{"id":426,"date":"2016-08-17T18:49:14","date_gmt":"2016-08-17T22:49:14","guid":{"rendered":"https:\/\/mae.ncsu.edu\/jiang\/?page_id=426"},"modified":"2024-08-19T14:03:47","modified_gmt":"2024-08-19T18:03:47","slug":"xiaonings-cv","status":"publish","type":"page","link":"https:\/\/mae.ncsu.edu\/jiang\/members\/xiaonings-cv\/","title":{"rendered":"Xiaoning’s CV"},"content":{"rendered":"
\n

Xiaoning Jiang, Ph.D.<\/h2>\n

\"jiang\"<\/p>\n

\n

Dean F. Duncan Distinguished Professor, Department of Mechanical and Aerospace Engineering
\nAdjunct Professor, UNC-Chapel Hill & NC State Joint Department of Biomedical Engineering
\nUniversity Faculty Scholar<\/p>\n

911 Oval Drive
\n3282 Engineering Building III
\nCampus Box 7910
\nNorth Carolina State University, Raleigh, NC<\/p>\n

Tel: 919-515-5240
\nFax: 919-515-7968
\nEmail:\u00a0xjiang5@ncsu.edu<\/a><\/p>\n<\/div>\n<\/div>\n

\n

EDUCATION<\/h3>\n
\n\n\n\n\n\n\n\n
Postdoc<\/td>\n1997-2001<\/td>\nThe Pennsylvania State University<\/td>\n<\/tr>\n
Postdoc<\/td>\n1996-1997<\/td>\nNanyang Technological University<\/td>\n<\/tr>\n
Ph.D.<\/td>\n1997<\/td>\nPrecision Instruments, Tsinghua University<\/td>\n<\/tr>\n
M.S.<\/td>\n1992<\/td>\nMechanical Engineering, Tianjin University<\/td>\n<\/tr>\n
B.S.<\/td>\n1990<\/td>\nMechanical Engineering, Shanghai Jiaotong University<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n
\n

 <\/p>\n<\/div>\n<\/div>\n

\n

PROFESSIONAL EXPERIENCE<\/h3>\n
\n

Nov. 2009- present\u00a0<\/strong> \u00a0 NC State University, Raleigh, NC.<\/em><\/p>\n

Distinguished Professor, Nov. 2018-present: Mechanical and Aerospace Engineering
\nFull Professor, July 2015- present: Mechanical and Aerospace Engineering
\nTenured Associate Professor July 2013 -June 2015: Mechanical and Aerospace Engineering
\nTenure Track Associate Professor, Nov. 2009 \u2013 June 2013: Mechanical and Aerospace Engineering
\nAdjunct Professor of Biomedical Engineering 2010-present
\nUniversity faculty Scholar, 2017-
\nResearch smart M\/NEMS, nanoengineering, micromachined ultrasound transducers, renewable power, high frequency ultrasound, intravascular ultrasound imaging and therapy, ultrasound NDT\/NDE, electromechanical sensors, actuators, and transducers for medicine, biology and industrial applications. Teach undergraduate and graduate courses. Provide on-campus and off-campus services.<\/p>\n

August 2016-January 2017<\/strong> City University of Hong Kong, Hong Kong<\/em><\/p>\n

Visiting Professor<\/p>\n

2001-2009<\/strong> TRS Technologies, Inc., State College, PA.<\/em><\/p>\n

Vice President for Technology 2008 -2009
\nChief Scientist 2007-2009
\nCompany management team member 2006-2009
\nSenior Research Scientist 2005-2007
\nResearch Scientist 2001-2005
\nPrimary research focus was to research and develop novel piezoelectric transducers, sensors, and actuators. Research was mainly funded by NASA, NIH, DOD, and medical industry.<\/p>\n

2001<\/strong> Standard MEMS, Inc., Long Island, NY.<\/em><\/p>\n

R&D Engineer 2001
\nResearched and developed MEMS product including pressure sensors, gas sensors and microphone.<\/p>\n

1997-2001 <\/strong>The Pennsylvania State University, University Park, PA.<\/em><\/p>\n

Research Associate 2000-2001
\nPostdoctoral Scholar 1997-1999
\nResearched and developed novel micromanufacturing including – laser direct write (microstereolithography) of 3D structures and thick films of polymer, ceramics (alumina, silica, piezoelectric ceramics (PZT), etc.), and metals on silicon substrate. Taught <MEMS and Smart Structures>, <RF MEMS> courses for Undergraduate and Graduate students.<\/p>\n

1996-1997<\/strong> Nanyang Technological University, Singapore<\/em><\/p>\n

Postdoctoral Fellow in School of MPE
\nResearched Microfluid flow and microcooling for electronics.<\/p>\n

1992-1996<\/strong> Department of Precision Instruments and Mechanology, Tsinghua University, Beijing, China.<\/em><\/p>\n

Research Assistant on Microelectromechanical Systems
\nTeaching Assistant on Mechanical Design and Drawing for undergraduate students.
\nInvestigated microfluid flow through microchannels with various cross sections, and eveloped Si micro-valves and micropumps for microfluid handling systems.<\/p>\n

1990-1992<\/strong> Department of Mechanical Engineering, Tianjin University, Tianjin, China.<\/em><\/p>\n

Research Assistant on Robot control.
\nMeasured pose error of an assembly robot and developed a pose error compensation algorithm.<\/p>\n<\/div>\n<\/div>\n

\n

SCHOLARLY AND PROFESSIONAL HONORS, ORGANIZATIONS AND AWARDS<\/h3>\n
    \n
  • Dean F. Duncan Distinguished Professorship (2020-)<\/li>\n
  • Co-Editor-in-Chief, IEEE Nanotechnology Magazine (2020-)<\/li>\n
  • IEEE Ultrasonics Symposium Student Paper Competition Award (2020, Advisor of the student
    \nwinner)<\/li>\n
  • 1st<\/sup> Prize of 2019 ASME Track-BioMed Student Paper Competition (2019, Advisor)<\/li>\n
  • Distinguished Lecturer, IEEE Nanotechnology Council (2018, 2019)<\/li>\n
  • 1st<\/sup> Prize of 2018 IEEE NMDC Student Paper Competition (2018, Advisor)<\/li>\n
  • University Faculty Scholar, NC State University (2017-)<\/li>\n
  • R&D100 Award finalist\u2014Special Recognition, 2016.<\/li>\n
  • IEEE Ultrasonics Symposium Student Paper Competition Award (2016, Advisor of the student winner)<\/li>\n
  • Departmental graduate symposium 1st Prize (out of 80 PhD students), 2016. (Advisor)<\/li>\n
  • IDTechEx Best Technical Development within Energy Harvesting and Storage Award, 2015.<\/li>\n
  • ASME IMECE Track-3 PhD Student Paper Competition 2nd Prize, 2015. (Advisor)<\/li>\n
  • NC State MAE Research Excellence Award, 2015.<\/li>\n
  • NC State Chancellor Innovation Funds award, 2015.<\/li>\n
  • NC State MAE Outstanding Research Award, 2014.<\/li>\n
  • IEEE UFFC Representative in IEEE Nanotechnology Council, 2014-present.<\/li>\n
  • DOD DURIP Award, 2013.<\/li>\n
  • ASNT Faculty Grant recipient, 2013.<\/li>\n
  • Best Research Publication, National Institute of Aerospace (\u201cA Piezoelectric Multi-layer-stacked Hybrid Actuation\/Transduction System\u201d by Tian-Bing Xu, Xiaoning Jiang, and Ji Su, Applied Physics Letters, Vol. 98, p.243503, 2011)<\/li>\n
  • IEEE Ultrasonics Symposium Student Paper Competition Award (2011, Advisor)<\/li>\n
  • Winner, Best Technology Development of Energy Harvesting, IDTechEx (2011)<\/li>\n
  • NC State Faculty Research and Professional Development Award, 2010.<\/li>\n
  • 2nd<\/sup> prize of Beijing Science and Technology Progress Award. 2009.<\/li>\n
  • 6 Certificates of Recognition for Invention, NASA Inventions and Contributions Board, 2008-2013.<\/li>\n
  • First Prize of China Instrument Society Scholarship, 1996.<\/li>\n
  • Gaotian Scholarship of Tsinghua University, 1994.<\/li>\n
  • First Order of Guanghua Scholarship of Tsinghua University, 1993.<\/li>\n
  • First Order Scholarship of Tianjin University, 1991.<\/li>\n
  • Six times, the People Scholarship of Shanghai Jiaotong University. 1986-1990.<\/li>\n
  • American Society of Mechanical Engineers (ASME, Fellow)<\/li>\n
  • The Institute of Electrical and Electronics Engineers (IEEE, Senior Member)<\/li>\n
  • The International Society for Optics and Photonics (SPIE, Senior Member)<\/li>\n<\/ul>\n

    STUDENTS RECEIVED PHD DEGREES UNDER DR. JIANG\u2019S ADVISORY<\/span><\/p>\n<\/div>\n

    \n
      \n
    • Howuk Kim, \u201cDesign, Fabrication, and Validation of Noninvasive Sensors for Nuclear Power Plant Applications\u201d, Dec. 2019. (Now Postdoc at NC State)<\/li>\n
    • Shujin Huang, \u201cStudy on flexoelectric materials, structures and their applications\u201d, Dec. 2018. (Now Engineer at ASM International)<\/li>\n
    • Wei-Yi Chang, \u201cNovel nanocomposites for piezoelectric and photoacoustic transduction structures\u201d, Nov. 2018. (Now Scientist at CTS)<\/li>\n
    • Taeyang Kim, \u201cNovel Piezoelectric Sensors: Design, Prototyping and Characterization\u201d, April 2018. (Now Assistant Professor at Korea Military Academy, South Korea)<\/li>\n
    • Jinwook Kim, \u201cMiniaturized Ultrasound Transducers for the Acoustic Excitation of Microbubbles and Microgels\u201d, June 2017. (Now Postdoc at UNC Chapel Hill)<\/li>\n
    • Sibo Li, \u201cStudy on Micromachined Piezoelectric Material and Dual-layer Transducers for Ultrasound Imaging\u201d, April 2017. (Now Scientist at Philipps Medical)<\/li>\n
    • Zhuochen Wang, \u201cDual-frequency Ultrasound Transducers for Medical Imaging\u201d, October 2016. (Now Assistant Professor at Tianjin University)<\/li>\n
    • Laura Tollier, \u201cStudy on Novel Piezoelectric Transduction Structures\u201d, July 2016. (Now in SPAWAR Systems Center)<\/li>\n
    • Sijia Guo, \u201cHigh-Intensity Ultrasound in Adherent Cell Sorting and Tissue Ablation\u201d, May 2015. (Now Postdoc at Univ. of Maryland)<\/li>\n
    • Seol Ryung Kwon, \u201cFlexoelectricity of Barium Strontium Titanate and Its Applications\u201d, Dec. 2014.<\/li>\n
    • Wenbin Huang, \u201cStudy on Strain Gradient Sensing and Flexoelectric Micro\/Nano Structures\u201d, Dec. 2014. (Now specially appointed Professor at Chongqing Univ.)<\/li>\n
    • Jianguo Ma, \u201cMulti-frequency Ultrasound Transducers and Their Applications in Tissue Ablation and Intravascular Acoustic Angiography\u201d, Dec. 2014. (Now Associate Professor at Beihang University)<\/li>\n
    • Kyungrim Kim, \u201cNovel Shear Mode Piezoelectric Sensors and Their Applications\u201d, Dec. 2013. (Now Engineer at Samsung, Korea)<\/li>\n<\/ul>\n<\/div>\n

      STUDENTS RECEIVED MS DEGREES UNDER DR. JIANG\u2019S ADVISORY<\/span><\/p>\n

        \n
      • Japen Karmesh Mehta, \u201cCalculation of flexoelectric effect in cantilever beam structures using Jiang\u2019s resume (as of Nov. 2020) theoretical and experimental approaches\u201d, May 2020.<\/li>\n
      • Karthik Narasimhan, \u201cDesign and Finite Element Analysis of 1-3 Flexible Composite Transducer for Non-Destructive Testing of Aircraft HVAC Pipes\u201d, May 2017.<\/li>\n
      • Joseph Johnson, \u201cHigh-Temperature Yttrium Calcium Oxyborate Acoustic Emission Sensor\u201d, Dec. 2013.<\/li>\n
      • Satyaraj Ghangam, May 2013.<\/li>\n
      • Guang Yang, May 2012.<\/li>\n
      • Saurabh Bakshi, \u201cCell Characterization Using High Frequency Ultrasound\u201d, May 2012.<\/li>\n
      • Vishal Kulkarni, \u201cFlexible Two-dimensional Ultrasonic Transducer Array: Design, Fabrication and Characterization\u201d, Dec. 2011.<\/li>\n<\/ul>\n
        \n

        POSTDOCS CURRENTLY UNDER DR. JIANG\u2019S ADVISORY<\/span><\/h3>\n
          \n
        • Dr. Howuk Kim (PhD @ NC State), 2020-present<\/li>\n
        • Dr. Chang Peng(PhD @ UFlorida), 2018-present<\/li>\n<\/ul>\n

          PHD STUDENTS CURRENTLY UNDER DR. JIANG\u2019S ADVISORY<\/span><\/h3>\n
            \n
          • Huaiyu Wu, 2016-present<\/li>\n
          • Bohua Zhang, 2017-present<\/li>\n
          • Howuk Kim, 2018-present<\/li>\n
          • Qianqian Cai, 2018-present<\/li>\n
          • Leela Devi Goel. 2018-present<\/li>\n
          • Haotian Wan, 2018-present<\/li>\n
          • Mengyue Chen, 2019-present<\/li>\n
          • Andrew Tormanen, 2020-present<\/li>\n<\/ul>\n

            POSTDOCTORAL FELLOWS, VISITING SCHOLARS AND STUDENTS SUPERVISED BY DR. JIANG AND THEIR CURRENT AFFILIATION (IF KNOWN):<\/span><\/h3>\n
              \n
            1. Dr. Chengtao Luo, 2017-2020 (Now Assistant Professor @ Shanghai Jiaotong University)<\/li>\n
            2. Mr. Chang Liu, 2019-2020 (Visiting Student)<\/li>\n
            3. Mr. Yangbin Liu, 2019-2020 (Visiting Student)<\/li>\n
            4. Dr. Di Wu, 2018 (Research Scholar)<\/li>\n
            5. Dr. Jinwook Kim, 2017-present (Postdoc, w\/Dr. Paul Dayton)<\/li>\n
            6. Dr. Jianlong Ji, 2018-2019 (Visiting Scholar)<\/li>\n
            7. Prof. Shengjie Zhou, 2018 (Visiting Professor)<\/li>\n
            8. Mr. Fan Zhang, 2017-2018 (Visiting Student)<\/li>\n
            9. Dr. Xiezhao Lin, 2017- 2018 (Visiting Scholar)<\/li>\n
            10. Ms. Shijing Sang, 2017-2018 (Visiting Student)<\/li>\n
            11. Mr. Zhongyuan Yuan, 2017-2018 (Visiting Student)<\/li>\n
            12. Dr. Brooks Lindsey, 2015-2017 (w\/Dr. Paul Dayton, now Faculty, Georgia Tech)<\/li>\n
            13. Mr. Lu Qi, 2016-2017 (Visiting PhD Student)<\/li>\n
            14. Dr. Hao Feng, 2016-2017 (Faculty, Tianjin University)<\/li>\n
            15. Dr. Pelin Berik, 2016-2017 (Postdoc)<\/li>\n
            16. Dr. Zhiwu An, 2015- 2016 (Chinese Academy of Science)<\/li>\n
            17. Dr. Wenbin Huang, 2015 (Chongqing University, China)<\/li>\n
            18. Dr. Yongbin Liu, 2014-2015 (Anhui University, China)<\/li>\n
            19. Dr. Hui Zhang, 2014-2015 (Tianjin University, China)<\/li>\n
            20. Mr. Longlong Shu, 2013 (Xi\u2019an Jiaotong University, China)<\/li>\n
            21. Dr. Xiaohua Jian, 2013 (Suzhou Institute of Biomedical Engineering and Technology, China)<\/li>\n
            22. Dr. Di Wu, 2013 (Beijing Jiaotong University, China)<\/li>\n
            23. Dr. Won Tae Kwon, 2012 (University of Seol, Korea)<\/li>\n<\/ol>\n

              LIST OF COURSES TAUGHT WITH ENROLLMENT IN EACH.<\/h3>\n<\/div>\n
              \n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n\n
              Year<\/td>\nSemester<\/td>\nCourse No.<\/td>\nCourse Title\/enrollment<\/td>\nEvaluation\/Dep. Avg.<\/td>\n<\/tr>\n
              2010<\/td>\nSpring<\/td>\nMAE 314-004<\/td>\nSolid Mechanics \/26<\/td>\n3.5\/3.9<\/td>\n<\/tr>\n
              2010<\/td>\nFall<\/td>\nMAE 435-002<\/td>\nPrinciples of Automatic Control \/29<\/td>\n3.7\/3.9<\/td>\n<\/tr>\n
              2011<\/td>\nSpring<\/td>\nMAE 314-003<\/td>\nSolid Mechanics \/40<\/td>\n4.6\/4.0<\/td>\n<\/tr>\n
              2011<\/td>\nFall<\/td>\nMAE 314-002<\/td>\nSolid Mechanics \/46<\/td>\n3.9\/4.0<\/td>\n<\/tr>\n
              2011<\/td>\nFall<\/td>\nMAE 495-001<\/td>\nIntroduction to Multidisciplinary Nanotechnology Laboratory \/14<\/td>\n4.0\/4.0<\/td>\n<\/tr>\n
              2012<\/td>\nSpring<\/td>\nMAE 314-002<\/td>\nSolid Mechanics \/35<\/td>\n4.7\/4\/0<\/td>\n<\/tr>\n
              2012<\/td>\nSpring<\/td>\nMAE 589-002<\/td>\nMicro Transducer \/19<\/td>\n4.8\/4.4<\/td>\n<\/tr>\n
              2012<\/td>\nFall<\/td>\nMAE 495-001<\/td>\nNon-destructive Testing and Evaluation \/15<\/td>\n4.6\/3.9<\/td>\n<\/tr>\n
              2014<\/td>\nSpring<\/td>\nMAE 532<\/td>\nSmart Structures and Micro-Transducer \/14<\/td>\n4.3\/4.5<\/td>\n<\/tr>\n
              2014<\/td>\nFall<\/td>\nMAE 495-001<\/td>\nNon-destructive Testing and Evaluation \/15<\/td>\n4.6\/3.9<\/td>\n<\/tr>\n
              2015<\/td>\nSpring<\/td>\nMAE 314-002<\/td>\nSolid Mechanics \/54<\/td>\n4.3\/3.9<\/td>\n<\/tr>\n
              2015<\/td>\nSpring<\/td>\nMAE 532<\/td>\nSmart Structures and Micro-Transducer \/11<\/td>\n4.5\/4.3<\/td>\n<\/tr>\n
              2015<\/td>\nFall<\/td>\nMAE 495-001<\/td>\nNon-destructive Testing and Evaluation \/15<\/td>\n4.7\/4.0<\/td>\n<\/tr>\n
              2016<\/td>\nSpring<\/td>\nMAE 314-001<\/td>\nSolid Mechanics \/64<\/td>\n4.4\/4.1<\/td>\n<\/tr>\n
              2016<\/td>\nSpring<\/td>\nMAE 532<\/td>\nSmart Structures and Micro-Transducer \/14<\/td>\n4.6\/4.4<\/td>\n<\/tr>\n
              2017<\/td>\nFall<\/td>\nMAE 440<\/td>\nNon-destructive Testing and Evaluation \/13<\/td>\n4.8\/3.9<\/td>\n<\/tr>\n
              2018<\/td>\nSpring<\/td>\nMAE 214<\/td>\nSolid Mechanics \/80<\/td>\n4.0\/4.0<\/td>\n<\/tr>\n
              2018<\/td>\nSpring<\/td>\nMAE 532<\/td>\nSmart Structures and Micro-Transducer \/14<\/td>\n4.7\/4.2<\/td>\n<\/tr>\n
              2018<\/td>\nFall<\/td>\nMAE 440<\/td>\nNon-destructive Testing and Evaluation \/33<\/td>\n3.8\/4.0<\/td>\n<\/tr>\n
              2018<\/td>\nFall<\/td>\nMAE 214<\/td>\nSolid Mechanics \/58<\/td>\n4.1\/4.0<\/td>\n<\/tr>\n
              2019<\/td>\nFall<\/td>\nMAE 214<\/td>\nSolid Mechanics \/62<\/td>\n3.0\/4.0<\/td>\n<\/tr>\n
              2019<\/td>\nFall<\/td>\nMAE 532<\/td>\nSmart Structures and Micro-Transducer \/17<\/td>\n4.8\/4.5<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/div>\n
              \n

