Patents by Inventor Zuyan Shen
Zuyan Shen has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 9431598Abstract: A simple, economical sol-gel method was invented to produce thick and dense lead zirconate titanate (PZT) thin films that exhibit the stoichiometric chemical composition and unprecedented electrical and dielectric properties. The PZT films are the foundation of many microelectromechanical systems (MEMS) and nanoelectromechanical systems (NEMS) for micro/nano sensors and actuators applications.Type: GrantFiled: November 6, 2007Date of Patent: August 30, 2016Assignee: Drexel UniversityInventors: Wei-Heng Shih, Wan Y. Shih, Zuyan Shen, Huidong Li, Xiaotong Gao
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Patent number: 9274087Abstract: A piezoelectric microcantilever for sensing compounds or molecules. The piezoelectric microcantilever, may include at least one electrode, an insulation layer, a receptor, an immobilization layer, a non-piezoelectric layer and a piezoelectric layer The sensor is capable of self actuation and detection. The piezoelectric layer may be constructed from a highly piezoelectric thin lead magnesium niobate-lead titanate film, a highly piezoelectric thin zirconate titanate film, a highly piezoelectric lead-free film. Methods of using the sensors and flow cells and arrays including the sensors are also described.Type: GrantFiled: November 24, 2014Date of Patent: March 1, 2016Assignee: Drexel UniversityInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen, John-Paul McGovern, Qing Zhu, Joseph Capobianco
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Publication number: 20150105294Abstract: A piezoelectric microcantilever for sensing compounds or molecules. The piezoelectric microcantilever, may include at least one electrode, an insulation layer, a receptor, an immobilization layer, a non-piezoelectric layer and a piezoelectric layer The sensor is capable of self actuation and detection. The piezoelectric layer may be constructed from a highly piezoelectric thin lead magnesium niobate-lead titanate film, a highly piezoelectric thin zirconate titanate film, a highly piezoelectric lead-free film. Methods of using the sensors and flow cells and arrays including the sensors are also described.Type: ApplicationFiled: November 24, 2014Publication date: April 16, 2015Applicant: DREXEL UNIVERSITYInventors: WAN Y. SHIH, WEI-HENG SHIH, ZUYAN SHEN, JOHN-PAUL MCGOVERN, QING ZHU, JOSEPH CAPOBIANCO
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Patent number: 8927259Abstract: A piezoelectric microcantilever for sensing compounds or molecules. The piezoelectric microcantilever, may include at least one electrode, an insulation layer, a receptor, an immobilization layer, a non-piezoelectric layer and a piezoelectric layer. The sensor is capable of self actuation and detection. The piezoelectric layer may be constructed from a highly piezoelectric thin lead magnesium niobate-lead titanate film, a highly piezoelectric thin zirconate titanate film, a highly piezoelectric lead-free film. Methods of using the sensors and flow cells and arrays including the sensors are also described.Type: GrantFiled: November 28, 2007Date of Patent: January 6, 2015Assignee: Drexel UniversityInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen, John-Paul Mcgovern, Qing Zhu, Joseph Capobianco
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Patent number: 8857248Abstract: The invention is direct to a piezoelectric microcantilever for static contact and dynamic noncontact atomic force microscopy which may be carried out in solution. The piezoelectric microcantilever, which includes a piezoelectric layer and a non-piezoelectric layer is capable of self actuation and detection. The piezoelectric layer may be constructed from a lead magnesium niobate-lead titanate (Pb(Mg1/3Nb2/3)O3)0.65—(PbTiO3)0.35(PMN0.65-PT0.35) (PMN-PT), zirconate titanate (PZT)/SiO2 or from any lead-free piezoelectric materials such as doped sodium-potassium niobate-lithium niobate. The piezoelectric layers of the microcantilevers may have dielectric constants of from 1600-3000 and thicknesses below 10 ?m. Also disclosed are methods for fabricating microcantilever sensors and methods for atomic force microscopy employing the microcantilevers.Type: GrantFiled: June 14, 2011Date of Patent: October 14, 2014Assignee: Drexel UniversityInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen, Qing Zhu
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Publication number: 20110265227Abstract: The invention is direct to a piezoelectric microcantilever for static contact and dynamic noncontact atomic force microscopy which may be carried out in solution. The piezoelectric microcantilever, which includes a piezoelectric layer and a non-piezoelectric layer is capable of self actuation and detection. The piezoelectric layer may be constructed from a lead magnesium niobate-lead titanate (Pb(Mg1/3Nb2/3)O3)0.65—(PbTiO3)0.35(PMN0.65-PT0.35) (PMN-PT), zirconate titanate (PZT)/SiO2 or from any lead-free piezoelectric materials such as doped sodium-potassium niobate-lithium niobate. The piezoelectric layers of the microcantilevers may have dielectric constants of from 1600-3000 and thicknesses below 10 ?m. Also disclosed are methods for fabricating microcantilever sensors and methods for atomic force microscopy employing the microcantilevers.Type: ApplicationFiled: June 14, 2011Publication date: October 27, 2011Applicant: DREXEL UNIVERSITYInventors: WAN Y. SHIH, WEI-HENG SHIH, ZUYAN SHEN, QING ZHU
