks can facilitate the acquisition of useful data for the assessment and retrofitting of existing structures and infrastructures. In this perspective, recent studies have presented numerical and experimental results about self-powered wireless nodes for structural monitoring applications in the event of earthquake, wherein the energy is scavenged from seismic accelerations. A general computational approach for the analysis and design of energy harvesters under seismic loading, however, has not yet been presented. Therefore, this paper proposes a rational method that relies on the random vibrations theory for the electromechanical analysis of piezoelectric energy harvesters under seismic ground motion. In doing so, the ground acceleration is simulated by means of the Clough-Penzien filter. The considered piezoelectric harvester is a cantilever bimorph modeled as Euler-Bernoulli beam with concentrated mass at the free-end, and its global behavior is approximated by the dynamic response of the fundamental vibration mode only (which is tuned with the dominant frequency of the site soil). Once the Lyapunov equation of the coupled electromechanical problem has been formulated, mean and standard deviation of the generated electric energy are calculated. Numerical results for a cantilever bimorph which piezoelectric layers made of electrospun PVDF nanofibers are discussed in order to understand issues and perspectives about the use of wireless sensor nodes powered by earthquakes. A smart monitoring strategy for the experimental assessment of structures in areas struck by seismic events is finally illustrated
Projecting the nanoworld: Concepts, results and perspectives of molecular electronics
A bottom-up approach is a promising alternative to build nanodevices and/or nanomachines starting from molecular building blocks. The idea of molecular electronics comes from a farsighted paper by Aviram and Ratner, predicting that single molecules with a donor–spacer–acceptor structure would have rectifying properties when placed between two electrodes. Today, molecular electronics is emerging as an alternative to Si-nanoelectronics for building integrated devices. This review aims to give an overview of this emerging field, analysing the concepts, the key results and the perspectives
Nanotechnology approaches to self-organized bio-molecular devices
Abstract In this paper we briefly describe new strategies to exploit self-assembled solid-state biomolecular materials as active elements of electronic devices. Two basically different approaches are proposed: a top-down approach, where biomolecular semiconductors consisting of DNA basis are self-organized and interconnected by planar metallic nanopatterns, and a bottom-up approach, where single or ordered matalloproteins are immobilized in a nanocircuit realizing a hybrid covalently bound biologic–inorganic system. The transport characteristics of different devices such as diodes, photodetectors and metal–semiconductor–metal structures will be described
Optimization of SAW Sensors for Nanoplastics and Grapevine Virus Detection
In this work, we report the parametric optimization of surface acoustic wave (SAW) delay lines on Lithium niobate for environmental monitoring applications. First, we show that the device performance can be improved by acting opportunely on geometrical design parameters of the interdigital transducers such as the number of finger pairs, the finger overlap length and the distance between the emitter and the receiver. Then, the best-performing configuration is employed to realize SAW sensors. As aerosol particulate matter (PM) is a major threat, we first demonstrate a capability for the detection of polystyrene particles simulating nanoparticulates/nanoplastics, and achieve a limit of detection (LOD) of 0.3 ng, beyond the present state-of-the-art. Next, the SAW sensors were used for the first time to implement diagnostic tools able to detect Grapevine leafroll-associated virus 3 (GLRaV-3), one of the most widespread viruses in wine-growing areas, outperforming electrochemical impedance sensors thanks to a five-times better LOD. These two proofs of concept demonstrate the ability of miniaturized SAW sensors for carrying out on-field monitoring campaigns and their potential to replace the presently used heavy and expensive laboratory instrumentation
Nanofabrication for Molecular Scale Devices
The predicted 22-nm barrier which is seemingly going to put a final stop to Moore’s law is essentially related to the resolution limit of lithography. Consequently, finding
suitable methods for fabricating and patterning nanodevices is the true challenge of
tomorrow’s electronics. However, the pure matter of moulding devices and interconnections
is interwoven with research on new materials, as well as architectural and computational
paradigms. In fact, while the performance of any fabrication process is obviously related to
the characteristic of the materials used, a particular fabrication technique can put constraints
on the definable geometries and interconnection patterns, thus somehow biasing the upper
levels of the computing machine. Further, novel technologies will have to account for heat
dissipation, a particularly tricky problem at the nanoscale, which could in fact prevent the
most performing nanodevice from being practically employed in complex networks. Finally,
production costs – exponentially growing in the present Moore rush – will be a key factor in
evaluating the feasibility of tomorrow technologies.