              RESEARCH INTEREST AND CURRENT PROJECTS<\/h3>\n
              \n

              Micro\/nanofabrications with smart materials and structures incorporation; micro\/nano-sensors, actuators and transducers; biomedical devices; ultrasound imaging for medical and industrial NDE\/NDT applications; ultrasound in medicine and biology; high power ultrasonic therapies; ultrasonic drug delivery; sensors and actuators for extreme environment.<\/p>\n

              The budget total of externally and internally sponsored grants, contracts and gifts that support my scholarship is more than $18M<\/em><\/strong>. The research at NCSU since Nov. 2009 has been supported by ~ $10.2M, <\/em><\/strong>with my portion of ~ $5.8M<\/em><\/strong>.<\/p>\n

              Current\/Awarded Projects <\/em>(<\/em>Total: $5,574,483[1]<\/sup>; Jiang\u2019s portion: $2,791,788<\/span><\/em>)<\/em><\/span><\/p>\n<\/div>\n

                \n
              1. Title: Prevent Unnecessary Carotid Intervention and Stroke using Noninvasive Transcutaneous Ultrasound Thermal Strain Imaging (US-TSI)
                \nAgency\/Program: NIH\/UPitt
                \nDuration: June 15, 2020 \u2013 May 31, 2024
                \nPI: Kang Kim (UPitt)
                \nAmount: $442,802*<\/li>\n
              2. Title: Domain-Engineering Enabled Thermal Switching in Ferroelectric Materials
                \nAgency\/Program: NSF
                \nDuration: July 01, 2020 \u2013 June 30, 2024
                \nPI: Jun Liu (Co-PIs: Xiaoning Jiang, Divine Philip Kumah)
                \nAmount: $558,645*<\/li>\n
              3. Title: Development of a Miniaturized Multidirectional Ultrasound Ablation Array (MiDUSa) for Endobronchoscopic Lung Nodule Ablation
                \nAgency\/Program: UNC Lineberger Cancer Center
                \nDuration: August 01, 2020 \u2013 August 01, 2021
                \nPI: Cole Burks (Co-PIs: Yueh Lee, Xiaoning Jiang and Gianmarco Pinton)
                \nAmount: $29,312<\/li>\n
              4. Title: Dual Excitation Catheter-delivered Laser Ultrasound Thrombolysis System (declut) For Deep Vein Thrombolysis
                \nAgency\/Program: NIH\/SonoVascular, Inc.
                \nDuration: August 15, 2020 \u2013 July 31, 2021
                \nPI: Xiaoning Jiang
                \nAmount: $150,000<\/li>\n
              5. Title: Forward viewing catheter-delivered microbubble enhanced sonothrombolysis (FVCAMUS)
                \nAgency\/Program: NIH
                \nDuration: August 15, 2018 \u2013 June 30, 2022
                \nPI: Xiaoning Jiang
                \nAmount: $2,286,591<\/li>\n
              6. Title: Photoacoustic-imaging-Guided Intravascular Sonothrombolysis
                \nAgency\/Program: NIH
                \nDuration: June 1, 2019 \u2013 May 31, 2021
                \nPI: Xiaoning Jiang (Co-PI: Dr. Junjie Yao)
                \nAmount: $411,010*<\/li>\n
              7. Title: Effect of AC Poling on Dielectric and Piezoelectric Properties of Relaxor Single Crystals for Acoustic Sensors
                \nAgency\/Program: ONR
                \nDuration: June 1, 2018 \u2013 May 31, 2021
                \nPI: Xiaoning Jiang
                \nAmount: $496,435*<\/li>\n
              8. Title: High Temperature Embedded\/integrated Sensors (hiteis) for Remote Monitoring Of Reactor and Fuel Cycle Systems
                \nAgency\/Program: DOE
                \nDuration: October 1, 2017 \u2013 Sept. 30, 2020
                \nPI: Xiaoning Jiang (Co-PIs: Dr. Mohamed Bourham, and Dr. Mo-Yuen Chow)
                \nAmount: $999,688<\/li>\n
              9. Piezoelectric devices (Gift Grant)
                \nAgency\/Program: Industry
                \nDuration: Nov. 2011 \u2013
                \nPI: Xiaoning Jiang
                \nAmount: $100,000<\/li>\n
              10. Medical Ultrasound (Gift Grant)
                \nAgency\/Program: Industry
                \nDuration: September 2012 \u2013
                \nPI: Xiaoning Jiang
                \nAmount: $50,000<\/li>\n
              11. BioMedical Ultrasound (Gift Grant)
                \nAgency\/Program: Industry
                \nDuration: May 2017 \u2013
                \nPI: Xiaoning Jiang
                \nAmount: $50,000<\/li>\n<\/ol>\n

                [1] Estimated amount is considered for the awards under incremental funding or contract in negotiation (awards denoted with *)<\/span><\/p>\n

                Past Projects (After joining NCSU total: $4,152,322; Jiang\u2019s portion: $2,635,349):<\/em><\/strong><\/span><\/p>\n

                  \n
                1. \u201cNovel Biomedical Ultrasound Sensors\u201d, Goodix, February 20, 2018 \u2013 May 19, 2020, $200,658, Principal Investigator.<\/li>\n
                2. \u201cForward-viewing intravascular transducers for thrombolysis\u201d, SonoVascular, Inc., Dec 1, 2018 \u2013 April 1, 2020, $31,772, Principal Investigator.<\/li>\n
                3. \u201cULTRA \u2013 Ultrasound for Resource-limited Areas\u201d, UNC – UNC Chapel Hill (Prime–Bill and Melinda Gates Foundation), May 16, 2018 \u2013 April 30, 2020, $150,000, Principal Investigator.<\/li>\n
                4. \u201cUltrasonic Characterization of Atherosclerotic Plaque using Multiple Scattering\u201d, NIH, September 30, 2016 \u2013 July 31, 2019, $137,966, Co-I (PI: Dr. Marie Muller).<\/li>\n
                5. \u201ceVisR Ultrasound Assessment of Dystrophic Muscle Degeneration in Boys with Duchenne Muscular Dystrophy Using a Custom Row-Column Transducer Array\u201d, UNC TraCS, March 01, 2017 \u2013 February 28, 2019, $25,000, Principal Investigator.<\/li>\n
                6. \u201cSurface and Domain Nano-Engineering of Relaxor Single Crystal for Acoustic Sensors\u201d, ONR, June 01, 2015 \u2013 August 31, 2018, $362,105, Principal Investigator (Co-PI: Dr. Chih-Hao Chang).<\/li>\n
                7. \u201cDual-frequency intravascular arrays for functional imaging of atherosclerosis\u201d, NIH, August 01, 2012 \u2013 May 31, 2018, $2,035,875, Principal Investigator (Co-I: Paul Dayton).<\/li>\n
                8. \u201cNext generation tools for quantitative imaging and analysis of cancer-associated angiogenesis in breast cancer\u201d, UNC Lineberger, October 01, 2016 \u2013 September 30, 2018, $20,000, Principal Investigator.<\/li>\n
                9. \u201cFlexoelectricity in Nanostructures: Theory, Nanofabrication and Characterization\u201d, ARO, October 01, 2011 \u2013 June 30, 2017, $529,162, Principal Investigator (with Co-PI Dr. Fuh-Gwo Yuan).<\/li>\n
                10. \u201cPerformance Evaluation of High Temperature NDE Sensors\u201d, EPRI, June 06, 2016 \u2013 June 30, 2017, $15,000, Principal Investigator.<\/li>\n
                11. \u201cDesign and Analysis of a Lead-Free d36 in-Plane Shear-Based Piezoelectric Torsion Transducer\u201d, Max Kade Foundation, April 29, 2016 \u2013 April 28, 2017, $55,200, Principal Investigator.<\/li>\n
                12. \u201cEvaluation of Flexible Micropost Arrays for Shear Stress Measurement\u201d, NASA, July 10, 2014 \u2013 July 09, 2016, $144,622, Principal Investigator (Co-PIs: Dr. Yong Zhu, Dr. Ashok Gopalarathnam).<\/li>\n
                13. \u201cPiezoelectric Composite Micromachined Multifrequency Transducers for High-Resolution, High-Contrast Ultrasound Imaging for Improved Prostate Cancer Assessment\u201d, UNC\/DOD, August 01, 2012 \u2013 July 31, 2016, $161,407, Principal Investigator.<\/li>\n
                14. \u201cLaser Ultrasound Patch Using Carbon Nanofiber Composites\u201d, NCSU RISF, July 01, 2015 \u2013 June 30, 2016, $25,000, Principal Investigator (Co-PIs: Dr. Xiangwu Zhang, Dr. Tiegang Fang, Dr. Zhen Gu).<\/li>\n
                15. \u201cA Tumor Locating Device and Instrument for Needle Biopsy\u201d, BioSono\/NIH, October 01, 2014 \u2013 June 30, 2015, $43,640, Principal Investigator.<\/li>\n
                16. \u201cIn-Vivo Evaluation of Multi-frequency Ultrasound Transducers for Intravascular Applications\u201d, NC State\u2014CIF, August 01, 2014 \u2013 July 31, 2015, $74,999, Principal Investigator (Co-PI: Dr. Paul Dayton)<\/li>\n
                17. \u201cFlexoelectric Strain Gradient Sensors- a New Sensing Technology for In-situ Structure Health Monitoring\u201d, NSF-CMMI, May 01, 2011-April 30, 2015, $260,001, Principal Investigator (Co-PI: Dr. Fuh-Gwo Yuan).<\/li>\n
                18. \u201cDURIP: Piezoresponse Force Microscope (PFM) with Controlled Environment for Characterization of Flexoelectric Nanostructures\u201d, DOD, August 01, 2013 \u2013 Jan. 31, 2015, $199,821, Principal Investigator.<\/li>\n
                19. \u201cPlanning Grant: I\/UCRC for Dielectrics and Piezoelectrics (CDP)\u201d, NSF, 9\/01\/2012-8\/31\/2014, $15,280, Co-PI (PI: Elizabeth Dickey, Co-PIs: Jon-Paul Maria, Jur Jesse).<\/li>\n
                20. \u201cStability Testing of High Temperature Ultrasonic Conventional UT Probe-Evaluation of High Temperature Transducers\u201d\uff0cElectric Power Research Institute, Inc., 12\/03\/2013-12\/31\/2013, $4,500, Principal Investigator.<\/li>\n
                21. \u201cAerodynamic Sensing using Miniature Transducers\u201d, General Electric Co., March 01, 2013 \u2013 December 31, 2013, $59,696, Co\uff0dPI (PI: Ashok Gopalarathnam)<\/li>\n
                22. \u201cNondestructive Testing and Evaluation – An Undergraduate Course at NC State\u201d, American Society for Nondestructive Testing, Inc., May 01, 2013 \u2013 December 31, 2013, $8,000\uff0cPrincipal Investigator.<\/li>\n
                23. \u201cBottom-Up Meets Top-Down – An Integrated Undergraduate Nanotechnology Laboratory at NC State\u201d, NSF, January 01, 2011-June 30, 2013, $200,000, Co-PI (PI: Yong Zhu, Co-PIs: Joe Tracy, Jingyan Dong, Xiaoning Jiang and M. Gail Jones\u201d<\/li>\n
                24. \u201cHigh Temperature Piezoelectric Sensors for Future Propulsion Structure Health Monitoring\u201d, NC Space Grant Consortium, July 01, 2010 \u2013 June 30, 2013, $25,000, Principal Investigator.<\/li>\n
                25. \u201cBi-frequency PC-MUT Co-linear Array for Ophthalmic Imaging\u201d, Blatek, Inc. (NIH), July 01, 2011 \u2013 June 30, 2013, $70,119, Principal Investigator.<\/li>\n
                26. \u201cMR Compatible Multifrequency Focused Ultrasound\u201d, UNC-CH\/TRACS, 8\/01\/2011 \u2013 7\/31\/2012, $25,000. Principal Investigator.<\/li>\n
                27. \u201cModeling and Tests of Conformable 2D Arrays for NDE\u201d, UTRC, 9\/30\/2011-12\/09\/2012, $18,000, Principal Investigator.<\/li>\n
                28. \u201cScale Effect in Flexoelectricity for Novel Sensors and Detectors\u201d, ARO, 10\/01\/2010-6\/30\/2011, $50,000, Principal Investigator.<\/li>\n
                29. \u201cA Novel Flexoelectric Nanogenerator\u201d, NCSU\/FRPD, 7\/01\/2010-6\/30\/2011, $7,000, Principal Investigator.<\/li>\n
                30. \u201cEAGER: Materials and Structures for Strain Gradient Sensors\u201d, NSF, 11\/01\/2010-4\/30\/2011, $45,000, Principal Investigator (Co-PI: Fuh-Gwo Yuan).<\/li>\n
                31. \u201cDevelopment of Conformal Phased Array Transducer\u201d, UTRC, 10\/01\/2010-1\/31\/2011, $35,000, Principal Investigator.<\/li>\n<\/ol>\n

                  Past Projects (Prior to joining NC State, $7,843,000):<\/em><\/strong><\/span><\/p>\n

                    \n
                  1. \u00a0\u201cCryogenic Clamp-on Ultrasonic Flowmeter Using Single Crystal Piezoelectric Transducers\u201d, NASA, 1\/2010-7\/2010, $100,000, Principal Investigator (Transferred to Wesley Hackenberger at TRS)<\/li>\n
                  2. \u00a0\u201cHigh Frequency Phased Array Imaging System for SiC NDE\u201d, Air Force, 5\/2010-4\/2011, $300,000, Principal Investigator (Transferred to Wesley Hackenberger at TRS)<\/li>\n
                  3. \u00a0\u201cPiezoelectric Structural Microsensors for High Temperature Applications (> 1800 F)\u201d, NASA, 12\/2009-11\/2011, $600,000, Principal Investigator (Transferred to Wesley Hackenberger at TRS).<\/li>\n
                  4. \u00a0\u201cCryogenic Fluid Transfer Components Using Single Crystal Piezoelectric Actuators\u201d, NASA, 12\/2009-11\/2011, $600,000, Principal Investigator (Transferred to Wesley Hackenberger at TRS).<\/li>\n
                  5. \u00a0\u201cLarge Stroke Flextensional Actuators for Cryogenic Valves\u201d, NASA JSC, 7\/2009-10\/2009, $47,000, Principal Investigator.<\/li>\n
                  6. \u00a0\u201cPiezoelectric Structural Sensor Technology for Extreme Environments (> 1800 F)\u201d, NASA, 01\/2009-07\/2009, $100,000, Principle Investigator.<\/li>\n
                  7. \u00a0\u201cCryogenic Fluid Transfer Components Using Single Crystal Piezoelectric Actuators\u201d, NASA, 01\/2009-07\/2009, $100,000, Principal Investigator.<\/li>\n
                  8. \u00a0\u201cSingle Crystal Piezoelectric Deformable Mirrors with High Actuator Density and Large Stroke\u201d, NASA, 01\/2009-12\/2010, $600,000, Principle Investigator.<\/li>\n
                  9. \u00a0\u201cAdvanced NDE for SiC Optics Using Micromachined High Frequency Phased Array Ultrasound\u201d, Air Force, 03\/2008-03\/2010, $750,000, Principal Investigator.<\/li>\n
                  10. \u00a0\u201cMicromachined Piezoelectric Deformable Mirror for Cryogenic Adaptive Optics\u201d, NASA, 01\/2008-07\/2008, $100,000, Principal Investigator.<\/li>\n
                  11. \u00a0\u201cMicromachined Electrode Connections for HF Composite (60 MHz) Transducers\u201d, Boston Scientific Corporation, 12\/2007-04\/2008, $210,000, Principal Investigator.<\/li>\n
                  12. \u00a0\u201cStepping Piezomotor for Large Torque, Precise Rotary and Linear Motion Control in Passive Optics\u201d, NASA, 12\/07-11\/09, $600,000, Principal Investigator.<\/li>\n
                  13. \u00a0\u201cMicromachined Single Crystal HF Arrays for Interventional Cardiology Ultrasound\u201d, NIH, 09\/07-08\/09, $750,000, Co-PI with PI Dr. Kevin Snook.<\/li>\n
                  14. \u00a0\u201cMicromachined Piezoelectric 2-D Arrays for 3-D Medical Imaging\u201d, NIH, 8\/2007-10\/2008, $100,000, Principal Investigator.<\/li>\n
                  15. \u00a0\u201cSingle Crystal for Naval Energy Harvesting Application\u201d, NAVY, 06\/07-12\/07, $70,000, Sub-PI ($11,000) with Prime PI Dr. Gang Wang at TechnoSci, Inc.<\/li>\n
                  16. \u00a0\u201cAdvanced Single Crystal Ultrasound Transducers with High Sensitivity and Broad bandwidth for in-situ NDE Imaging of SiC Mirror\u201d, Air Force, 4\/2007-01\/2008, $100,000, Principal Investigator.<\/li>\n
                  17. \u00a0\u201cMicromachined Piezoelectric High Frequency Ultrasound Transducers (60 MHz)\u201d, Boston Scientific Corporation, 04\/2007-12\/2007, $305,000, Principal Investigator<\/li>\n
                  18. \u00a0\u201cCryogenic Piezo Actuators for Lightweight, Large Aperture, Deployable Membrane Mirrors\u201d, NASA, 01\/2007-07\/2007, $100,000, Principal Investigator.<\/li>\n
                  19. \u00a0\u201cCryogenic Stepping Piezomotor for Large Torque, Precise Rotary Motion Control in Passive Optics\u201d, NASA, 01\/2007-07\/2007, $100,000, Principal Investigator.<\/li>\n
                  20. \u00a0\u201cHybrid Electrostatic\/Flextensional Deformable Membrane Mirror for Lightweight, large Aperture and Cryogenic Space Telescope\u201d, NASA, 12\/2006-11\/2008, $600,000, Principal Investigator.<\/li>\n
                  21. \u00a0\u201cAdvanced Electroactive Single Crystal and Polymer Actuators for Passive Optics\u201d, NASA, 12\/2005-11\/2007, $600,000, Principal Investigator (Switched from Dr. Paul Rehrig).<\/li>\n
                  22. \u00a0\u201cMicromachined Piezoelectric Composites for HF Transducers and Transducer Arrays\u201d, Boston Scientific Corporation, 01\/2005-05\/2007, $650,000, Principal Investigator.<\/li>\n
                  23. \u00a0\u201cFlextensional Microactuators for Large-Aperture Lightweight Cryogenic Deformable Mirrors\u201d, NASA, 01\/2006-07\/2006, $70,000, Principal Investigator.<\/li>\n
                  24. \u00a0\u201cMiniaturized Lead Magnesium Niobate Titanate (PMN-PT) Single Crystal Piezoelectric Actuators\u201d, NASA JPL, 04\/2005-11\/2005, $40,000, Principal Investigator.<\/li>\n
                  25. \u00a0\u201cAdvanced Electroactive Single Crystal and Polymer Actuators Concepts for Passive Optics\u201d, NASA, 01\/2005-07\/2005, $70,000, Co-Investigator with PI Dr. Paul Rehrig.<\/li>\n
                  26. \u00a0\u201cAdvanced Actuator Concepts for High Precision Deformable Mirrors\u201d, NASA, 01\/2004-07\/2004, $70,000, Co-Investigator with PI Dr. Paul Rehrig.<\/li>\n
                  27. \u00a0\u201cSingle Crystal Piezomotor for Large Stroke, High Precision and Cryogenic Actuations\u201d, NASA, 01\/2004-07\/2004, $70,000, Co-Investigator with PI Dr. Paul Rehrig.<\/li>\n
                  28. \u00a0\u201cMicromachined Single Crystals for HF Transducers\u201d, NIH, 07\/2003-07\/2004, $100,000, Co-Investigator with PI Dr. Wesley Hackenberger.<\/li>\n<\/ol>\n<\/div>\n
                    \n

