Discrete microfluidics based on aluminum nitride surface acoustic wave devices

Zhou, Jian; Pang, Hua-Feng; Garcia‐Gancedo, Luis; Iborra, E.; Clément, M.; Miguel-Ramos, M. De; Jin, Hao; Luo, Jikui; Smith, S.; Dong, Shurong; Wang, D. M.; Fu, Yong Qing

doi:10.1007/s10404-014-1456-1

Cited by 47 publications

(44 citation statements)

References 50 publications

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“…SAWs, as well as thickness‐mode bulk waves, can also be generated on thin piezoelectric films (the latter being known as thin film bulk acoustic resonators, and has the advantage of overcoming challenges associated with fabricating interdigitated transducers with micron or submicron widths and thicknesses necessary to generate SAWs at higher (e.g., GHz) frequencies), on which similar azimuthal microfluidic centrifugation flows can be effected. In addition to demonstrating the microvortical flow arising from these devices for various applications, including hydrodynamic particle trapping, biomolecular concentration and the shearing of polyelectrolyte films for drug release, the piezoelectric films can be overlaid onto regular substrates so as to circumvent the need for the piezoelectric substrate as well as to facilitate microfluidic operations on flexible substrates . To however separate the actuator from the microfluidic components, so as to enable reuse of the actuator (i.e., the piezoelectric chip) while facilitating a disposable option for the microfluidic chip, it is necessary to transmit the SAW vibration through a liquid couplant into a superstrate (e.g., a low‐cost and hence disposable chip on which the microfluidic operations are to be carried out as opposed to the reusable higher‐cost piezoelectric substrate to drive the microfluidic actuation), as first shown by Hodgson et al, or even a capillary tube .…”

Section: Active Actuationmentioning

confidence: 99%

On‐Chip Generation of Vortical Flows for Microfluidic Centrifugation

Ahmed

Ramesan

Lee

et al. 2019

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Microcentrifugation constitutes an important part of the microfluidic toolkit in a similar way that centrifugation is crucial to many macroscopic procedures, given that micromixing, sample preconcentration, particle separation, component fractionation, and cell agglomeration are essential operations in small scale processes. Yet, the dominance of capillary and viscous effects, which typically tend to retard flow, over inertial and gravitational forces, which are often useful for actuating flows and hence centrifugation, at microscopic scales makes it difficult to generate rotational flows at these dimensions, let alone with sufficient vorticity to support efficient mixing, separation, concentration, or aggregation. Herein, the various technologies—both passive and active—that have been developed to date for vortex generation in microfluidic devices are reviewed. Various advantages or limitations associated with each are outlined, in addition to highlighting the challenges that need to be overcome for their incorporation into integrated microfluidic devices.

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Section: Active Actuationmentioning

confidence: 99%

On‐Chip Generation of Vortical Flows for Microfluidic Centrifugation

Ahmed

Ramesan

Lee

et al. 2019

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“…where σ 1 is a tensile stress (Pa), σ 2 is a maximum bending stress (Pa), ψ 1 (u) were obtained graphically for the stress-strain curve. The maximum stress values obtained were σ max = 141.8 MPa and 106.8 MPa for the quartz ST-cut and the lithium niobate YX-128 • -cut, accordingly [8,9,13]. These values were used in further mathematical models and computer simulations.…”

Section: Model Implementation and Computer Simulationsmentioning

confidence: 99%

“…In the current literature, various aspects of SAW sensor design and its manufacturing technology have been investigated thoroughly. Issues considered in recent literature include the choice of the sensitive element material [6,8,9], and the possibility of passive implementation with a wireless interface [10][11][12]. Acceleration measurements represent a prominent application possibility [13], where the proposed class of solutions has the potential to develop serial devices characterized by enhanced robustness and the implementation of high-G values, as indicated by a series of recent publications [14][15][16][17], including some developments by our research team [18,19].…”

Section: Introductionmentioning

confidence: 99%

Ring-Shaped Sensitive Element Design for Acceleration Measurements: Overcoming the Limitations of Angular-Shaped Sensors