The possible approaches to nanofabrication are commonly classified into top-down and
bottom-up. The former involves carving small features into a suitable bulk material; in the
latter, small objects assemble to form more complex and articulated structures. While the
present technology of silicon has a chiefly top-down approach, bottom-up approaches are
typical of the nanoscale world, being directly inspired by nature where molecules are
assembled into supramolecular structures, up to tissues and organs. As top-down
approaches are resolution-limited, boosting bottom-up approaches seems to be a good
strategy to future nanoelectronics; however, it is highly unlikely that no patterning will be
required at all, since even with molecular-scale technologies there is the need of electrically
contacting the single elements and this most often happens through patterned metal
contacts, although all-molecular devices were also proposed. Here, we will give some
insight into both top-down and bottom-up without the intention to be exhaustive, because
of space limitations
Gas sensing technologies -- status, trends, perspectives and novel applications
The strong, continuous progresses in gas sensors and electronic noses
resulted in improved performance and enabled an increasing range of
applications with large impact on modern societies, such as environmental
monitoring, food quality control and diagnostics by breath analysis. Here we
review this field with special attention to established and emerging approaches
as well as the most recent breakthroughs, challenges and perspectives. In
particular, we focus on (1) the transduction principles employed in different
architectures of gas sensors, analysing their advantages and limitations; (2)
the sensing layers including recent trends toward nanostructured,
low-dimensional and composite materials; (3) advances in signal processing
methodologies, including the recent advent of artificial neural networks.
Finally, we conclude with a summary on the latest achievements and trends in
terms of applications.Comment: arXiv admin comment: This version has been removed by arXiv
administrators as the submitter did not have the rights to agree to the
license at the time of submissio
Imaging correlated wave functions of few-electron quantum dots: Theory and scanning tunneling spectroscopy experiments
We show both theoretically and experimentally that scanning tunneling
spectroscopy (STS) images of semiconductor quantum dots may display clear
signatures of electron-electron correlation. We apply many-body tunneling
theory to a realistic model which fully takes into account correlation effects
and dot anisotropy. Comparing measured STS images of freestanding InAs quantum
dots with those calculated by the full configuration interaction method, we
explain the wave function sequence in terms of images of one- and two-electron
states. The STS map corresponding to double charging is significantly distorted
by electron correlation with respect to the non-interacting case.Comment: RevTeX 4.0, 5 pages, 3 B/W figures, 1 table. This paper is based on
an invited talk presented by the authors at the 28th International Conference
on the Physics of Semiconductors, which was held 24-28 July 2006, in Vienna,
Austri
Miniaturized Sensors for Detection of Ethanol in Water Based on Electrical Impedance Spectroscopy and Resonant Perturbation Method - A Comparative Study
The development of highly sensitive, portable and low-cost sensors for the evaluation of ethanol content in liquid is particularly important in several monitoring processes, from the food industry to the pharmaceutical industry. In this respect, we report the optimization of two sensing approaches based on electrical impedance spectroscopy (EIS) and complementary double split ring resonators (CDSRRs) for the detection of ethanol in water. Miniaturized EIS sensors were realized with interdigitated electrodes, and the ethanol sensing was carried out in liquid solutions without any functionalization of the electrodes. Impedance fitting analysis, with an equivalent circuit over a frequency range from 100 Hz to 1 MHz, was performed to estimate the electric parameters, which allowed us to evaluate the amount of ethanol in water solutions. On the other hand, complementary double split ring resonators (CDSRRs) were optimized by adjusting the device geometry to achieve higher quality factors while operating at a low fundamental frequency despite the small size (useful for compact electronic packaging). Both sensors were found to be efficient for the detection of low amounts of ethanol in water, even in the presence of salts. In particular, EIS sensors proved to be effective in performing a broadband evaluation of ethanol concentration and are convenient when low cost is the priority. On the other end, the employment of split ring resonators allowed us to achieve a very low limit of detection of 0.2 v/v%, and provides specific advantages in the case of known environments where they can enable fast real-time single-frequency measurements
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