                    SELECTED PUBLICATIONS<\/h3>\n
                    \n

                    Refereed Journal Articles Published or Accepted for Publishing (*: student or postdoc under advisory of Dr. Jiang)<\/em><\/span><\/strong><\/p>\n<\/div>\n

                      \n
                    1. Wu, H.*, M. Hossain, H. Kim*, C. Gallippi, and X. Jiang, \u201cA 1.5D Array for Acoustic Radiation Force (ARF)-Induced Peak Displacement Based Tissue Anisotropy Assessment with a Row-Column Excitation Method\u201d, IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 2020.<\/li>\n
                    2. Peng, C.*, M. Chen*, H. Sim, Y. Zhu, and X. Jiang, \u201cNoninvasive and Nonocclusive Blood Pressure Monitoring via a Flexible Piezo-composite Ultrasonic Sensor\u201c, IEEE Sensors Journal, 2020.<\/li>\n
                    3. Yu, H., J. Kim*, H. Kim*, N. Barrange, X. Jiang, and F. So, \u201cDirect Acoustic Imaging using a Piezoelectric Organic Light-Emitting Diode\u201c, ACS Applied Materials & Interfaces, 2020.<\/li>\n
                    4. Kim, J., R. DeRuiter, L. Goel*, Z. Xu, X. Jiang, and P. Dayton, \u201cA Comparison of Sonothrombolysis in Aged Clots Between Low Boiling Point Phase Change Nanodroplets and Microbubbles of the Same Composition\u201c, Ultrasound in Medicine & Biology, 2020.<\/li>\n
                    5. Ji, J.*, J. Zhang, J. Wang, Q. Huang, X. Jiang, W. Zhang, S. Sang, X. Guo, and S. Li, \u201cThree-Dimensional Analyses of Cells\u2019 Positioning on the Quadrupole-Electrode Microfluid Chip Considering the Coupling Effect of nDEP, ACEO, and ETF\u201d, Biosensors and Bioelectronics, 2020.<\/li>\n
                    6. Ji, J.*, J. Wang, L. Wang, Q. Zhang, Q. Duan, S. Sang, Q. Huang, S. Li, W. Zhang, and X. Jiang, \u201cDynamic-Coupling Analyses of Cells Localization by the Negative Dielectrophoresis\u201c, Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2020.<\/li>\n
                    7. Peng, C.*, M. Chen*, H. Wang, J. Shen and X. Jiang, \u201cP(VDF-TrFE) Thin-Film Based Transducer for Under-Display Ultrasonic Fingerprint Sensing Applications\u201d, IEEE Sensors Journal, 2020<\/li>\n
                    8. Kim, H.*, S. Kerrigan, M. Bourham, and X. Jiang, \u201cAlN Single Crystal Accelerometer for Nuclear Power Plants\u201d, IEEE Transactions on Industrial Electronics, 2020.<\/li>\n
                    9. Kim, H.*, W.-Y. Chang*, T. Kim*, and X. Jiang, \u201cStress Sensing Method via Laser-Generated Ultrasound Wave Using Candle Soot Nanoparticle Composite\u201c, IEEE transactions on ultrasonics, ferroelectrics, and frequency control, 2020.<\/li>\n
                    10. Peng, C.*, M. Chen*, H. Wang, J. Shen and X. Jiang, \u201cBroadband Piezoelectric Transducers for UnderDisplay Ultrasonic Fingerprint Sensing Applications\u201d, IEEE Transactions on Industrial Electronics, 2020.<\/li>\n
                    11. . Goel, L.*, H. Wu*, H. Kim*, B. Zhang*, J. Kim, P. Dayton, Z. Xu, and X. Jiang, \u201cExamining the influence of low dose Tissue Plasminogen Activator on Microbubble Mediated Forward-Viewing Intravascular Sonothrombolysis\u201d, Ultrasound in Medicine & Biology, 2020.<\/li>\n
                    12. Shu, L., S. Ke, L. Fei, W. Huang, Z. Wang, J. Gong, X. Jiang, L. Wang, F. Li, S. Lei, Z. Rao, Y. Zhou, R. Zheng, X. Yao, Y. Wang, M. Stengel, G. Catalan, \u201cPhotoflexoelectric effect in halide perovskites\u201d, Nature Materials, 2020.<\/li>\n
                    13. Goel, L.* and X. Jiang, \u201cRecent Advances in Pre-Clinical Sonothrombolysis using Piezoelectric Transducers\u201d, Sensors, 2020.<\/li>\n
                    14. Kim, K., T. Kim, J. Kim*, and X. Jiang, \u201cA face-shear mode piezoelectric array sensor for elasticity and force measurement\u201d, Sensors, 2020.<\/li>\n
                    15. Luo, C.*, W.-Y. Chang*, M. Gao, C.-H. Chang, J. Li, D. Viehland, J. Tian, and X. Jiang, \u201cMulti-layered Domain Morphology in Relaxor Single Crystals with Nano-patterned Composite Electrode\u201c, Acta Materialia 182 (2020): 10-17.<\/li>\n
                    16. Qi, L., S. Huang*, G. Fu., A. Li, , S. Zhou, and X. Jiang, \u201cModeling of the flexoelectric annular microplate based on strain gradient elasticity theory.\u201d Mechanics of Advanced Materials and Structures 26.23 (2019): 1958-1968.<\/li>\n
                    17. Kim, H.*, H. Wu*, N. Cho*, P. Zhong, K. Mahmood, H. Lyerly, and X. Jiang, \u201d Miniaturized Intracavitary Forward-Looking Ultrasound Transducer for Tissue Ablation\u201d, IEEE Transactions on Biomedical Engineering (2019).<\/li>\n
                    18. Luo, C.*#, H. Wan*#, W.-Y. Chang*, Y. Yamashita, A. Paterson, J. Jones, and X. Jiang, \u201cEffect of LowFrequency Alternating Current Poling on 5-mm-Thick 0.7Pb(Mg1\/3Nb2\/3)O3- 0.3PbTiO3 Single Crystals\u201d, Applied Physics Letters (2019). (Accepted) (# C. Luo and H. Wan contributed equally to this work)<\/li>\n
                    19. Luo, C.*, W.-Y. Chang*, M. Gao, C. Chang, J. Li, D. Viehland, J. Tian, and X. Jiang, \u201cMulti-layered Domain Morphology in Relaxor Single Crystals with Nano-patterned Composite Electrode\u201d, Acta Materialia (2019).<\/li>\n
                    20. . Kim, H.*, T. Kim*, D. Morrow*, and X. Jiang, \u201cStress Measurement of a Pressurized Vessel Using Ultrasonic Subsurface Longitudinal Wave with 1-3 Composite Transducers\u201d, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 2019.<\/li>\n
                    21. Kim, T.*, W. Chang*, H. Kim*, and X. Jiang, \u201cNarrow Band Photoacoustic Lamb Wave Generation for Nondestructive testing using Candle Soot Nanoparticle Patches,\u201d Applied Physics Letters, 2019.<\/li>\n
                    22. Kim, T.*, Z. Cui, W. Chang*, H. Kim*, Y. Zhu, and X. Jiang, \u201cFlexible 1-3 Composite Ultrasound Transducers with Silver Nanowire based Stretchable Electrodes,\u201d IEEE Transactions on Industrial Electronics, 2019.<\/li>\n
                    23. Ji, J*., M. Li, Z. Chen, H. Wang, X. Jiang, K. Zhuo, Y. Liu, X. Yang, Z. Gu, S. Sang, and Y. Shu, \u201cIn Situ Fabrication of Organic Electrochemical Transistors on a Micro-fluidic Chip\u201d, Nano Research, 2019.<\/li>\n
                    24. Zhang, B.*, H. Kim*, H. Wu*, Y. Gao, and X. Jiang, \u201cSonothrombolysis with Magnetic Microbubbles Under a Rotational Magnetic Field.\u201d Ultrasonics, 2019. (Accepted)<\/li>\n
                    25. Jiang, X., and J. Spicer. \u201cNanoacoustics Comes Quietly\u201d IEEE Nanotechnology Magazine 13.3 (2019): 4-4. (Guest Editorial)<\/li>\n
                    26. Zhang, F.*, P. Lv, Y. Zhang, S. Huang, C. Wong, H. Yau, X. Chen, Z. Wen, X. Jiang, C. Zeng, J. Hong, and J. Dai, \u201cModulating the electrical transport in the two-dimensional electron gas at LaAlO 3\/SrTiO 3 heterostructures by interfacial flexoelectricity\u201c, PHYSICAL REVIEW LETTERS, 2019 (Accepted) (Editors\u2019 Suggestion)<\/li>\n
                    27. Kim, J., H. Kim*, W.-Y. Chang*, W. Huang, X. Jiang, P. Dayton, \u201cCandle-Soot Carbon Nanoparticles in Photoacoustics: Advantages and challenges for laser ultrasound transmitters.\u201d IEEE Nanotechnology Magazine (2019).<\/li>\n
                    28. Li, M, W. Shao, X. Jiang, and Z. Feng, \u201cDeconvolution in Intravascular Ultrasound to Improve Lateral Resolution,\u201d Ultrasonic Imaging (2019): 0161734619838456.<\/li>\n
                    29. Wan, H.*, C. Luo*, W.-Y. Chang*, Y. Yamashita, and X. Jiang, \u201cEffect of poling temperature on piezoelectric and dielectric properties of 0.7Pb(Mg1\/3Nb2\/3)O3 \u2013 0.3PbTiO3 single crystals under alternating current poling\u201c, Applied Physics Letters, 114, 17, 172901 (2019) (Featured Article).<\/li>\n
                    30. Li, S.*, J. Tian, and X. Jiang, \u201cA Micromachined PMN-PT Single Crystal Composite Circular Array for Intravascular Ultrasound Imaging\u201d, ASME J of Medical Diagnostics 2(2), 021001 (Jan 18, 2019)<\/li>\n
                    31. Gao, M., C. Luo*, W-Y. Chang*, C. M.Leung, J. Tian, J.Li, X. Jiang and D. Viehland, \u201cApparent phase stability and domain distribution of PMN-30PT single crystals with nanograted Au\/MnOx electrodes.\u201d Acta Materialia (2019).<\/li>\n
                    32. Jiang, X., and Al-Jumaily, A. M. \u201cUltrasound Transducers for Biomedical Imaging and Therapy\u201c, Journal of Engineering and Science in Medical Diagnostics and Therapy, 1.4 (2018): 040201.<\/li>\n
                    33. Zhang, S., F. Li, F. Yu, X. Jiang, H.-Y. Lee, J. Luo, and T. R. Shrout, \u201cRecent developments in piezoelectric crystals\u201c, Journal of the Korean Ceramic Society, 55, 5, 419-439 (2018).<\/li>\n
                    34. Li, S.*, J. Kim*, Z. Wang*, S. Kasoji, B. Lindsey, P. Dayton, X. Jiang, \u201cA Dual-frequency Co-linear Array for Acoustic Angiography in Prostate Cancer Evaluation\u201d, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, Volume: 65 , Issue: 12, pp. 2418-2428, 2018.<\/li>\n
                    35. Yuan, Z.*, S. Sang*, E. Sun, X. Qi, W.-Y. Chang*, R. Zhang, B. Yang, X. Jiang, and W. Cao, \u201cDomain engineering and full matrix material constants of [111] c-poled 0.63 Pb (Mg1\/3Nb2\/3)-0.37 PbTiO3 single crystal\u201c, CrystEngComm, 20, 4745-4751 (2018).<\/li>\n
                    36. Chang, W.*, C. Chung, C. Luo*, T. Kim*, Y. Yamashita, J. Jones, and X. Jiang, \u201cDielectric and piezoelectric properties of 0.7 Pb(Mg1\/3Nb2\/3)O3-0.3 PbTiO3 single crystal poled using alternating current\u201d, Materials Research Letters, 6, 10, 537-544 (2018).<\/li>\n
                    37. Huang, S.*, H.M. Yau, H. Yu, L. Qi*, F. So, J.Y. Dai,and X. Jiang, \u201cFlexoelectricity in a metal\/ferroelectric\/semiconductor heterostructure\u201d, AIP Advance, 8, 6, 065321, (2018 Editor\u2019s Pick).<\/li>\n
                    38. Chang, W.-Y.*, X.A. Zhang, J. Kim*, W. Huang, A. Bagal, C.-H. Chang, T. Fang, H.F. Wu, and X. Jiang, \u201cEvaluation of Photoacoustic Transduction Efficiency of Candle Soot Nanocomposite Transmitters\u201d, IEEE Transactions on Nanotechnology, 17, 5, 985-993 (2018).<\/li>\n
                    39. Nguyen, B.H., S.S. Nanthankumar, X. Zhuang, P. Wriggers, X. Jiang, and T. Rabczuky, \u201cDynamic flexoelectric effect on piezoelectric nanostructures\u201d, European Journal of Mechanics\/ A Solids, 71, 404-409, (2018).<\/li>\n
                    40. Huang, S.*, L. Qi*, W. Huang, L. Shu, S. Zhou, and X. Jiang, \u201cFlexoelectricity in dielectrics: materials, structures and characterizations.\u201d Journal of Advanced Dielectrics, 8, 02, 1830002 (2018).<\/li>\n
                    41. Kim, Taeyang*, J. Kim*, and X. Jiang, \u201cAlN Ultrasound Sensor for Photoacoustic Lamb Wave Detection in a High Temperature Environment\u201d, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 65, 8, 1444-1451 (2018).<\/li>\n
                    42. Qi, L.*, S. Huang*, G. Fu, A. Li, S. Zhou, and X. Jiang, \u201cModelling of the flexoelectric annular microplate based on strain gradient elasticity theory\u201d, Mechanics of Advanced Materials and Structures, 2018. (Accepted)<\/li>\n
                    43. Qi, L.*, S. Huang*, G. Fu, S. Zhou, and X. Jiang, \u201cOn the mechanics of curve flexoelectric microbeams\u201d, International Journal of Engineering Science, 124, 1-15 (2018).<\/li>\n
                    44. Chang, W.-Y.*, C.-C. Chung, Z. Yuan*, C.-H. Chang, J. Tian, D. Viehland, J.-F. Li, J. L. Jones, and X. Jiang, \u201cPatterned Nano-domains in PMN-PT Single Crystals\u201d, Acta Materialia, 143, 166-173 (2018).<\/li>\n
                    45. Wang, Z.*, K. H. Martin, P.A. Dayton, and X. Jiang, \u201cReal-time ultrasound angiography using superharmonic dual-frequency (2.25 MHz \/ 30 MHz) cylindrical array: in vitro study\u201d, Ultrasonics, 82, 298-303 (2018).<\/li>\n
                    46. Joshi, A.A., S. Li*, S. Kasoji, X. Jiang, P. Dayton, and M.M. Muller, \u201cQuantitative analysis of the angiogenic microvasculature in tumor using multiple scattering and dual-frequency transducers\u201c, The Journal of the Acoustical Society of America, 142, 2563 (2017).<\/li>\n
                    47. Kim, T.*, J. Kim*, and X. Jiang, \u201cTransit Time Difference Flowmeter for Intravenous Flow Rate Measurement Using 1-3 Piezoelectric Composite Transducers\u201d, IEEE Sensors, 2017. (Accepted)<\/li>\n
                    48. Huang, S.*, T. Kim*, D. Hou, D. Cann, J. L. Jones, and X. Jiang, “Flexoelectric Characterization of BaTiO3-0.08Bi(Zn1\/2Ti1\/2)O3”, Applied Physics Letters (2017, accepted).<\/li>\n
                    49. Kim, J.*, B. D. Lindsey*, W. Chang*, X. Dai, J. M. Stavas, P. A. Dayton and X. Jiang, \u201cIntravascular forward-looking ultrasound transducers 1 for microbubble-mediated sonothrombolysis\u201d, Scientific Reports, 7, 3454 (2017).<\/li>\n
                    50. Lindsey, B. D.*, J. Kim*, P. Dayton, and X. Jiang, \u201cDual-frequency piezoelectric endoscopic transducer for imaging vascular invasion in pancreatic cancer\u201d, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, Volume: 64, Issue: 7, pp. 1078 \u2013 1086 (2017).<\/li>\n
                    51. Berik, P., W.-Y. Chang* and X. Jiang, \u201cPiezoelectric d36 in-plane shear-mode of lead-free BZT-BCT single crystals for torsion actuation\u201c, Applied Physics Letters, 110, 5, 052902 (2017).<\/li>\n
                    52. Suo, D., Z. Jin, X. Jiang, P. Dayton and Y. Jing, \u201cMicrobubble mediated dual-frequency high intensity focused ultrasound thrombolysis: an In vitro study\u201c, Applied Physics Letters, 110, 2, 023703 (2017).<\/li>\n
                    53. Sang, S.*, Z. Yuan*, L. Zheng, E. Sun, X. Qi, R. Zhang, X. Jiang, S. Li, and J. Du, \u201cRaman spectra of (K, Na)(Nb, Ta)O3 single crystal\u201c, Journal of Alloys and Compounds, 704, 804-808 (2017).<\/li>\n
                    54. Kim, T.*, A. Saini, J. Kim*, A. Gopalarathnam, Y. Zhu, F. L. Palmieri, C. J. Wohl, and X. Jiang, \u201cPiezoelectric Floating Element Shear Stress Sensor for the Wind Tunnel Flow Measurement,\u201d IEEE Transactions on Industrial Electronics, Volume: 64, Issue: 9, pp. 7304 – 7312 (2017).<\/li>\n
                    55. Wang, Z.*, K. Martin, W. Huang*, P. Dayton, X. Jiang, \u201cContrast enhanced superharmonic imaging for acoustic angiography using reduced form-factor lateral mode transmitters for intravascular and intracavity applications\u201d, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 64, 2, 311-319 (2017).<\/li>\n
                    56. Shu, L., T. Wang, X. Jiang and W. Huang, \u201cVerification of the flexoelectricity in barium strontium titanate through d33 meter\u201d, AIP Advances, 6, 125003 (2016).<\/li>\n
                    57. Shi, X., W. Huang, F. Li, Z. Li, Z. Xu, X. Jiang, and X. Wei, \u201cAnalysis on the anisotropic electromechanical properties of lead magnoniobate titanate single crystal for ring type ultrasonic motors\u201c, AIP Advances, 6, 115017 (2016)<\/li>\n
                    58. Shu, L., Z. Yong, X. Jiang, Z. Xie, W. Huang, \u201cFlexoelectricity in low densification materials and its implication\u201c, Journal of Alloys and Compounds, 695, 25, 1555-1560 (2016).<\/li>\n
                    59. Lindsey, B. D.*, K. Martin, X. Jiang, and P.A. Dayton, “Adaptive windowing in contrast-enhanced intravascular ultrasound imaging”, Ultrasonics, 70, 123-135, (2016).<\/li>\n
                    60. Kim, T.*, W. Huang*, S. Huang*, and X. Jiang, “Thermal Gradient Induced Flexoelectric Effects in Bulk Ba0.67Sr0.33TiO3”, Applied Physics Letters, 108, 92902, (2016).<\/li>\n
                    61. Martin, K. H., B. D. Lindsey, J. Ma*, T. C. Nichols, X. Jiang, and P. A. Dayton, “Ex-vivo porcine arterial and chorioallantoic membrane acoustic angiography using dual frequency intravascular ultrasound probes”, Ultrasound in Medicine and Biology, (2016). Accepted<\/li>\n
                    62. Huang, W.*, W.-Y Chang*, J. Kim*, S. Li*, S. Huang*, and X. Jiang, “A Novel Laser Ultrasound Transducer Using Candle Soot Carbon Nanoparticles”, IEEE Transactions on Nanotechnology, 15(3), 395-401, (2016).<\/li>\n