2019

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A new modification of an acceleration measurement sensor based on an acoustic waves resonance principle is proposed. Common angular-shaped sensors exhibit stress concentrations at the angular points near the origin points of destruction under external stresses; these points are the "Achilles' heel" of the entire design. To overcome the above limitation, we suggest an angular-free ring-shaped sensitive element design that is characterized by enhanced robustness against external stress. The analytical treatment is validated by computer simulation results performed using the COMSOL Multiphysics software package. For an appropriate model parameterization, an original experiment has been carried out to estimate the stress-strained robustness of two potential candidates for sensitive console materials. Moreover, characteristics of the proposed sensor design, such as sensitivity threshold and maximum stress, have been obtained from the simulation data. The above results indicate that the proposed concept offers a promising advancement in surface acoustic waves (SAW) based accelerometer devices, and could, therefore, be used for several practical applications in such areas as biomedical and sports wearable devices; vehicular design, including unmanned solutions; and industrial robotics, especially those where high-G forces are expected.

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“…Specifically, the micron-sized droplet technique, with the characteristics of stable injection and full dispersion, constitutes an important development direction in these fields [10]. To realize the above-mentioned objectives, surface acoustic wave atomizer [11] and static mesh atomizer [12] can suffer high pressure across the whole system, which inevitably results in high-energy consumption, high cost, and high loss. Furthermore, structures of this type have a low energy utilization rate in which their atomization process is random and uncontrollable, and are also extremely inconvenient to carry and practical use [13].…”

Section: Introductionmentioning

confidence: 99%

Study on the Influencing Factors of the Atomization Rate in a Piezoceramic Vibrating Mesh Atomizer

2020

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On the basis of previous study in our research group, the phenomenon of the dynamic tapered angle was founded, the occurrence of atomization is regarded to derive from the combined effects of the dynamic variation of the micro-tapered aperture, and the difference between forward and reverse flow resistance has been explained by both theories and experiments. It has been revealed that the main influencing factors of the atomization rate are driving voltage, driving frequency, and so on, while the root causes of the various atomization rates still need to be further clarified. In this paper, a micro-tapered aperture worked as a micron-sized tapered flow tube valveless piezoelectric pump in periodic variation. The working principle of such a micro-tapered aperture atomizer was analyzed in detail, and the corresponding formula of the atomization rate was also established. Through measuring the atomization rates at different working frequencies (f), it was established that when the f was set as 122 kHz, the atomization rate reached a maximum value. By building the relationship between the atomization rate and voltage at a fixed resonance frequency, it can be seen that the atomization rate increased with the increase of driving voltage. Subsequently, in order to measure their atomization rates, the micro-tapered apertures of three different outlet diameters were applied, so that the atomization rate was enhanced with the increase of the micro-tapered aperture diameter. Moreover, through examining the atomization rates at different temperatures, it was observed that the atomization rate rose with increasing temperature; while changing the liquid concentration, the atomization rate was also enhanced by the increase in its concentration. Apparently, the impact factors including working frequency, driving voltage, outlet diameter, temperature, and liquid concentration all exert some effects on the atomization rate. It is worth noting that at the first stage, these influence factors indirectly work on the micro-tapered aperture structure or flow state, followed by further effects on the flow resistance. As above-mentioned, in this work, we considered that the root cause influencing the atomization rate in a piezoceramic vibrating mesh atomizer can be attributed to the flow resistance.

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Discrete microfluidics based on aluminum nitride surface acoustic wave devices

Cited by 47 publications

References 50 publications

On‐Chip Generation of Vortical Flows for Microfluidic Centrifugation

On‐Chip Generation of Vortical Flows for Microfluidic Centrifugation

Ring-Shaped Sensitive Element Design for Acceleration Measurements: Overcoming the Limitations of Angular-Shaped Sensors

Study on the Influencing Factors of the Atomization Rate in a Piezoceramic Vibrating Mesh Atomizer

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