New Groove Structures for Miniature Quartz Crystal Microbalance with Low Crystal Impedance

Zong Han Liu; Chih Hsiung Shen

doi:10.4028/www.scientific.net/AMR.538-541.2461

Paper Titles

Melting Characteristics of Equiaxed NH₄Cl Crystals Settling in Superheated NH₄Cl-H₂O Melts
p.2444

Improving in Oxidization Kinetics of Manganese Sulfate Hydrolyzates in Alkaline Solution Media
p.2448

Dynamic Experimental Study on Liquefaction Behavior of Saturated Silts
p.2453

Review of Stratified Charge Research in Oxygen-Enriched and Nitrogen-Enriched Combustion
p.2457

New Groove Structures for Miniature Quartz Crystal Microbalance with Low Crystal Impedance
p.2461

Introduction and Analysis of the Techniques for the Removal of Phenol from Water
p.2466

Study on Adsorption Reaction Dynamics of Fine Hematite
p.2470

Dynamic Performance for the Spindle System of the Composite Grinder Based on Transfer Matrix Method
p.2477

Efficient Sampling Approaches for Stochastic Response Surface Method
p.2481

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 538-541New Groove Structures for Miniature Quartz Crystal...

New Groove Structures for Miniature Quartz Crystal Microbalance with Low Crystal Impedance

Abstract:

Throughout the world, there are numerous of studies on quartz crystal microbalance (QCM). Today, we come up with a new way to reduce both the size of QCM structure and the crystal impedance without lowering the sensitivity. Beyond the conventional design of QCM originally developed in recent years, a new disk shape with multi-groove structures is proposed and investigated thoroughly to realize the miniaturized QCM. Along the miniaturization stage, there are two main approaches to remain the efficiency of vibration. One is to improve the piezoelectric effect which can be further increased by reducing the distance of electric field and the other is to improve the effective area of electric potential flow between the electrodes. Several proposed design with grooves in the disk has been proposed to make effective area larger, crystal impedance lower ,and Q value higher. We will investigate between different groove structures on QCM under the same bias voltage. In this study, we propose and verify the innovative design of QCM and a thorough investigation of the electric and mechanical response were performed with evidence marvelous efficiency. Consequently, the three groove structure gives the best piezoelectric performance than the other.

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Periodical:

Advanced Materials Research (Volumes 538-541)

Pages:

2461-2465

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.538-541.2461

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Online since:

June 2012

Authors:

Zong Han Liu, Chih Hsiung Shen

Keywords:

Groove Design, Piezoelectric Sensor, QCM, QMEMS

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