                    63. Kwon, S.R.*,W. Huang*, S. Zhang, F.-G. Yuan and X. Jiang, “Study on a flexoelectric microphone using barium strontium titanate”, Journal of Micromechanics and Microengineering, 26(4), 045001 (2016).<\/li>\n
                    64. Huang, W.*, J. Kim*, K. Kim*, S. Bakshi*, J. Williams, P. Matthieu, E. Loboa, K. K. Shung, Q. Zhou, X. Jiang, “A Novel Ultrasound Technique for Non-Invasive Assessment of Cell Differentiation”, IEEE Sensors, 16(1), 61-68, (2016).<\/li>\n
                    65. Wang, Z.*, S. Li*, T. Czernuszewicz, C. Gallippe, C. Liu, X. Geng, X. Jiang, “Design, fabrication and characterization of a bi-frequency co-linear array”, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 63(2), 266-274 (2016).<\/li>\n
                    66. Li, Y., J. Ma*, K. H. Martin, M. Yu, T. Ma, P. A. Dayton, X. Jiang, K. Shung, and Q. Zhou, \u201cAn Integrated System for Super-Harmonic Contrast-Enhanced Ultrasound Imaging: Design and Intravascular Phantom Imaging Study\u201d, IEEE Transactions on Biomedical Engineering, (2015). (Accepted)<\/li>\n
                    67. Chang, W.-Y.*, W. Huang*, J. Kim*, S. Li*, X. Jiang, “Candle Soot Nanoparticles-PDMS Composites for Laser Ultrasound Transducers”, Applied Physics Letters, 107(16), 161903, (2015).<\/li>\n
                    68. Di, J., J. Kim,*, Q. Hu, X. Jiang, Z. Gu, “Spatiotemporal Drug Delivery Using Laser-Generated-Focused Ultrasound System”, Journal of Controlled Release, (2015). (Equivalent contribution)<\/li>\n
                    69. Kim, T.*, J. Kim*, R. Dalmau, R. Schlesser, E. Preble, X. Jiang, “High Temperature Electromechanical Characterization of AlN Single Crystals”, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, 62, 10, (2015).<\/li>\n
                    70. Suo, D., S. Guo*, W. Lin, X. Jiang, J. Jing, “Thrombolysis using multi-frequency high intensity focused ultrasound at MHz range: an in vitro study”, Physics in Medicine and Biology, 60, 7403, (2015).<\/li>\n
                    71. Kim, J.*, S. Li*, S. Kasoji, P. A. Dayton and X. Jiang, “Phantom evaluation of stacked-type dual-frequency 1-3 composite transducers: a feasibility study on intracavitary acoustic angiography”, Ultrasonics, 63, 7-15, (2015).<\/li>\n
                    72. Ma, J.*, M. Steer and X. Jiang, “An acoustic filter based on layered structure”, Applied Physics Letter, 106, 111903 (2015); doi: 10.1063\/1.4915100.<\/li>\n
                    73. Ma, J.*, K. Martin, Y. Li, P. Dayton, K. Shung, Q. Zhou, X. Jiang, “Design factors of intravascular dual frequency transducers for super-harmonic contrast imaging and acoustic angiography”, Physics in Medicine and Biology, 60(9), 3441, (2015).<\/li>\n
                    74. Hsieh, B.-Y.*, J. Kim*, J. Zhu, S. Li*, X. Zhang, X. Jiang, “A laser ultrasound transducer using carbon nanofibers-polydimethylsiloxane composite thin film”, Applied Physics Letters, 106(2), 021902, (2015).<\/li>\n
                    75. Zhang, S., F. Li, X. Jiang, J. Kim*, J. Luo, and X. Geng, “Advantages and Challenges of Relaxor-PbTiO3 Ferroelectric Crystals for Electroacoustic Transducers-A Review,” Progress in Materials Science, Volume 68, Pages 1-66, March 2015.<\/li>\n
                    76. Huang, W.*, L. Shu*, S. R. Kwon*, F. G. Yuan, X. Jiang, “Fabrication and Measurement of a Flexoelectric Micro-pyramid Composite”, AIP Advances, (2014).<\/li>\n
                    77. Martin, K. H., B.D. Lindsey, J. Ma*, M. Lee, S. Li*, F.S. Foster, X. Jiang, P.A. Dayton, “Dual-Frequency Transducers for Contrast Enhanced Ultrasound Imaging”, Sensors, (2014).<\/li>\n
                    78. Li, Y.1, L. Shu1*, W. Huang*, X. Jiang, H. Wang, “Giant Flexoelectricity in Ba0.6Sr0.4TiO3\/Ni0.8Zn0.2Fe2O4 Composite”, Applied Physics Letters, 105(14), 162906, 2014. (1Equivalent contribution)<\/li>\n
                    79. Kwon, S.R.*, W. Huang*, L. Shu*, F.G. Yuan, J.P. Maria, X. Jiang, “Flexoelectricity in Barium Strontium Titanate Thin Film”, Applied Physics Letters, 105(14), 142904 (2014).<\/li>\n
                    80. Shu, L.*, F. Li, W. Huang*, X. Wei, X. Yao, X. Jiang, “Relationship between Direct and Converse Flexoelectric Coefficients”, Journal of Applied Physics, 116(14), 144105, (2014).<\/li>\n
                    81. Cui, Z., F. Robles Poblete, G. Cheng, S. Yao, X. Jiang, Y. Zhu, “Design and Operation of Silver Nanowire Based Flexible and Stretchable Touch Sensors”, Journal of Materials Research, Vol. 30, No. 1, pp.79-85, Jan 14, 2015.<\/li>\n
                    82. Jian, X., S. Li*, W. Huang*, Y. Cui, X. Jiang, “Electromechanical response of micromachined 1-3 piezoelectric composites: Effect of etched piezo-pillar slope”, Journal of Intelligent Material Systems and Structures, 2014. DOI: 10.1177\/1045389X14546657<\/li>\n
                    83. Huang, W.*, S. Yang, N. Zhang, F.-G. Yuan, X. Jiang, “Direct measurement of opening mode stress intensity factors using flexoelectric strain gradient sensors”, Experimental Mechanics, 2014. (Accepted)<\/li>\n
                    84. Jiang, X., J. Kim*, K. Kim*, “Relaxor-PT single crystal piezoelectric sensors”, Crystals, 4(3), 351-376, (2014).<\/li>\n
                    85. Shu, L.*, W. Huang*, S. Kwon*, Z. Wang, F. Li, X. Wei, S. Zhang, M. Lanagan, X. Yao, X. Jiang, \u201cConverse flexoelectric coefficient f1212 in bulk Ba0.67Sr0.33TiO3\u201d, Applied Physics Letters, 104(23), 232902 (2014).<\/li>\n
                    86. Wang, M., W. Yuan, X. Jiang, Y. Jing, Z. Wang, “Disruption of microalgal cells using high-frequency focused ultrasound”, Bioresource Technology, 153, 315-321 (2014).<\/li>\n
                    87. Johnson, J.*, K. Kim*, S. Zhang, D. Wu, X. Jiang, “High-temperature acoustic emission sensing tests using a yttrium calcium oxyborate sensor”, IEEE Trans. Ultrason. Ferroelectr. Freq. Contr., 61(5), 805-14 (2014).<\/li>\n
                    88. Ma, J.*, K. Martin, P. Dayton, X. Jiang, “A preliminary engineering design of intravascular dual-frequency transducers for contrast enhanced acoustic angiography and molecular imaging”, IEEE Trans. Ultrason. Ferroelectr. Freq. Contr., 61(5), 870-80 (2014). (Cover Image)<\/li>\n
                    89. Jiang, X., K. Kim*, S. Zhang, J. Johnson, G. Salazar, “High-Temperature Piezoelectric Sensing”, Sensors, 14(1), 144-69 (2014).<\/li>\n
                    90. Di, J., J. Price, X. Gu, X. Jiang, Y. Jing, and Z. Gu, \u201cUltrasound-Triggered Regulation of Blood Glucose Levels Using Injectable Nano-Network\u201d, Advanced Healthcare Materials, Vol. 3, No. 6, pp. 811-816 (2014).<\/li>\n
                    91. Jiang, X., W. Huang*, S. Zhang, “Flexoelectric nano-generator: Materials, structures and devices”, Nano Energy, 2(6), 1079-92 (2013).<\/li>\n
                    92. Kwon, S.R.*, W. Huang*, F.-G. Yuan, X.N. Jiang, “Flexoelectric sensing using a multilayered barium strontium titanate structure”, Smart Materials and Structures, 22(11), 115017 (2013).<\/li>\n
                    93. Chang, W.-Y., W. Huang*, A. Bagal, C.-H. Chang, J. Tian, P. Han, X. Jiang, “Study on dielectric and piezoelectric properties of 0.7Pb(Mg1\/3Nb2\/3)O3-0.3PbTiO3 single crystal with nano-patterned composite electrode”, Journal of Applied Physics, 114(11), 114103 (2013).<\/li>\n
                    94. Guo, S.*, Y. Jing, and X.N. Jiang, \u201cTemperature Rise in Tissue Ablation Using Multi-frequency Ultrasound\u201d, IEEE Trans. Ultrason. Ferroelectr. Freq. Contr., Vol. 60, No. 8, pp. 1699-1707 (2013).<\/li>\n
                    95. Zhu, Y., J.B. Tracy, J. Dong, X. Jiang, M.G. Jones and G. Childers, “Teaching a Multidisciplinary Nanotechnology Laboratory Course to Undergraduate Students”, Journal of Nano Education, 5, 17-26 (2013).<\/li>\n
                    96. Ma, J.*, S. Guo*, D. Wu, X. Geng, and X. N. Jiang, \u201cDesign, Fabrication and Characterization of a Single Aperture 1.5 MHz \/ 3 MHz Dual Frequency HIFU Transducer\u201d, IEEE Trans. Ultrason. Ferroelectr. Freq. Contr., Vol. 60, No. 7, pp. 1519-1529 (2013).<\/li>\n
                    97. Yan, X., W. Huang*, S.R. Kwon*, S. Yang, X. Jiang, F.-G. Yuan, “A Sensor for the Direct Measurement of Curvature Based on Flexoelectricity”, Smart Materials and Structures, 22, 085016 (2013).<\/li>\n
                    98. Huang, W.*, S. Kwon*, S. Zhang, F. Yuan and X.N. Jiang, “A Trapezoid Shape Flexoelectric Accelerometer”, J Intell Mater Syst Struct, 2013; DOI: 10.1177\/1045389X13491021.<\/li>\n
                    99. Xu, T., E. J. Siochi, J. H. Kang, L. Zuo, W. Zhou, X. Tang, and X.N. Jiang, \u201cEnergy Harvesting using a PZT Ceramic Multilayer stack\u201d, Smart Mater. Struct. 22 (2013) 065015; doi:10.1088\/0964-1726\/22\/6\/065015.<\/li>\n
                    100. Xu, T., L. Tolliver*, X. Jiang, and J. Su, “A Single Crystal Lead Magnesium Niobate-Lead Titanate Multilayer-stacked Cryogenic Flextensional Actuator”, Appl Phys Lett, 102, 042906 (2013).<\/li>\n
                    101. Tolliver, L.*, T. Xu, and X. Jiang. “Finite element analysis of the piezoelectric stacked-HYBATS transducer” Smart Mater. Struct. 22 (2013) 035015; doi:10.1088\/0964-1726\/22\/3\/035015.<\/li>\n
                    102. Huang, W.*, X. Yan, S. Kwon, S. Zhang, F. Yuan, and X.N. Jiang, \u201cFlexoelectric Strain Gradient Detection using Ba0.64Sr0.36TiO3 (BST) for Sensing\u201d, Appl. Phys. Lett. 101, 252903 (2012); doi: 10.1063\/1.4772803.<\/li>\n
                    103. Kim, K.*, S. Zhang, and X.N. Jiang, \u201cSurface Acoustic Load Sensing Using a Face-Shear PIN-PMN-PT Single Crystal Resonator\u201d, IEEE Trans. Ultrason. Ferroelectr. Freq. Contr. Vol. 59, pp. 2548-2554 (2012).<\/li>\n
                    104. Guo, S.*, Y. Wang, N. Allbritton, and X.N. Jiang, \u201cUltrasound-Induced Release of Micropallets with Cells\u201d, Appl. Phys. Lett. 101, 163703 (2012); doi: 10.1063\/1.4757648.<\/li>\n
                    105. Kim, K.*, S. Zhang, and X.N. Jiang, \u201cSurface Load Induced Electrical Impedance Shift in Relaxor-PbTiO3 Crystal Piezoelectric Resonators\u201d, Appl. Phys. Lett. 100, 253501 (2012); doi: 10.1063\/1.4729766.<\/li>\n
                    106. Kim, K.*, S. Zhang, G. Salazar*, X.N. Jiang, \u201cDesign, Fabrication and Characterization of High Temperature Piezoelectric Vibration Sensor Using YCOB Crystals\u201d, Sensors and Actuators: A Physical, Vol. 178, pp. 40\u201348 (2012).<\/li>\n
                    107. Huang, W.*, K. Kim*, S. Zhang, F. Yuan and X.N. Jiang, \u201cScaling Effect of Flexoelectric (Ba,Sr)TiO3 Microcantilevers\u201d, Phys. Status Solidi RRL 5, No.9, pp. 350-352 (2011) \/ DOI 10.1002\/pssr.201105326.<\/li>\n
                    108. Thein, M., A. Cheng, P. Khanna, C. Zhang, E.J. Park, D. Ahmed, C.J. Goodrich, F. Asphahani, F. Wu, N. Smith, C. Dong, X.N. Jiang, M. Zhang, and J. Xu, \u201cSite-specific Sonoporation of Human Melanoma Cells at the Cellular Level using High Lateral-Resolution Ultrasonic Micro-transducer Arrays\u201d, Biosensors and Bioelectronics 27 (2011) 25-33.<\/li>\n
                    109. Kim, K.*, S. Zhang, W. Huang*, F. Yu and X.N. Jiang, \u201cYCa4O(BO3)3 (YCOB) High Temperature Vibration Sensor\u201d, J. Appl. Phys. 109, 126103 (2011); doi:10.1063\/1.3598115.<\/li>\n
                    110. Xu, T., X.N. Jiang, and J. Su, \u201cA Piezoelectric Multilayer-Stacked Hybrid Actuation\u2044Transduction System\u201d, Applied Physics Letters, 98, No. 24, 062124 (2011).<\/li>\n
                    111. Ma, T., C. Zhang, X.N. Jiang, and G. Feng, \u201cThickness Shear Mode Quartz Crystal Resonators with Optimized Elliptical Electrodes\u201d, Chinese Phys. B 20 047701 (2011).<\/li>\n
                    112. Ma, T., C. Zhang, G. Feng, and X.N. Jiang, \u201cLateral Field Excitation Properties of Langasite Single Crystal\u201d, Chinese Phys. B 19 087701 (2010).<\/li>\n
                    113. Zhang, S., X.N. Jiang, M. Lapsley, P. Moses, and T. R. Shrout, \u201cPiezoelectric Accelerometers for Ultrahigh Temperature Application\u201d, Applied Physics Letters, 96, 013506 (2010)<\/li>\n
                    114. Toda, R., X.N. Jiang, K. Shcheglov, and EH Yang, \u201cLinear Microactuators and Their Control Models for Mirror Shape Correction\u201d, Journal of Micro and Nano-Mechatronics, 4:159\u2013167(2009).<\/li>\n
                    115. Dong, S., L. Yan, D. Viehland, X.N. Jiang, and W. Hackenberger, \u201cA Piezoelectric Single Crystal Traveling Wave Step Motor for Low-Temperature Applications\u201d, Applied Physics Letters, 92, 153504 (2008).<\/li>\n
                    116. Zhang, S., Y. Fei, B. Chai, E. Frantz, D. Snyder, X.N. Jiang, and T. Shrout, \u201c Characterization of Piezoelectric Single Crystal Yca4O(BO3)3 for High Temperature Applications, Applied Physics Letters, 92, 202905 (2008).<\/li>\n
                    117. Woody, S. C., S. T. Smith, X. N. Jiang, and P.W. Rehrig, \u201cPerformance of Single-Crystal Pb(Mg1\/3Nb2\/3)-32%PbTiO3 Stacked Actuators with Application to Adaptive Structures\u201d, Review of Scientific Instruments 76, 075112 (2005), pp.1-8.<\/li>\n
                    118. Zhan, C., J. Wu, S. Yin, and X.N. Jiang, \u201cStrong, High-Frequency, AC Electric-Field-Induced Rhombohedra-Tetragonal Phase Transition in Pb(Mg1\/3Nb2\/3)-32%PbTiO3 Single Crystal\u201d, Journal of Applied Physics 97, 074107(2005), pp.1-4.<\/li>\n
                    119. Dong, S., L. Yan, N. Wang, D. Viehland, X.N. Jiang, P. Rehrig, and W.Hackenberger, \u201c A Small, Linear, Piezoelectric Ultrasonic Cryomotor\u201d, Applied Physics Letter 86, 053501 (2005), pp.1-3.<\/li>\n
                    120. Jiang, X.N., C. Sun, X. Zhang, B. Xu, and Y.H. Ye, \u201cMicro-stereolithography of lead zirconate titanate (PZT) thick films on silicon substrate\u201d, Sensors and Actuators: A. Physical, vol. 87, pp. 72-77 (2000).<\/li>\n
                    121. Zhang, X., X. N. Jiang. And C. Sun, \u201cPolymeric and Ceramic Microstereolithography for MEMS\u201d, Sensors and Actuators: A. Physical, Vol.77, No.2, pp.149-156 (1999).<\/li>\n
                    122. Jiang, X. N., Z. Y. Zhou, X. Y. Huang, Y. Li, Y. Yang, and C.Y. Liu, \u201cMicro-nozzle\/diffuser Flow and Its Application in Micro Valveless Pumps\u201d, Sensors and Actuators: A. Physical, Vol.70\/1-2, pp.81-87 (1998).<\/li>\n
                    123. Zhou, Z.Y., X.Y. Ye, Y. Li, Z. You, T.H. Cui, Y. Yang, X.N. Jiang, M. Hu, S.S. Xiong, W.D. Zhang, H.N. Cai, J. Zou, L. Zhang, X. H. Wang and X.Q. Lu \u201cResearch on microfluid handling systems\u201d, Journal of the Institution of Engineers Singapore, Vol. 38, No.4, pp.7-14 (1998).<\/li>\n
                    124. Zhou, Z. Y., Y. Yang, X. Y. Ye, Y. Li, and X. N. Jiang, \u201cMicro System and Micro manufacturing Technology\u201d, J. Micro\/Nano Science and Technology, Vol.2, No.1, pp.1-11 (1996). (in Chinese)<\/li>\n
                    125. Jiang, X. N., Z. Y. Zhou, Y. Li, and X. Y. Ye, \u201cA Novel Silicon Based Micropump\u201d, Chinese J. of Scientific Instrument, Vol.17, No.1, pp.322-326 (1996). (in Chinese)<\/li>\n
                    126. Jiang, X. N., Z. Y. Zhou, Y. Li, X. Y. Ye, and Y. Yang, \u201cStudy on Microfluid Flow Behavior\u201d, J. of Optics and Precision Engineering, Vol.3, No.3, pp.51-55 (1995). (in Chinese)<\/li>\n
                    127. Jiang, X. N., Z. Y. Zhou, Y. Li, and D. L. Shen, \u201cMicrofluid Measuring System and its Application in the Microfluid Flow Behavior Research\u201d, Chinese J. of Scientific Instrument, Vol.16 No.1, pp.346-351 (1995b) . (in Chinese)<\/li>\n
                    128. Li, Y., X. N. Jiang, Z.Y. Zhou, and X. Y. Ye, \u201cProperty of Fluid Flow in Micro-channel\u201d, J. China Mechanical Engineering Vol.5, No.3, pp.23-25 (1994). (in Chinese)<\/li>\n
                    129. Jiang X. N., Y. Li, Z. Y. Zhou, and X. Y. Ye, \u201cMicro-actuation Technology\u201d, J. of China Instrumentation, No.2, pp10-14 (1993). (in Chinese)<\/li>\n
                    130. Zhou, Z. Y., X. N. Jiang, Y. Li, and X. Y. Ye, \u201cThe Development of Micromachine\u201d, J. of China Instrumentation, No.1, pp14-17 (1993). (in Chinese)<\/li>\n<\/ol>\n