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Patent number: 7992431Abstract: The invention is direct to a piezoelectric microcantilever for static contact and dynamic noncontact atomic force microscopy which may be carried out in solution. The piezoelectric microcantilever, which includes a piezoelectric layer and a non-piezoelectric layer is capable of self actuation and detection. The piezoelectric layer may be constructed from a lead magnesium niobate-lead titanate (Pb(Mg1/3Nb2/3)O3)0.65—(PbTiO3)0.35(PMN0.65-PT0.35)(PMN-PT), zirconate titanate (PZT)/SiO2 or from any lead-free piezoelectric materials such as doped sodium-potassium niobate-lithium niobate. The piezoelectric layers of the microcantilevers may have dielectric constants of from 1600-3000 and thicknesses below 10 ?m. Also disclosed are methods for fabricating microcantilever sensors and methods for atomic force microscopy employing the microcantilevers.Type: GrantFiled: November 28, 2007Date of Patent: August 9, 2011Assignee: Drexel UniversityInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen, Qing Zhu
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Publication number: 20100068697Abstract: A piezoelectric microcantilever for sensing compounds or molecules. The piezoelectric microcantilever, may include at least one electrode, an insulation layer, a receptor, an immobilization layer, a non-piezoelectric layer and a piezoelectric layer The sensor is capable of self actuation and detection. The piezoelectric layer may be constructed from a highly piezoelectric thin lead magnesium niobate-lead titanate film, a highly piezoelectric thin zirconate titanate film, a highly piezoelectric lead-free film. Methods of using the sensors and flow cells and arrays including the sensors are also described.Type: ApplicationFiled: November 28, 2007Publication date: March 18, 2010Applicant: DREXEL UNIVERSITYInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen, John-Paul Mcgovern, Qing Zhu, Joseph Capobianco
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Publication number: 20100051447Abstract: A simple, economical sol-gel method was invented to produce thick and dense lead zirconate titanate (PZT) thin films that exhibit the stoichiometric chemical composition and unprecedented electrical and dielectric properties. The PZT films are the foundation of many microelectromechanical systems (MEMS) and nanoelectromechanical systems (NEMS) for micro/nano sensors and actuators applications.Type: ApplicationFiled: November 6, 2007Publication date: March 4, 2010Applicant: DREXEL UNIVERSITYInventors: Wei-Heng Shih, Wan Y. Shih, Zuyan Shen, Huidong Li, Xiaotong Gao
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Publication number: 20090007645Abstract: The invention is direct to a piezoelectric microcantilever for static contact and dynamic noncontact atomic force microscopy which may be carried out in solution. The piezoelectric microcantilever, which includes a piezoelectric layer and a non-piezoelectric layer is capable of self actuation and detection. The piezoelectric layer may be constructed from a lead magnesium niobate-lead titanate (Pb(Mg1/3Nb2/3)O3)0.65—(PbTiO3)0.35(PMN0.65-PT0.35)(PMN-PT), zirconate titanate (PZT)/SiO2 or from any lead-free piezoelectric materials such as doped sodium-potassium niobate-lithium niobate. The piezoelectric layers of the microcantilevers may have dielectric constants of from 1600-3000 and thicknesses below 10 ?m. Also disclosed are methods for fabricating microcantilever sensors and methods for atomic force microscopy employing the microcantilevers.Type: ApplicationFiled: November 28, 2007Publication date: January 8, 2009Applicant: DREXEL UNIVERSITYInventors: WAN Y. SHIH, WEI-HENG SHIH, ZUYAN SHEN, QING ZHU
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Patent number: 7458265Abstract: A piezoelectric cantilever with a non-piezoelectric, or piezoelectric tip useful as mass and viscosity sensors. The change in the cantilever mass can be accurately quantified by monitoring a resonance frequency shift of the cantilever. For bio-detection, antibodies or other specific receptors of target antigens may be immobilized on the cantilever surface, preferably on the non-piezoelectric tip. For chemical detection, high surface-area selective absorbent materials are coated on the cantilever tip. Binding of the target antigens or analytes to the cantilever surface increases the cantilever mass. Detection of target antigens or analytes is achieved by monitoring the cantilever's resonance frequency and determining the resonance frequency shift that is due to the mass of the adsorbed target antigens on the cantilever surface. The use of a piezoelectric unimorph cantilever allows both electrical actuation and electrical sensing.Type: GrantFiled: October 27, 2004Date of Patent: December 2, 2008Assignee: Drexel UniversityInventors: Wan Y. Shih, Wei-Heng Shih, Zuyan Shen
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Publication number: 20070089515Abstract: A piezoelectric cantilever with a non-piezoelectric, or piezoelectric tip useful as mass and viscosity sensors. The change in the cantilever mass can be accurately quantified by monitoring a resonance frequency shift of the cantilever. For bio-detection, antibodies or other specific receptors of target antigens may be immobilized on the cantilever surface, preferably on the non-piezoelectric tip. For chemical detection, high surface-area selective absorbent materials are coated on the cantilever tip. Binding of the target antigens or analytes to the cantilever surface increases the cantilever mass. Detection of target antigens or analytes is achieved by monitoring the cantilever's resonance frequency and determining the resonance frequency shift that is due to the mass of the adsorbed target antigens on the cantilever surface. The use of a piezoelectric unimorph cantilever allows both electrical actuation and electrical sensing.Type: ApplicationFiled: October 27, 2004Publication date: April 26, 2007Applicant: drexel UniversityInventors: Wan Shih, Wei-Heng Shih, Zuyan Shen