                      Refereed Encyclopedia Entries\/Book Chapters \/Books<\/strong><\/em><\/span><\/p>\n

                        \n
                      1. Ma J. and X. Jiang, Chapter \u201cContrast-Enhanced Dual-Frequency Super-Harmonic Intravascular Ultrasound (IVUS) Imaging\u201d. In: Zhou Q., Chen Z. (eds) Multimodality Imaging. Springer, Singapore, 2019.<\/li>\n
                      2. Jiang, X., S. Li, J. Kim, J. Ma, W. Huang, and X. Jian, \u201cHigh frequency piezo-composite micromachined ultrasound transducer array technology for biomedical imaging\u201d, ASME Press, New York, 2017 (ISBN: 9780791860441).<\/li>\n
                      3. Huang, W.*, F.G. Yuan, and X. Jiang, Chapter : \u201cFlexoelectric Effect, Materials, and Structures\u201d, Chapter 5 in a book titled \u201cStructural Health Monitoring (SHM) in Aerospace Structures\u201d, edited by Fuh-Gwo Yuan, Woodhead Publishing, pp.119-148, 2016. (ISBN: 9780081001486)<\/li>\n
                      4. Huang, W.*, F.G. Yuan, and X. Jiang, Chapter : \u201cFlexoelectric Strain Gradient Sensing\u201d, Chapter 6 in a book titled \u201cStructural Health Monitoring (SHM) in Aerospace Structures\u201d, edited by Fuh-Gwo Yuan, Woodhead Publishing, pp. 149-174, 2016. (ISBN: 9780081001486)<\/li>\n
                      5. Zhang, S., F. Li, J. Li, W. Huang*, and X.N. Jiang, Chapter: \u201cCryogenic Piezoelectric Materials and transducers\u201d in a book edited by Yoseph Bar-Cohen, 2016.<\/li>\n
                      6. W.S. Hackenberger, J. Luo, X.N. Jiang, K. Snook, S. Zhang, and T. Shrout, \u201cRecent Development and Applications of Relaxor Piezoelectric Crystals\u201d, Chapter 3 in Part 1 of Book Edited by Z.G. Ye, Woodhead Publishing Limited, Cambridge, England, 2008. (ISBN 1 84569 186 5)<\/li>\n
                      7. V.K. Varadan, X.N. Jiang, and V.V. Varadan, \u201cMicrostereolithography and other Fabrication Techniques for 3D MEMS\u201d, John Wiley & Sons Ltd, England, 2001. (ISBN 0 471 52185 X)<\/li>\n
                      8. X.N. Jiang and X. Zhang, Chapter: \u201cMicromanufacturing\u201d in the book titled \u201cIndustrial Engineering Applications and Practices\u2014User\u2019s Encyclopedia\u201d, 14 pages, International Journal of Industrial Engineering, 1999 (ISBN 0-9654599-0-X).<\/li>\n<\/ol>\n

                        Refereed Conference Papers Published (*: student under advisory of Dr. Jiang)<\/span><\/em><\/strong><\/p>\n

                          \n
                        1. Kim, H.*, H. Wu*, and X. Jiang, \u201cMiniaturized Ultrasound Transducer Composed of a Composite of Multiple Piezoelectric Stacks\u201d, ASME IMECE2019-12208, Nov. 2019, Salt Lake City, UT.<\/li>\n
                        2. Goel, L.*, H. Wu*, H.* Kim, B. Zhang*, J. Kim, P. Dayton, Z. Xu, and X. Jiang, \u201cIntravascular Sonothrombolysis, in vitro, Using a Small Aperture, Forward-Viewing, Sub-Megahertz Transducer to Enhance tPA Treatment\u201d, 2019 IEEE Ultrasonics Symposium, Oct. 2019, Glasgow, UK.<\/li>\n
                        3. Cai, Q.*, C. Peng*, J. Prietoy, A. Rosenbaumy, J. Stringery, and X. Jiang, \u201cA Low-Cost Camera-Based Ultrasound Probe Tracking System: Design and Prototype\u201d, 2019 IEEE Ultrasonics Symposium, Oct. 2019, Glasgow, UK.<\/li>\n
                        4. Kim,, H.*, H. Wu*, P. Zhong, K. Mahmood, and X. Jiang, \u201cSmall Aperture Ultrasound Transducers for Intracavitary Tissue Ablation\u201d, 2019 IEEE Ultrasonics Symposium, Oct. 2019, Glasgow, UK.<\/li>\n
                        5. Lu, J. and X. Jiang, \u201cConformable Row-Column Ultrasound Arrays for Abdominal Imaging\u201d, 2019 IEEE Ultrasonics Symposium, Oct. 2019, Glasgow, UK.<\/li>\n
                        6. Wu, H.*, H. Kim *, and X. Jiang, \u201cFiber-optic laser-ultrasound transducer using carbon nanoparticles for intravascular sonothrombolysis\u201d, IEEE Nano 2019, July 2019, Macau, China.<\/li>\n
                        7. Kim, H.*, W. Chang*, T. Kim*, S. Huang*, and X. Jiang, \u201cStress Measurement of a Pressurized Vessel Using Candle Soot Nanocomposite Based Photoacoustic Excitation\u201d, SPIE Smart Structures and NDE, March 2019, Denver, CO.<\/li>\n
                        8. Kim, H.*, T. Kim*, D. Morrow*, and X. Jiang, \u201cStress Sensing Technique via Subsurface Longitudinal Wave with Composite Transducer\u201d, 2019 ANS NPIC&HMIT, Orlando, FL, Feb. 2019.<\/li>\n
                        9. Kim, H.*, J. Kim, H. Wu*, and X. Jiang, \u201cDesign of Forward-Looking Intravascular Ultrasonic Transducer for Microbubble-Mediated Thrombolysis\u201d, ASME IMECE2018-86464, Pittsburgh, PA, Nov. 2018.<\/li>\n
                        10. Zhang, B.*, H. Wu*, Y. Gao, and X. Jiang, \u201cUltrasound Thrombolysis with Magnetic Microbubbles Under a Rotational Magnetic Field\u201d, IEEE NMDC 2018, Portland, OR, Oct. 2018.<\/li>\n
                        11. Wu, H.*, M. Hossain, C. Gallippi, and X, Jiang, \u201cA row-column array for ultrasound-based tissue anisotropy measurement\u201d, 2018 IEEE Ultrasonics Symposium, Oct. 2018, Kobe, Japan.<\/li>\n
                        12. Kim, H.*, H. Wu*, J. Kim*, and X. Jiang, \u201cMiniaturized Sub-Megahertz Focused Ultrasound Transducer Composed of Multilayer Hard PZT Ceramics\u201d, 2018 IEEE Ultrasonics Symposium, Oct. 2018, Kobe, Japan.<\/li>\n
                        13. Chang, W.* and X. Jiang, \u201cA Fiber Optic Laser Ultrasound Transducer using Carbon Nanoparticles\/PDMS Composites\u201d, IEEE Nano Conference, July 2018, Cork, Ireland.<\/li>\n
                        14. Chang, W.* and X. Jiang, \u201cA Fiber Optic Laser Ultrasound Transducer using Carbon Nanoparticles\/PDMS Composites\u201d, IEEE Nano Conference, July 2018, Cork, Ireland.<\/li>\n
                        15. Berik, P., W. Chang*, and X. Jiang, \u201cPiezoelectric torsional actuation in d36 shear-mode PMN-PT single crystals\u201d, SPIE Smart Structures and NDE, March 2018, Denver, CO.<\/li>\n
                        16. Kim, T.*, Z. Cui, Y. Zhu, and X. Jiang, \u201cFlexible Piezo-Composite Ultrasound Transducers for Biomedical Applications\u201d, SPIE Smart Structures and NDE, March 2018, Denver, CO.<\/li>\n
                        17. Kim, T.*, H. Kim*, and X. Jiang, \u201cHigh Temperature Transducer using Aluminum Nitride Single Crystal for Laser Ultrasound Detection\u201d, SPIE Smart Structures and NDE, March 2018, Denver, CO.<\/li>\n
                        18. Kim, J.*, H. Wu*, and X. Jiang, \u201cMiniaturized Focused Ultrasound Transducers for Intravascular Therapies\u201d, ASME IMECE2017-72426, Tampa, FL, Nov. 2017.<\/li>\n
                        19. Kim, J.*, B. D. Lindsey, W. Chang*, H. Wu*, P, A. Dayton, and X. Jiang, \u201cDevelopment of Forward-Looking Ultrasound Transducers for Microbubble-Aided Intravascular Ultrasound-Enhanced Thrombolysis\u201d, IEEE Ultrasonics Symposium, Washington DC, Sept. 2017.<\/li>\n
                        20. Kim, J.*, W. Chang*, H. Wu*, P. A. Dayton, and X. Jiang, \u201cOptical Fiber Laser-Generated-Focused-Ultrasound Transducers for Intravascular Therapies\u201d, IEEE Ultrasonics Symposium, Washington DC, Sept. 2017.<\/li>\n
                        21. Wu, H.*, S. Li*, S. Kasoji, P. Dayton, and X. Jiang, \u201cMicromachined 1-3 Composite Dual Frequency IVUS Array for Contrast Enhanced Intravascular Ultrasound Imaging\u201d, IEEE Ultrasonics Symposium, Washington DC, Sept. 2017.<\/li>\n
                        22. Chang, W.*, A. Xu Zhang, J. Kim*, W. Huang, C. Chang, and X. Jiang, \u201cPhotoacoustic Transduction Efficiency Evaluation of Candle Soot Nanoparticles\/PDMS Composites\u201d, IEEE Nano Conference, July 2017, Pittsburgh, PA.<\/li>\n
                        23. Kim, T.*, J. Kim*, and X. Jiang, \u201cHigh temperature transducer using aluminum nitride single crystal for laser ultrasound detection\u201d, SPIE Smart Structures and NDE, March 2017, Portland, OR.<\/li>\n
                        24. Kim, J.*, B. D. Lindsey*, S. Li*, P. A. Dayton, and X. Jiang, \u201cDual-Frequency Transducer with a Wideband PVDF Receiver for Contrast-Enhanced, Adjustable Harmonic Imaging\u201d, SPIE Smart Structures and NDE, March 2017, Portland, OR.<\/li>\n
                        25. Lindsey, B.*, P. Dayton, J. Kim*, and X. Jiang, \u201cA dual-frequency endoscopic transducer for imaging vascular invasion in pancreatic cancer\u201d, IEEE Ultrasonics Symposium, Tours, France, Sept. 2016.<\/li>\n
                        26. Lindsey, B.*, X. Jiang, P. A. Dayton, \u201cAdaptive windowing in mechanically-steered intravascular ultrasound imaging: ex vivo and in vivo studies with contrast enhancement\u201d, IEEE Ultrasonics Symposium, Tours, France, Sept. 2016.<\/li>\n
                        27. Li, S.*, J. Kim*, Z. Wang*, S. Kasoji, B. Lindsey*, P. Dayton, and X. Jiang, \u201cA dual-frequency co-linear array for prostate acoustic angiography\u201d, IEEE Ultrasonics Symposium, Tours, France, Sept. 2016.<\/li>\n
                        28. Kim, J.*, W. Chang*, B. Lindsey*, P. Dayton, X. Dai, J. Stavas, and X. Jiang, \u201cLaser-generated-focused ultrasound transducers for microbubble-mediated, dual-excitation sonothrombolysis\u201d, IEEE Ultrasonics Symposium, Tours, France, Sept. 2016.<\/li>\n
                        29. Kim, T.*, A. Saini, J. Kim*, A. Gopalarathnam, Y.Zhu, F. L. Palmieri, C. J. Wohl, and X. Jiang, \u201cA piezoelectric shear stress sensor\u201d, SPIE Smart Structures and NDE, March 2016, Las Vegas, NE.<\/li>\n
                        30. Wang, Z.*, T. J Czernuszewicz, C. M. Gallippi and X. Jiang, \u201cDual frequency IVUS transducer for acoustic radiation force impulse imaging (ARFI)\u201d, 2015 IEEE Ultrasonics Symposium, Oct. 2015, Taipei, Taiwan.<\/li>\n
                        31. Wang, Z.*, W. Huang*, K. H. Martin, P. A. Dayton and X. Jiang \u201cDual frequency IVUS array for contrast enhanced intravascular ultrasound imaging\u201d, 2015 IEEE Ultrasonics Symposium, Oct. 2015, Taipei, Taiwan.<\/li>\n
                        32. Li, S.*, J. Kim*, S. Kasoji, P. A. Dayton and X. Jiang, \u201c3\/15 MHz Dual-layer Co-Linear Array for Transrectal Acoustic Angiography\u201d, 2015 IEEE Ultrasonics Symposium, Oct. 2015, Taipei, Taiwan.<\/li>\n
                        33. Li, S.*, Z. Wang*, J. Kim*, W. Huang*, J. Tian, P. Han, C. Zhang and X. Jiang, \u201cA PMN-PT Micromachined 1-3 Composite IVUS Ultrasound Array\u201d, 2015 IEEE Ultrasonics Symposium, Oct. 2015, Taipei, Taiwan.<\/li>\n
                        34. Wang, Z.*, K. H. Martin, P. A. Dayton and X. Jiang, \u201cA dual frequency IVUS transducer with a lateral mode transmitter for contrast enhanced intravascular ultrasound imaging\u201d, ASME IMECE2015-51141, Houston, TX, Nov. 2015.<\/li>\n
                        35. Li, S.*, W. Huang*, and X. Jiang, \u201c40-MHz Micromachined PMN-PT Composite Ultrasound Array for Medical Imaging\u201d, ASME IMECE2015-52540, Houston, TX, Nov. 2015.<\/li>\n
                        36. Kim, J.*, S. Li*, S. Kasoji, P. A. Dayton, X. Jiang, \u201cDual-frequency Super Harmonic Imaging Piezoelectric Transducers for Transrectal Ultrasound\u201d, SPIE Smart Structures and NDE, 2015. San Diego, CA.<\/li>\n
                        37. Wang, Z.*, S. Li*, R. Liu, X. Geng, and X.N. Jiang, \u201cA bi-frequency co-linear array transducer for medical ultrasound imaging\u201d, ASME IMECE 2014-38871, Montreal, Canada, Nov. 2014.<\/li>\n
                        38. Guo, S.* and X.N. Jiang, \u201cEnhancement of ultrasonic cavitation yield by dual frequency sonication\u201d, ASME IMECE2014-39641, Montreal, Canada, Nov. 2014.<\/li>\n
                        39. Ma, J.*, S. Li*, Z. Wang*, and X.N. Jiang, \u201cAnti-matching design for wave isolation in dual frequency transducer for intravascular super-harmonic imaging\u201d, ASME IMECE2014-38844, Montreal, Canada, Nov. 2014.<\/li>\n
                        40. Wang, Z.*, S. Li*, R. Liu, X. Geng, and X.N. Jiang, \u201cA bi-frequency 7.5MHz\/15MHz co-linear array\u201d, IEEE Ultrasonics Symposium, Chicago, IL, Sept. 2014.<\/li>\n
                        41. Guo, S.*, A. Smith, L. Phillips, P. Dayton, and X.N. Jiang, \u201cEnhancement of ultrasonic cavitation by dual-frequency sonication: experimental and theoretical assessment\u201d, IEEE Ultrasonics Symposium, Chicago, IL, Sept. 2014.<\/li>\n
                        42. Li, S.*, J. Tian, P. Han, X.N. Jiang, \u201c20 MHz\/40 MHz Dual-layer Micromachined Composite Transducer for Tissue Harmonic Imaging\u201d, IEEE Ultrasonics Symposium, Chicago, IL, Sept. 2014.<\/li>\n
                        43. Wang, Z.*, J. Ma*, K. Martin, P. Dayton, and X.N. Jiang, \u201cAn array transmitter for contrast enhanced intravascular ultrasound imaging\u201d, IEEE Ultrasonics Symposium, Chicago, IL, Sept. 2014.<\/li>\n
                        44. Ma, J.*, K. Martin, Y. Li, P. Dayton, Q. Zhou, K. Shung, and X.N. Jiang, \u201cDual frequency transducers for super harmonic intravascular ultrasound imaging\u201d, IEEE Ultrasonics Symposium, Chicago, IL, Sept. 2014.<\/li>\n
                        45. Kim, K.*, J. Johnson*, and X.N. Jiang, \u201cHigh temperature (> 1000 \u00b0C) piezoelectric sensors for nuclear applications\u201d, Proc. ICAPP 2014, Charlotte, NC, April 6-9, 2014.<\/li>\n
                        46. Johnson, J.*, K. Kim*, S. Zhang, and X.N. Jiang, \u201cCrack Propagation Testing Using an YCOB Acoustic Emission Sensor\u201d, SPIE Smart Structures and NDE, 2014. San Diego, CA.<\/li>\n
                        47. Huang, W.*, S. Yang, N. Zhang, F.G. Yuan, and X.N. Jiang, \u201cCracks Monitoring and Characterization using Ba0.64Sr0.36TiO3 Flexoelectric Strain Gradient Sensors\u201d, SPIE Smart Structures and NDE, 2014. San Diego, CA.<\/li>\n
                        48. Kwon, S.*, W. Huang*, S. Zhang, F.G. Yuan, and X.N. Jiang, \u201cA new type of microphone using flexoelectric barium strontium titanate\u201d, SPIE Smart Structures and NDE, 2014. San Diego, CA.<\/li>\n
                        49. Kwon, S.*, W. Huang*, B. Rogers, J.P. Maria, F.G. Yuan, S. Zhang, and X.N. Jiang, \u201cCharacterization of flexoelectric barium strontium titanate thin film\u201d, 16th US-Japan Seminar on Dielectric and Piezoelectric Materials, Raleigh, NC, Nov. 2-6, 2013.<\/li>\n
                        50. Kim, K.* and X.N. Jiang, \u201cAcoustic Wave Microsensor Array for Tactile Sensing\u201d, ASME IMECE 2013-66098, San Diego, CA, Nov. 15-21, 2013.<\/li>\n
                        51. Tolliver, L.*, X.N. Jiang, and T. Xu, \u201cPiezoelectric Actuators with Active and Passive Frames\u201d, ASME 2013 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, SMASIS2013, Snowbird, UT Sept. 16-18, 2013.<\/li>\n
                        52. Li, S.*, W. Huang*, X. Jian, Y. Cui, and X.N. Jiang, \u201cA Dual-layer Micromachined PMN-PT 1-3 Composite Transducer for Broadband Ultrasound Imaging\u201d, IEEE Ultrasonic Symposiums, Prague, Czech, July 2013.<\/li>\n
                        53. Wang, Z.*, S. Li*, X.N. Jiang, R. Liu and X. Geng, \u201c Design, fabrication and characterization of a bi-frequency co-linear array (7.5MHz\/15MHz)\u201d, IEEE Ultrasonic Symposiums, Prague, Czech, July 2013.<\/li>\n
                        54. Johnson, J.*, K. Kim*, S. Zhang, D. Wu, and X.N. Jiang, \u201cHigh-temperature (> 1000 \uf0b0C) acoustic emission sensor\u201d, Proc. SPIE Smart Materials and Structures and NDE, 8694, 869428, pp.1-12 (2013).<\/li>\n
                        55. Ma, J.*, X.N. Jiang, K. Martin, and P. Dayton, \u201cSmall Aperture, Dual Frequency Ultrasound
                          \nTransducers for Intravascular Contrast Imaging\u201d, IEEE Ultrasonic Symposiums, Prague, Czech, July 2013.<\/li>\n
                        56. Yan, X., W. Huang*, X.N. Jiang and F. Yuan, \u201cDesign of a Curvature Sensor using a Flexoelectric Materials\u201d, SPIE Smart Structures and NDE, 2013. San Diego, CA.<\/li>\n
                        57. Huang, W. *, S. Kwon*, S. Zhang, F. G. Yuan and X.N. Jiang, \u201cA Flexoelectric Micro-accelerometer\u201d, ASME IMECE2012-89814, Houston, TX, Nov. 2012.<\/li>\n
                        58. Kim, K.*, S. Zhang, and X.N. Jiang, \u201cFace-shear Mode Ultrasonic Tactile Sensor Array\u201d, IEEE Ultrasonic Symposiums, Dresden, Germany, October 2012.<\/li>\n
                        59. Salazar, G.*, K. Kim*, X.N. Jiang, and S. Zhang, \u201cPiezoelectric Accelerometer for High Temperature (1300\u00b0C) Sensing\u201d, Proc. SPIE 8347, 83471K (2012); http:\/\/dx.doi.org\/10.1117\/12.917104 .<\/li>\n
                        60. Huang, W*., K. Kim*, S. Zhang, F. Yuan and X.N. Jiang, \u201c Flexoelectric Strain Gradient Sensing Using Microcantilevers\u201d, International Symposium on Innovation & Sustainability of Structures in Civil Engineering, Xiamen University, China, Oct. 28-30, 2011.<\/li>\n
                        61. Huang, W.*, X.N. Jiang, and F.G. Yuan, \u201cFlexoelectric Materials and Structures for M\/NEMS\u201d, ASME IMECE2011-64520, Denver, Nov. 2011.<\/li>\n
                        62. Bakshi, S.*, S. Guo*, and X.N. Jiang, \u201cMulti-frequency Focused Ultrasound for Tissue Ablation\u201d, ASME IMECE2011-64076, Denver, Nov. 2011.<\/li>\n
                        63. Xu, T., E. J. Siochi, J. H. Kang, L. Zuo, W. Zhou, X. Tang, and X.N. Jiang, \u201cA Piezoelectric PZT Ceramic Multilayer Stack for Energy Harvesting Under Dynamic Forces,\u201d ASME DETC2011-47720, 2011.<\/li>\n
                        64. Guo, S.*, X.N. Jiang, and W. Lin, \u201cTissue Ablation Using Multi-frequency Focused Ultrasound\u201d, IEEE Ultrasonic Symposiums, Orlando, October, 2011.<\/li>\n
                        65. Bakshi, S. *, J. Williams, X.N. Jiang, and E. Loboa, \u201cCell Characterization Using High Frequency Ultrasound\u201d, IEEE Ultrasonic Symposiums, Orlando, October, 2011.<\/li>\n
                        66. Kim, K.*, X.N. Jiang, and S. Zhang, \u201cA High Temperature Piezoelectric Sensor for Structure Health Monitoring\u201d, Proc. SPIE Smart Materials and Structures and NDE, 7983, 79832V (2011).<\/li>\n
                        67. Chen, C., J. Liu, Y. Luo, X. Han, J. Liao, X.N. Jiang, and F.G. Yuan, \u201cFabrication of 1-3 Piezo-Composites Using New Micro PZT Fibers\u201d, Proc. SPIE Smart Materials and Structures and NDE, 7983, 79833M (2011).<\/li>\n
                        68. Zheng, F., C. Hu, L. Zhang, K. Snook, Y. Liang, S. Hackenberger, R. Liu, X. Geng, X.N. Jiang and K. Shung, \u201cDevelopment of a C-Scan Phased Array Ultrasonic Imaging System Using a 64-element 35MHz Transducer\u201d, Proc. SPIE Smart Materials and Structures and NDE, 7983, 79833E (2011).<\/li>\n
                        69. Hu, C., F. Zheng, P. Sun, L. Zhang, XN. Jiang, K. Snook, W. Hackenberger, R. Liu, X. Geng, and K. Shung, \u201cDevelopment of a Digital 35 MHz, 64-channel Phased Ultrasound Array Imaging System for NDT Applications\u201d, Proc. IEEE Ultrasonics Symposium, pp.1829-1832, 2010.<\/li>\n
                        70. Lapsley, M.I., E.F. Alberta, R. Sahul, W.S. Hackenberger, X.N. Jiang, S. Zhang, and T.R. Shrout, “Piezoelectric Structural Sensor Technology for Extreme Environments,” 2010 High Temperature Electronics Conference (HiTEC), Albuquerque, NM, May 10-14, 2010.<\/li>\n
                        71. Jiang, X.N., K. Snook, R. Liu , X. Geng, and W. Hackenberger, \u201cFabrication and Characterization of High Frequency Phased Arrays for NDE Imaging\u201d, Proc. SPIE Smart Materials and Structures and NDE, 7649-30 (2010).<\/li>\n
                        72. Jiang, X.N., W. Cook, and W.S. Hackenberger, \u201cCryogenic Piezoelectric Actuators\u201d, Proc. SPIE Optical Engineering + Applications, Vol. 7439, 74390Z (2009).<\/li>\n
                        73. Jiang, X.N., K. Snook, C. Hu, X. Geng, R. Liu, J. Welter, K. Shung, and W. Hackenberger, \u201cA 35 MHz PCMUT Phased Array for NDE Ultrasound\u201d, Proc. SPIE Smart Materials and Structures and NDE, Vol. 7294(1): 729403-8 (2009).<\/li>\n
                        74. Jiang, X.N., K. Snook, T. Walker, A. Portune, R. Haber, X. Geng, J. Welter, and W.S. Hackenberger, ” Single Crystal Piezoelectric Composite Transducers for Advanced NDE applications\u201d, Proc. SPIE Smart Materials and Structures and NDE, Vol. 6934, 6934-12 (2008).<\/li>\n
                        75. Jiang, X.N., K. Snook, A. Cheng, W.S, Hackenberger, and X. Geng, \u201cMicroamchined PMN-PT Single Crystal Composite Transducers: 15 \u2013 75 MHz PCMUT\u201d, Proc. IEEE Ultrasonics Symposium, pp.164-167, 2008.<\/li>\n
                        76. Yuan, J., S. Rhee, and X.N. Jiang, \u201c60 MHz PMN-PT Based 1-3 Composite Transducer for IVUS Imaging\u201d, Proc. IEEE Ultrasonics Symposium, pp.682-685, 2008.<\/li>\n
                        77. Zhang, S., H. J. Lee, X.N. Jiang, J. Luo, G. Gerber, and T. Shrout, \u201cFrequency Dependent Properties of High Permittivity PMNT Piezoelectric for Ultrasonic Transducer Applications\u201d, Proc. IEEE Ultrasonics Symposium, pp.265-268, 2008.<\/li>\n
                        78. Jiang, X.N., K. Snook, W.S, Hackenberger, A. Cheng, and J. Xu, \u201cPiezoelectric Transducers using Micromachined Bulk Piezo Substrates\u201d, Proc. IEEE Sensors, pp.573-576, 2008.<\/li>\n
                        79. Jiang, X.N., K. Snook, W.S. Hackenberger, and M. Shafer, “PC-MUT Arrays for Ophthalmologic Ultrasound”, Proc. IEEE Ultrasonics Symposium, pp.309-312, 2007.<\/li>\n
                        80. Snook, K., X. Geng, W.S. Hackenberger, X.N. Jiang, A. Winder, F. Forsberg, “Optimization of Single Crystal Composite Arrays for Harmonic Imaging”, Proc. IEEE Ultrasonics Symposium, pp.292-295, 2007.<\/li>\n
                        81. Jiang, X.N., K. Snook, and W.S. Hackenberger, \u201cSingle Crystal Piezoelectric Composites for Advanced NDE Ultrasound\u201d, Proc. SPIE Smart Materials and Structures, Vol. 6531, 65310F, 2007.<\/li>\n
                        82. Jiang, X.N., J.R. Yuan, A. Cheng, K. Snook, and W.S. Hackenberger, \u201cMicro\/Nano Piezoelectric Composites for Advanced M\/NEMS\u201d, Proc. ASME MicroNanoChina, 20070110-13, 2007.<\/li>\n
                        83. Jiang, X.N., P.W. Rehrig, J. Luo, W.S. Hackenberger, S.J. Zhang, and T. Shrout, \u201cLow-Voltage Single Crystal Actuators\u201d, Proc. SPIE Smart Materials and Structures, Vol. 6170, 61700G, 2006.<\/li>\n
                        84. Jiang, X.N., J.R. Yuan, A. Cheng, G. Lavallee, P.W. Rehrig, K. Snook, S. Kwon, W.S. Hackenberger, J. Catchmark, J. McIntosh, and X. Geng, \u201cMicromachined PMN-PT Single Crystal for Advanced Transducers\u201d, Technical Digest of Solid-State Sensors, Actuators, and Microsystems Workshop, pp. 384-387, 2006.<\/li>\n
                        85. Jiang, X.N., J.R. Yuan, A. Cheng, K. Snook, PJ Cao, P.W. Rehrig, W.S. Hackenberger, G. Lavallee, X. Geng, and T.R. Shrout, \u201cMicrofabrication of Piezoelectric Composite Ultrasound Transducers (PC-MUT)\u201d, Proc. IEEE Ultrasonics Symposium, pp.918-921, 2006.<\/li>\n
                        86. Yuan, J., X.N. Jiang, P. Cao, K. Snook, P. Rehrig and W. Hackenberger, \u201cHigh Frequency Piezo Composites Microfabricated Ultrasound Transducers for Intravascular Imaging\u201d, Proc. IEEE Ultrasonics Symp., pp.264-268, 2006.<\/li>\n
                        87. Xu, T.B., J. Su, X.N. Jiang, P. W. Rehrig, S. Zhang, T. R. Shrout, and Q. Zhang, \u201cEffect of bending stiffness of the electroactive polymer element on the performance of a Hybrid Actuator System (HYBAS),\u201d Proceedings of SPIE Vol. 6168, pp. 61682H-1-61682H-9, 2006.<\/li>\n
                        88. Xu, T.B., J. Su, X.N. Jiang, P. W. Rehrig,, and W. S. Hackenberger, \u201cHigh Load Capable Piezoelectric Single Crystal Actuators,\u201d Mater. Res. Soc. Symp. Proc., Vol. 888, 0888-V08-02.1, 2006.<\/li>\n
                        89. Jiang, X.N., P.W. Rehrig, W.S. Hackenberger, and T. R. Shrout, \u201cCryogenic Actuators and Motors Using Single Crystal Piezoelectrics\u201d, Advances in Cryogenic Engineering, Vol. 51B, pp. 1783-1789, 2005.<\/li>\n
                        90. Jiang, X.N., P.W. Rehrig, W.S. Hackenberger, S. Perini, M. Lanagan, X.X. Xi, E. Furman, E. Prophet, B. Willemsen, and B. Hammond, \u201cSingle Crystal Piezoelectric Actuators for Tunable HTS Filters\u201d, Advances in Cryogenic Engineering, Vol. 51A, pp. 928-935, 2005.<\/li>\n
                        91. Snook, K., P. W. Rehrig, X.N. Jiang, W. S. Hackenberger, R. J. Meyer, and D. Markley, \u201cAdvanced Piezoelectric Single Crystal Based Transducers for Naval Sonar Applications\u201d, Proc. IEEE Ultrasonic Symposium, pp.1065-1068, 2005.<\/li>\n
                        92. Jiang, X.N., P. W. Rehrig, W. S. Hackenberger, E. Smith, S. Dong, D. Viehland, J. Moore, B. Patrick, \u201cAdvanced Piezoelectric Single Crystal Based Actuators\u201d, Proc. SPIE Smart Materials and Structures, Vol. 5761, pp.253-262, 2005.<\/li>\n
                        93. Rehrig, P.W., W.S. Hackenberger, X.N. Jiang, R.J. Meyer, \u201cAdvanced Piezoelectric Single-Crystal-Based Transducers for Naval Sonar Applications\u201d, Proc. SPIE Smart Materials and Structures, Vol. 5761, pp.263-271, 2005.<\/li>\n
                        94. Jiang, X.N., P.W. Rehrig, W.S. Hackenberger, J. Moore, S. Chodimella and B. Patrick, \u201cSingle Crystal Piezoelectric actuators for advanced deformable mirrors\u201d, Proc. ASME International Mechanical Engineering Congress and Exposition, Vol.3, IMECE-60504, 2004.<\/li>\n
                        95. Jiang, X.N., S. Dong, P.W. Rehrig, W.S. Hackenberger, D. Viehland, \u201cSingle Crystal Ultrasonic Motor for Cryogenic Actuations\u201d, Proc. IEEE UFFC, pp. 1314-1317, 2004.<\/li>\n
                        96. Hackenberger, W.S., X.N.Jiang, X.Geng, A. Winder, and F. Forsberg, \u201cBroad Band Single Crystal Transducer for Contrast Agent Harmonic Imaging\u201d (II), Proc. IEEE UFFC, Montreal, pp. 1-30-1033, 2004.<\/li>\n
                        97. Hackenberger, W.S., X.N. Jiang, X. Geng, A. Winder, and F. Forsberg, \u201cBroadband Single Crystal Transducer for Contrast Agent Harmonic Imaging\u201d (I), Proc. IEEE Ultrasonics Symposium, pp. 778-781, 2003.<\/li>\n
                        98. Jiang, X.N., P.W. Rehrig, W. Hackenberger, and T. Shrout, \u201cLarge Stroke and Low Profile Single Crystal Piezoelectric Actuators\u201d, SPIE Proceeding Vol.5053, pp.436-444, 2003.<\/li>\n
                        99. Rehrig, P.W., W.S. Hackenberger, X.N.Jiang, R. J. Meyer, and X. Geng, \u201cHigh-performance Tonpilz Transducers Utilizing d32-cut Piezoelectric Single Crystals\u201d, SPIE Proceedings, Vol. 5053, pp.445-452, 2003.<\/li>\n
                        100. Tutwiler, T.R., J.P. Titter, T.A. Ritter, K.K. Shung, W.S. Hackenberger, X.N.Jiang, and P.W. Rehrig, \u201cPrecision Mechanically Scanned HF Ultrasound Arrays\u201d, Proc. IEEE Ultrasonics Symposium, pp.863-876, 2003.<\/li>\n
                        101. Rehrig, P.W., W. Hackenberger, X.N. Jiang, R. Meyer, and X. Geng, \u201cNaval Device Applications of Relaxor Piezoelectric Single Crystals\u201d, Proc. IEEE Proc. Ultrasonics Symposium, pp.733-737, 2002.<\/li>\n
                        102. Jiang, X.N., \u201cMicrofabrications for Ceramic MEMS\u201d, Technical Digest of Berkeley MEMS, pp.45-46, 2001.<\/li>\n
                        103. Sun, C., X.N. Jiang, and X. Zhang, \u201cExperimental and numerical study on micro-stereolithography of ceramics\u201d, ASME MEMS-Vol. 1, pp.339-345, 1999.<\/li>\n
                        104. Jiang, X.N., C. Sun and X. Zhang, \u201cMicro-stereolithography of 3D complex ceramic microstructures and PZT thick films on Si substrate\u201d, ASME MEMS-Vol.1, pp.67-73, 1999.<\/li>\n
                        105. Zhang, X., X.N. Jiang, and C. Sun, \u201cMicro-scale free surface rapid prototyping\u201d, Technical Digest of CLEO\u201999, Baltimore, Maryland, US, May 23-28, pp.513-514, 1999.<\/li>\n
                        106. Zhang, X., X. N. Jiang, and C. Sun, \u201cMicrostereolithography for MEMS\u201d, ASME DSC, Vol.66, pp.3-9, 1998.<\/li>\n
                        107. Jiang, X.N., Z. Y. Zhou, X. Y. Huang, and C. Y. Liu, \u201cLaminar Flow Through Microchannels Used for Microscale Cooling Systems\u201d, Proc. of IEEE 1st Electronic Packaging Technology Conference, pp. 119-122, 1997.<\/li>\n
                        108. Jiang, X.N., Z. Y. Zhou, Y. Li, Y. Yang, X.Y. Ye, X. Y. Huang, and C. Y. Liu, \u201cMicrodynamics for Reciprocating Micropumps\u201d, International Conference on Micromechatronics for Information and Precision Equipment, pp. 698-701, 1997.<\/li>\n
                        109. Jiang, X.N., Z. Y. Zhou, Y. Li, Y. Yang, X. Y. Huang, and C. Y. Liu, \u201cExperiments and Analysis for Micro-Nozzle\/Diffuser Flow and micro Valveless Pumps\u201d, Technical Digest of Transducers\u201997, pp369-372, 1997.<\/li>\n
                        110. Yang, Y., Z.Y. Zhou, X.Y. Ye, and X.N. Jiang, \u201cA Bimetallic Thermally Actuated Micropump\u201d, ASME DSC-Vol.59, pp.351-354, 1996.<\/li>\n
                        111. Jiang, X.N., Z. Y. Zhou, Y. Li, Y. Yang, and X. Y. Ye, \u201cFlow Behavior Through Microfluidic Valves\u201d, ASME DSC-Vol.59, pp.221-224, 1996.<\/li>\n
                        112. Jiang, X.N., Z. Y. Zhou, Y. Li, X. Y. Ye, and Y. Yang, \u201cFlow Modeling Analysis for Microvalves and Micropumps\u201d, The 3rd Asian\/Pacific International Symposium on Instrumentation, Measurement and Automatic Control, Beijing, China, Aug.20-23, pp.95-98, 1996.<\/li>\n
                        113. Jiang, X.N., Z. Y. Zhou, J. Yao, Y. Li, and X. Y. Ye, \u201cMicrofluid Flow in Microchannel\u201d, Tansducers’95, Vol.2 pp317-320, 1995.<\/li>\n<\/ol>\n

                          \n<\/div>\n

                          \n

                          PATENTS AWARDED<\/h3>\n
                            \n
                          1. Xu, T., E. Siochi, L. Zuo, X. Jiang, and J. Kang, \u201cMultistage Force Amplification of Piezoelectric Stacks\u201d, US Patent #9,048,759 B2, 2015<\/li>\n
                          2. Xu, T., X.N. Jiang, and J. Su, \u201cPiezoelectric Multilayer-Stacked Hybrid Actuation\/Transduction System\u201d,\u00a0US\u00a0Patent\u00a0#\u00a08680749 B2, 2014.<\/li>\n
                          3. Xu, T., J. Su, and X.N. Jiang, \u201cAdvanced Modified High Performance Synthetic Jet Actuator with Curved Chamber\u201d,\u00a0US\u00a0Patent\u00a0#8662412 B2, 2014.<\/li>\n
                          4. Xu, T., X.N. Jiang, and J. Su, “Advanced high performance horizontal piezoelectric hybrid synthetic jet actuator”, US patent # 8,235,309, 2012.<\/li>\n
                          5. Jiang, X.N., W.S. Hackenberger, and K. Snook, \u201cMicromachined Piezoelectric Ultrasound Transducer Arrays\u201d, US Patent # 8148877, 2012.<\/li>\n
                          6. Xu, T., X.N. Jiang, and J. Su, \u201cAdvanced high performance vertical hybrid synthetic jet actuator,\u201d US Patent # 8052069, 2011.<\/li>\n
                          7. Jiang, X.N., W.S. Hackenberger, and K. Snook, \u201cMicromachined Piezoelectric Ultrasound Transducer Arrays\u201d, US Patent # 8008842, 2011.<\/li>\n
                          8. Rehrig, P., X.N. Jiang, W. Hackenberger, J. Yuan and R. Romley, \u201cMicromachined Imaging Transducer\u201d,\u00a0 US Patent # 7622853, 2009.<\/li>\n
                          9. Xu, T., X.N. Jiang, J. Su, P. Rehrig, and W. Hackenberger, “Hybrid Piezoelectric Energy Harvesting Transducer System”\u00a0 US Patent # 7446459, 2008.<\/li>\n<\/ol>\n

                             <\/p>\n

                            PATENTS FILED<\/h3>\n
                              \n
                            1. Jiang, X., P. Dayton, J. Kim, and Z. Xu, \u201cThe use of phase change nanodroplets to enhance sonothrombolysis\u201d, US Patent Appl. No. 62\/897, 759; Filed September 9, 2019; PCT\/US2017\/042372, Sept. 9, 2020.<\/li>\n
                            2. Jiang, X., T. Kim*, and Y. Zhu, \u201cFlexible piezo-composite sensors and transducers\u201d, US Patent Appl. No. 62\/813,896; Filed March 05, 2019.<\/li>\n
                            3. Jiang, X. and B. Zhang*, \u201cSystem and methods for ultrasound induced thrombolysis with magnetic microbubbles and a rotational magnetic field\u201d, US Patent Appl. No. 62\/744,784Y; Filed Oct. 12, 2018.<\/li>\n
                            4. Jiang, X., J. Kim*, J. Ma*, and X. Dai, \u201cUltrasound transducers and arrays for intravascular thrombolysis\u201d, US Patent Appl. No. PCT\/US2017\/042372, Filed July 14, 2017; International application WO2018\/014021 A3, Jan. 2018.<\/li>\n
                            5. Jiang, X. and J. Kim*, \u201cHybrid Ultrasound Transducer and Array for Intravascular Thrombolysis\u201d, US Patent Appl. No. 62\/362,687; Filed July 15, 2016.<\/li>\n
                            6. Jiang, X., T. Kim*, and J. Kim* , \u201cUltrasonic Flowmeter for Intravenous Flow Rate Measurement\u201d, 62\/723,287; Filing Date: August 27, 2018.<\/li>\n
                            7. Dayton, P. and X.N. Jiang, \u201cCatheter Device Implementing High Frequency, Contrast Imaging Ultrasound Transducer, and Associated Method\u201d, US Patent Application # 61\/654,335, June 2012; PCT\/US2013\/043002, May 2013.<\/li>\n<\/ol>\n<\/div>\n
                              \n

                              INVENTION DISCLOSURES (NCSU)<\/h3>\n
                                \n
                              1. Jiang, X. and H. Kim*, \u201cMulti-pillar piezoelectric stack (MPPS) Intravascular Transducer\u201d, NCSU Disclosure No. 20115, Nov. 2019.<\/li>\n
                              2. Jiang, X. and B. Zhang*, \u201cUltrasound and Magnetic Field Mediated Intravascular Thrombolysis with Magnetic Microbubbles\/Nanodroplets\u201d, NCSU Disclosure No. 20054, Sept. 2019.<\/li>\n
                              3. Jiang, X., H. Wu*, J. Yao, and Y. Tang, \u201cPhotoacoustic Imaging Guided Intravascular Thrombolysis\u201d, NCSU Disclosure No. 20027, August. 2019.<\/li>\n
                              4. Jiang, X., P. Dayton, J. Kim, Y. Jing, and Z. Xu, \u201cThe use of Phase Change Nanodroplets to Enhance Sonothrombolysis\u201d, NCSU Disclosure No. 20010, July. 2019.<\/li>\n
                              5. So, F., H. Yu, X. Jiang, J. Kim*, and N. Barange, \u201cPiezoelectric Organic Light-Emitting Diode for Ultrasound Imaging\u201d, NCSU Disclosure No. 18288, July 2018.<\/li>\n
                              6. Jiang, X. and B. Zhang*, \u201cUltrasonic and Magnetic Thrombolysis with Magnetic Microbubbles\u201d, NCSU Disclosure No. 18295, June 2018.<\/li>\n
                              7. Mahmood, K. P. Zhong, H. Lyerly, \u201cHigh-intensity Focused Ultrasound Device for Bronchoscopy\u201d, NCSU Disclosure No. 18292, June 2018.<\/li>\n
                              8. Jiang, X., T. Kim*, and Y. Zhu, \u201cFlexible piezo-composite sensors and transducers\u201d, NCSU Invention Disclosure No. 18114, Dec. 2017.<\/li>\n
                              9. Jiang, X., T. Kim*, and J. Kim*, \u201cUltrasonic Flowmeter for Intravenous Flow Rate Measurement\u201d, NCSU Invention Disclosure No. 17108, Nov. 2016.<\/li>\n
                              10. Jiang, X., T. Kim*, and J. Kim*, \u201cPiezoelectric Floating Element Shear Stress (PeFESS) Sensor for Flow Measurements\u201d, NCSU Invention Disclosure No. 17043, Aug. 2016. Jiang\u2019s resume (as of Nov. 2020)<\/li>\n
                              11. Jiang, X., W. Chang*, J. Kim*, and W. Huang*, \u201cCandle soot nanoparticles-PDMS composites for novel photoacoustic transducers\u201d, NCSU Invention Disclosure No. 15278, 2015.<\/li>\n
                              12. Gu, Z., X. Jiang, J. Kim*, and J. Di, \u201cSpatiotemporal Drug Delivery Using Laser-Generated-Focused Ultrasound System\u201d, NCSU Invention Disclosure No. 15293, 2015.<\/li>\n
                              13. Jiang, X.N., J. Kim*, J. Ma*, and X. Dai, \u201cSmall Aperture Hybrid Ultrasound Transducers and Arrays for Intravascular Thrombolysis\u201d, NCSU Invention Disclosure No. 15222, 2015.<\/li>\n
                              14. Jiang, X.N. and J. Ma*, \u201cMulti-Frequency Ultrasound Transducers and Arrays for Ultra-Broadband Ultrasound Imaging\u201d, NCSU Invention Disclosure No. 14187, 2014.<\/li>\n
                              15. Yan, X., F. Yuan, X.N. Jiang, and W. Huang*, \u201cCurvature Sensor based on Flexoelectricity\u201d, NCSU Invention Disclosure No. 13233, 2013.<\/li>\n
                              16. Jiang, X.N., X. Geng, and J. Ma*, \u201cMultifrequency Ultrasound Transducers\/Arrays Using Multi-layer Piezoelectric Structures\u201d, NCSU Invention Disclosure No. 13154, 2013.<\/li>\n
                              17. Jiang, X.N., S. Guo*, Y. Wang, and N. Allbritton, \u201cCell Release with Micropallets using Ultrasound\u201d, NCSU Invention Disclosure No. 12281, 2012.<\/li>\n
                              18. Jiang, X.N. and K. Kim*, \u201cA New Tactile Sensing Technique using Face-shear Piezoelectric Resonators\u201d, NCSU Invention Disclosure No. 12136, 2012.<\/li>\n
                              19. Dayton, P. and X.N. Jiang, \u201cTechnologies for Intravascular Ultrasound Transducers for Contrast Imaging\u201d, NCSU Invention Disclosure No. 12127, 2012.<\/li>\n<\/ol>\n<\/div>\n
                                \n

                                SERVICES<\/h3>\n

                                Professional service on campus:<\/h3>\n
                                  \n
                                • Member, MSE Distinguished Professor Nomination Committee, 2020<\/li>\n
                                • Member, BME Distinguished Professor Nomination Committee, 2019<\/li>\n
                                • Member, BME PTR committee (2018\/2019)<\/li>\n
                                • Member, MAE PTR committee (2018\/2019)<\/li>\n
                                • Member, MAE RPT committee (2018)<\/li>\n
                                • Chair, Advanced Manufacturing Faculty Search Committee (2017-2018)<\/li>\n
                                • Corporate advisory board member, MAE department, NC State, 2016-2017<\/li>\n
                                • Advisory Committee member, NC State Nanofabrication Facility, 2015-2017.<\/li>\n
                                • NC State University Standing Committee on Extension, Engagement and Economic Development: 2015- 2017.<\/li>\n
                                • Packard Foundation: Fellowship for Science and Engineering internal review panel, 2014.<\/li>\n
                                • Member, Departmental faculty recruiting committee (electromechanical), 2013.<\/li>\n
                                • Judge for MAE graduate poster competition, 2012, 2013.<\/li>\n
                                • NC State internal NSF MRI panel: 2010, 2011, 2012.<\/li>\n
                                • Member, Departmental faculty recruiting committee (acoustic\/vibro), 2011.<\/li>\n
                                • Member, Departmental Public Relationship Committee, 2010-2017.<\/li>\n<\/ul>\n<\/div>\n
                                  \n

                                  Professional service off campus:<\/h3>\n

                                  Invited Talks:<\/em><\/strong><\/span><\/p>\n

                                    \n
                                  • Invited Speaker at 2020 IEEE International Ultrasonics Symposium, Las Vegas, NV, Sept. 7-11, 2020. (Virtual)<\/li>\n
                                  • Invited Speaker at ACIST Medical Systems, April 6, 2020 (Virtual)<\/li>\n
                                  • Invited Speaker at Infraredx, Inc., March 26, 2020 (Virtual)<\/li>\n
                                  • Invited Speaker, 2020 Triangle Imaging Symposium, UNC Chapel Hill, March 11, 2020 (postponed).<\/li>\n
                                  • Invited Seminar Speaker at University of Toledo, Toledo, OH, September 27, 2019.<\/li>\n
                                  • Invited Speaker at 2019 International Symposium of Research and Application of Functional Oxide Electronic Ceramics, Shanghai, China, June 11-14, 2019.<\/li>\n
                                  • Keynote Speaker at CICC-11, Kunming, China, May 25-29, 2019.<\/li>\n
                                  • Distinguished Lecture at IIT Roorkee, India, April 26, 2019<\/li>\n
                                  • Invited Speaker at CICMPT 2019, Shanghai, China, April 16-19, 2019<\/li>\n
                                  • Keynote Speaker at IEEE NEMS 2019, Bangkok, Thailand, April 12-15, 2019<\/li>\n
                                  • Invited Speaker at Hefei University of Technology, Anhui, China, March 2019<\/li>\n
                                  • Invited Speaker at Shanghai Jiaotong University, Shanghai, China, Jan. 2019<\/li>\n
                                  • Invited Speaker at Chongqing Medical University, China, Dec. 2018<\/li>\n
                                  • Invited Speaker at University of Houston, Houston, TX, Nov. 2018.<\/li>\n
                                  • Invited Speaker at Penn State, Harrisburg, PA, Oct. 2018.<\/li>\n
                                  • Invited Speaker at IEEE NMDC 2018, Portland, Oregon, Oct. 2018.<\/li>\n
                                  • Invited Speaker at Suzhou Institute of Biomedical Engineering Technology, July 12, 2018.<\/li>\n
                                  • Invited Speaker at International Symposium in Precision Engineering, Hefei, China, July 9-11, 2018.<\/li>\n
                                  • Invited Speaker at Beijing Institute of Nanoenergy and Nanosystems (BINN), CAS, July 2, 2018.<\/li>\n
                                  • Invited Speaker at Johns Hopkins University, Baltimore, MD, December 6, 2017.<\/li>\n
                                  • Invited speaker at University of Dundee, Dundee, Scotland, July 18, 2017.<\/li>\n
                                  • Invited speaker at Imperial College London, London, UK, July 14. 2017.<\/li>\n
                                  • Invited speaker at University of Edinburgh, Edinburgh, Scotland, July 13. 2017.<\/li>\n
                                  • Invited speaker at University of Glasgow, Glasgow, Scotland, July 12. 2017<\/li>\n
                                  • Invited speaker at Beihang University, Beijing, China, June 2, 2017.<\/li>\n
                                  • \u201cNovel piezoelectric sensors, actuators and transducers: design, fabrication, characterization and applications\u201d, 2017 IEEE ISAF Tutorial Lecture, Atlanta, GA, May 7, 2017. (Invited)<\/li>\n
                                  • \u201cRelaxor-PT crystals with engineered domains\u201d, NSF Center for Dielectrics and Piezoelectrics (NCSU&PSU), 2017 Spring Meeting at Penn State, University Park, PA, April 26, 2017. (Invited)<\/li>\n
                                  • Invited speaker at BME program annual meeting, ShenZhen University, Shenzhen, China, Dec. 10, 2016.<\/li>\n
                                  • Invited speaker at Southern Medical University, Guangzhou, China, Dec. 5, 2016.<\/li>\n
                                  • Invited speaker at 973 annual review meeting of relaxor single crystals, Shenzhen, China, Dec. 3, 2016.<\/li>\n
                                  • Invited speaker at the City University of Hong Kong, Hong Kong, Nov. 30, 2016.<\/li>\n
                                  • Invited speaker at Shandong University, Jinan, China, Oct. 9, 2016.<\/li>\n
                                  • Invited speaker at The Hong Kong Polytechnic University, Hong Kong, Oct. 05, 2016.<\/li>\n
                                  • Invited speaker at Nanjing University, Nanjing, China, Sept. 29, 2016.<\/li>\n
                                  • Invited speaker at Suzhou Institute of Biomedical Engineering and Technology, Chinese Academy of Sciences, Suzhou, July 28, 2016.<\/li>\n
                                  • Invited speaker, Academic Seminar on Novel Medical Imaging Techniques, Shenzhen Institutes of Advanced Technology, Chinese Academy of Sciences, Shenzhen, China, July 25, 2016.<\/li>\n
                                  • Invited speaker at Huazhong University of Science and Technology, Wuhan, China, July 22, 2016.<\/li>\n
                                  • Invited speaker at Taiyuan University of Technology, Taiyuan, July 20, 2016.<\/li>\n
                                  • Invited speaker at North University of China, Taiyuan, China, July 19, 2016.<\/li>\n
                                  • Invited speaker at the Nonlinear Acoustics Workshop, Taiyuan, China, July 19-21, 2016.<\/li>\n
                                  • Invited speaker at the 13th Annual Ultrasonic Transducer Engineering Conference May 16-17, 2016, Los Angeles, CA.<\/li>\n
                                  • Plenary speaker at The 2015 Symposium on Piezoelectricity, Acoustic Waves, and Device Applications (SPAWDA 2015), Oct.20-Nov.2, 2015, Jinan, China.<\/li>\n
                                  • Invited speaker at Suzhou Institute of Biomedical Engineering and Technology (Sinica), Suzhou, China, Nov., 2015.<\/li>\n
                                  • Invited speaker at Shanghai Jiaotong University, Shanghai, China, Oct., 2015.<\/li>\n
                                  • Invited speaker at Peking University, Beijing, China, July, 2015.<\/li>\n
                                  • Invited speaker at Anhui University, Anhui, China, July, 2015.<\/li>\n
                                  • Invited speaker at International Congress on Ultrasonics, Metz, France, May 11-14, 2015.<\/li>\n
                                  • Keynote Presentation at SPIE Smart Structures\/NDE 2015: Structural Health Monitoring and Inspection of Advanced Materials, Aerospace, and Civil Infrastructure IX, San Diego, CA, March, 2015.<\/li>\n
                                  • Invited speaker at NCSU CCEE graduate seminar, Jan. 22, 2015.<\/li>\n
                                  • Invited speaker at PSU-NCSU NSF CDP Fall meeting, November 2-5, 2014.<\/li>\n
                                  • Graduate Seminar, University of Minnesota, October 1st, 2014.<\/li>\n
                                  • Invited speaker at University of Science and Technology of China, Hefei, China, July 15, 2014.<\/li>\n
                                  • Invited speaker at Southern Medical University, Guangzhou, China, July 8, 2014.<\/li>\n
                                  • Invited speaker at Xi\u2019an Jiaotong University, Xi\u2019an, China, July 4, 2014.<\/li>\n
                                  • Invited speaker at Tianjin University, China, July 1, 2014.<\/li>\n
                                  • Invited speaker at Design of Medical Device Conference, University of Minnesota, April 9, 2014.<\/li>\n
                                  • Invited speaker at seminar series for graduate students at Joint School of Nanoscience and Nanoengineering, UNC, Greensboro, Jan. 24, 2014.<\/li>\n
                                  • Invited speaker at Xi\u2019an Jiaotonmg University, Xi\u2019an, China, June 2013.<\/li>\n
                                  • Invited speaker at Suzhou Institute of Biomedical Engineering and Technology, Suzhou, China, June 2013.<\/li>\n
                                  • Invited speaker at 11th Annual Ultrasonic Transducer Engineering Conference, Los Angeles, CA, April 17-19, 2013.<\/li>\n
                                  • Invited speaker at NCSU Chapter of the MRS on February 2013.<\/li>\n
                                  • Invited speaker at Idaho National Lab, July 26, 2012.<\/li>\n
                                  • Invited speaker at NSF CMMI Grantee Conference, Boston, MA, July 11, 2012.<\/li>\n
                                  • Invited speaker at Smart Materials, Structures and Systems, Montecatini Terme, Italy, June 10-14, 2012.<\/li>\n
                                  • Invited speaker at Design of Medical Device Conference, University of Minnesota, April 8-11, 2012.<\/li>\n
                                  • Invited speaker at Penn State NSF Center for Dielectric Studies, Oct. 24-25, University Park, 2011.<\/li>\n
                                  • Invited speaker at Shanghai Jiaotong University, July 06, 2011.<\/li>\n
                                  • Invited speaker at Zhejiang University, July 04, 2011.<\/li>\n
                                  • Invited speaker at BRIC Center, UNC Chapel Hill, June 13, 2011.<\/li>\n
                                  • Invited speaker at Sandia National Lab, February 21, 2011.<\/li>\n
                                  • Invited speaker at seminar series for UNC\/NCSU BME graduate students, Chapel Hill, August 27, 2010.<\/li>\n
                                  • Invited speaker at UNC BRIC, June 24, 2010.<\/li>\n
                                  • Invited speaker at International Symposium on Ultrasound Imaging and Tissue Characterization, Washington, DC, May 2010.<\/li>\n
                                  • Invited Tutorial talk, \u201cPiezoelectric Composite Micromachined Ultrasonic Transducer: A New Ultrasound Transducer Technology\u201d, AIUM Annual Convention\u2014Tutorial Session, San Diego, March 24-27, 2010.<\/li>\n
                                  • Invited speaker at Wright-Patterson AFRL, Dayton, OH, September 2009.<\/li>\n
                                  • Invited speaker at NCSU MAE Seminar, Raleigh, NC, April 2009.<\/li>\n
                                  • Invited Tutorial talk, \u201cMicromachined High Frequency Ultrasound Transducers for Biomedical and NDE Imaging Applications\u201d, PSU ESM Seminar, January 21, 2009.<\/li>\n
                                  • Invited speaker at WVU ME Seminar, Morgan Town, WV, June 2008.<\/li>\n
                                  • Invited speaker at PSU Center of Excellence in Structural Health Monitoring Spring Meeting, University Park, PA, April 2008.<\/li>\n
                                  • Invited speaker at Annual Workshop, PSU International Center for Actuators and Transducers, University Park, PA, May 2007.<\/li>\n
                                  • Invited speaker at SUNY Albany Seminar, Albany, NY, July 2001.<\/li>\n
                                  • Invited speaker at Xerox, Palo Alto, CA, May 2001.<\/li>\n
                                  • Invited speaker at Standard MEMS Seminar, Long Island, NY, November 2000.<\/li>\n
                                  • Invited speaker at Naval Research Lab, Washington, DC, August 1999.<\/li>\n<\/ul>\n

                                    Proposal Reviews:<\/em><\/strong><\/span><\/p>\n<\/div>\n

                                      \n
                                    • NIH IGIS Study Section (06\/2020)<\/li>\n
                                    • NIH ZRG1 F02A-K Study Section (02\/2020)<\/li>\n
                                    • Europe Science Foundation panel (01\/2020)<\/li>\n
                                    • NIH IDT Study Section (10\/2019)<\/li>\n
                                    • NIH SBIB-Q Study Section (03\/2019, 07\/2019, 11\/2019, 03\/2020, 07\/2020)<\/li>\n
                                    • NIH SBIB-T Study Section (2011, 02\/2012, 06\/2012, 10\/2012, 02\/2013, 10\/2013, 02\/2014, 06\/2014, 10\/2014, 02\/2015, 06\/2015, 11\/2015, 03\/2016, 06\/2016, 11\/2016, 03\/2017, 06\/2017, 03\/2018, 06\/2018, 03\/2019)<\/li>\n
                                    • Canada CFI proposal review (2017)<\/li>\n
                                    • NASA Early Career Proposal panel (2016)<\/li>\n
                                    • European Research Council proposal review (2015)<\/li>\n
                                    • NIH SBIB-T Study Section (2011, 02\/2012, 06\/2012, 10\/2012, 02\/2013, 10\/2013, 02\/2014, 06\/2014, 10\/2014, 02\/2015, 06\/2015, 11\/2015, 03\/2016, 06\/2016, 11\/2016, 03\/2017, 06\/2017, 03\/2018, 06\/2018, 03\/2019)<\/li>\n
                                    • NSF proposal review: NSF MRI Panel (2011), DMR electronic proposal review (2011), CMMI (2015)<\/li>\n
                                    • Reviewer of Focused Ultrasound Foundation’s Research Awards Program (2014, 2015)<\/li>\n
                                    • Proposal reviewer of DOE NEUP program (2013, 2014, 2016, 2017, 2018)<\/li>\n
                                    • Proposal reviewer of DOE SBIR\/STTR program (2013, 2014, 2016, 2018)<\/li>\n
                                    • Reviewer of Shanghai Jiaotong University Principal Investigator Program (2013)<\/li>\n
                                    • Proposal reviewer of South Carolina NASA Space Grant REAP program (2013)<\/li>\n
                                    • NSERC proposal review (Canada) (2011)<\/li>\n
                                    • NIH NIBIB RC2 Panel (2009)<\/li>\n
                                    • NIH Disparity Panel (2009)<\/li>\n<\/ul>\n

                                      Conference Services:<\/em><\/span><\/strong><\/p>\n

                                        \n
                                      • <\/li>\n
                                      • IEEE NMDC, Member of Technical Program Committee, Chair of Award Committee, 2018.<\/li>\n
                                      • IEEE NANO, Member of Technical Program Committee, \u00a0NanoAcoustics Session Chair (2017, 2018, 2019)<\/li>\n
                                      • IEEE Ultrasonics Symposium: Member of Technical Program Committee (Publicity Co-Chair and Student Event Co-Chair, 2019; TPC-5, 2014- present), Session Chair (2015-present ), Student paper competition judge (2015)<\/li>\n
                                      • SPIE Smart Materials and Structures and NDE: Member of Program Committee of Health Monitoring of Structural and Biological Systems VII (2013-present ), Member of Program Committee of Nondestructive Characterization for Composite Materials, Aerospace Engineering, Civil Infrastructure, and\u00a0 Homeland Security III (2009 – present ), Session Chair (2008-present )<\/li>\n
                                      • ASME IMECE: Member of Program Committee (Track-3, 2014- present), Session chair (2011- present), Student paper competition Chair (2014-2016, 2019 )<\/li>\n
                                      • Symposium on Piezoelectricity, Acoustic Waves, and Device Applications (SPAWDA): Session chair (2015)<\/li>\n
                                      • IEEE Sensors: Member of Program Committee (2007, 2008, 2009), Session Chair, IEEE Sensors (2008)<\/li>\n
                                      • Member of Program Committee of International Berkeley MEMS Conference (2000)<\/li>\n<\/ul>\n

                                        Editorial Services and Paper Reviews:<\/em><\/span><\/strong><\/p>\n

                                          \n
                                        • \n
                                            \n
                                          • Co-Editor-in-Chief, IEEE Nanotechnology Magazine (2020-)<\/li>\n
                                          • Associate Editor\/Guest Editor, IEEE Nanotechnology Magazine (2018-2019) (Special Issue on Nano-Acoustics\u20144 papers, 2019)<\/li>\n
                                          • Senior Associate Editor, The ASME Journal of Engineering and Science in Medical Diagnostics and Therapy (JESMDT), 2017-present<\/li>\n
                                          • Editorial board member: Sensors, 2015-present<\/li>\n
                                          • Guest Editor, Sensors, Special Issue on Ultrasound Transducers, 2018-2019. (30 papers)<\/li>\n
                                          • Guest Editor, Sensors, Special Issue on Acoustic Sensing and Ultrasonic Drug Delivery, 2016-2017. (18 papers)<\/li>\n
                                          • Guest Editor, Sensors, Special Issue on Ultrasonic Sensors and Transducers for Applications in Biology, Medicine and NDT, 2013-2014. (29 papers)<\/li>\n
                                          • Guest Editor, Smart Materials Research, Special Issue on Electroactive Functional Materials for Actuation, Sensing and Energy Harvesting, 2012-2013.<\/li>\n
                                          • Book chapter reviewer for book titled \u201cHigh Temperature Materials and Mechanisms\u201d, Edited by Yoseph Bar-Cohen, CRC Press, 2013.<\/li>\n
                                          • Reviewed Journals:<\/li>\n<\/ul>\n

                                            ACS Applied Materials & Interfaces; Acta Biomaterialia; Acta Materiala; Advanced Electronic Materials; Advanced Optical Materials; Advances in Acoustics and Vibration; AIP Advance; Applied Energy; Applied Mathematical Modelling; Applied Physics A; Applied Physics Letters; ASME Journal of Engineering and Science in Medical Diagnostics and Therapy; ASME Journal of Micro and NanoManufacturing; Biomicrofluidics; Biotechnology and Bioengineering; Ceramics International; Composites Part B: Engineering; IEEE Access; IEEE Sensors; IEEE Transactions on Biomedical Engineering; IEEE Transactions on Electron Devices; IEEE Transactions on Industrial Electronics; IEEE Transactions on Medical Imaging; IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control; Journal of Acoustic Society of America; Journal of Advanced Dielectrics; Journal of Alloys and Compounds; Journal of Applied and Computational Mechanics; Journal of Applied Physics; Journal of Electronic Materials; Journal of Engineering; Journal of Engineering Manufacture; Journal of Intelligent Material Systems and Structures ; Journal of Materials Chemistry C; Journal of Micromechanics and Microengineering; Journal of Physics D: Applied Physics; Journal of Sound and Vibration; Journal of the American Ceramic Society; Lab on Chip; Materials and Design; Material Letters; Measurement; Mechanics of Materials; Mechatronics; Microelectronic Engineering; Microelectronics; Micromachine; Nano Energy; Nanoscale; Nature Electronics; Nature Communications; Optics Communications; Royal Society Open Science; Science Advances; Scientific Reports; Sensors; Sensors and Actuators: A Physical; Smart Materials and Structures; Solid State Communications; Theranostics; Ultrasonics<\/li>\n

                                          • Conference paper reviews:
                                            \nIEEE IUS (2014, 2015, 2016, 2017, 2018, 2019, 2020); IEEE Nano (2017, 2018, 2019, 2020); IEEE NMDC (2018); ASME IMECE (2006, 2011, 2012, 2013, 2014, 2015, 2016, 2017, 2018, 2019, 2020); IEEE Sensors (2007, 2008, 2009); International Berkeley MEMS Conference (2000)<\/li>\n<\/ul>\n

                                            Other Services:<\/em><\/span><\/strong><\/p>\n

                                              \n
                                            • PhD Thesis external examiner, Hong Kong Polytechnic University, 2017.<\/li>\n
                                            • NanoAcoustics Technical Committee Chair, IEEE NTC (2016-)<\/li>\n
                                            • PhD Thesis external examiner, University of Waterloo, Canada, 2016.<\/li>\n
                                            • IEEE UFFC Education Committee, 2015-2017<\/li>\n
                                            • PhD Thesis external examiner, Auckland University of Technology, New Zealand, 2014, 2017, 2018<\/li>\n
                                            • IEEE UFFC Representative to IEEE Nanotechnology Council, 2014-2018<\/li>\n<\/ul>\n","protected":false},"excerpt":{"rendered":"

                                              Xiaoning Jiang, Ph.D. Dean F. Duncan Distinguished Professor, Department of Mechanical and Aerospace Engineering Adjunct Professor, UNC-Chapel Hill & NC State Joint Department of Biomedical…<\/p>\n","protected":false},"author":138,"featured_media":0,"parent":26,"menu_order":2,"comment_status":"closed","ping_status":"closed","template":"","meta":{"_acf_changed":false,"footnotes":""},"class_list":["post-426","page","type-page","status-publish","hentry"],"acf":[],"yoast_head":"\nXiaoning's CV - Dr. Xiaoning Jiang Research Group<\/title>\n<meta name=\"robots\" content=\"index, follow, max-snippet:-1, max-image-preview:large, max-video-preview:-1\" \/>\n<link rel=\"canonical\" href=\"https:\/\/mae.ncsu.edu\/jiang\/members\/xiaonings-cv\/\" \/>\n<meta property=\"og:locale\" content=\"en_US\" \/>\n<meta property=\"og:type\" content=\"article\" \/>\n<meta property=\"og:title\" content=\"Xiaoning's CV - Dr. Xiaoning Jiang Research Group\" \/>\n<meta property=\"og:description\" content=\"Xiaoning Jiang, Ph.D. Dean F. 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