Zermatt, Switzerland, 2011

Prof. Huang Hsing PAN

  • E-mail: pam [at] nkust.edu.tw
  • Phone: 07-3814526 ext. 15231
    		•

    Education

  		•  Ph. D. Rutgers University

    Contact

  		•  Office +886 7 3814526 ext.15231
  		• MTS Experimental Mechanics Lab. +886 7 3814526 ext.15292
  		• Advanced Materials and Technology Development Lab. +886 7 3814526 ext.15285
  		• Address Department of Civil Engineering
    National Kaohsiung University of Science and Technology
    415 Chien-Kung Road
    Kaohsiung 80778
    TAIWAN
  		• E-mail pam@nkust.edu.tw

    Research Interests

  		•  Structural Health Monitoring
  		• Cement-Based Piezoelectric Composites and Piezoelectric Sensors
  		• Ultra High Performance Concrete (UHPC)
  		• Micromechanics of Cement-Matrix Composites
  		• Construction Risk Assessment and Safety Management

    Publications

    [72]. Rebar Corrosion Monitoring in Concrete Using Piezoelectric Cement Sensors. (DOI:10.1007/9783031533891_100)(2024)
    [71]. Effect of Epoxy Resin and Barium Zirconate Titanate Contents on Piezoelectric Properties of 0-3 Barium Zirconate Titanate-Portland Cement Composite with Epoxy Resin Addition. (2023)
    [70]. Piezoelectric Cement Sensor-Based Electromechanical Impedance Technique for the Chloride Ion Content Monitoring of Hardened Concrete. (2023)
    [69]. Effect of Water to Cement Ratio on Acoustic Impedance, Microstructure, and Piezoelectric Properties of 0-3 Barium Zirconate Titanate-Portland Cement Composite with Epoxy Resin Addition. (2023)
    [68]. Effect of Graphene on Piezoelectric Properties of Cement-Based Piezoelectric Composites. (2022)
    [67]. Stress and Strain Behavior Monitoring of Concrete Through Electromechanical Impedance Using Piezoelectric Cement Sensor and PZT Sensor. (2022)
    [66]. Rudder Profiles of Power-Free Underwater Vehicle for Kuroshio Power Generation. (2020)
    [65]. Piezoelectric Properties of Cement Piezoelectric Composites Containing Nano-Quartz Powders. (2020)
    [64]. Piezoelectric Cement Sensor-Based Electromechanical Impedance Technique for the Strength Monitoring of Cement Mortar. (2020)
    [63]. Influence of Water-to-Cement Ratio on Piezoelectric Properties of Cement-Based Composites Containing PZT Particles. (2020)
    [62]. A Case Study of Urban Road Subsidence Induced By the Underground Connection of the Shield Tunneling Method. (2019)
    [61]. Monitoring of the Strength of Mortar and Concrete Using Piezoelectric Cement Sensors via Electromechanical Impedance Technique.
    (使用壓電水泥與機電阻抗技術監測砂漿和混凝土強度)    		(2019)
    [60]. Performance Evaluation of a Rocking Steel Column Base Equipped With Asymmetrical Resistance Friction Damper. (2019)
    [59]. Piezoelectric Cement Sensor and Impedance Analysis for Concrete Health Monitoring. (2019)
    [58]. The Evaluation of Skid Resistance with Various Film Thickness of Moisture in Dense-Graded Asphalt Mixture. (2018)
    [57]. Strength Analysis for the Rudder of Power-Free Underwater Vehicle in Kuroshio Subjected to Typhoon Waves. (2017)
    [56]. Curing Time and Heating Conditions for Piezoelectric Properties of Cement-Based Composites Containing PZT. (2016)
    [55]. High Piezoelectric and Dielectric Properties of 0-3 PZT/Cement Composites by Temperature Treatment. (2016)
    [54]. The Nondestructive Evaluation of High-Temperature Conditioned Concrete in conjunction with Acoustic Emission and X-ray Computed Tomography. (2016)
    [53]. Causes of Explosion in Section C of the Diversion Tunnel Under Construction at Zengwen Reservoir. (2016)
    [52]. High Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Kaolin. (2015)
    [51]. Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Fly Ash. (2014)
    [50]. Effect of Aged Binder on Piezoelectric Properties of Cement-Based Piezoelectric Composites. (2014)
    [49]. Age Effect on Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Slag. (2013)
    [48]. Attack Angle and Strength of Rudders for Power-Free Underwater Vehicle in Kuroshio. (2013)
    [47]. New Waterwheel Blades for Power Generation in Kuroshio. (2013)
    [46]. Influence of Pozzolanic Materials on 0-3 Cement-Based Piezoelectric Composites. (2013)
    [45]. Rudder Controlling of Underwater Vehicle Using in Kuroshio. (2012)
    [44]. Effect of Pozzolanic Materials and Poling Field on Electromechanical Coupling Coefficient of Cement-Based Piezoelectric Composites. (2012)
    [43]. Investigation on the Age-Dependent Constitutive Relations of Mortar. (2012)
    [42]. Properties of Coconut Fiber/Rubber Cement Board for Building Partitions. (2011)
    [41]. Mechanical Properties of Steel Fiber Reinforced Reactive Powder Concrete Following Exposure to High Temperature Reaching 800 oC. (2011)
    [40]. Static-Dynamic Properties of Reactive Powder Concrete with Blast Furnace Slag. (2011)
    [39]. Comparison of Various Electrode Instrumentations for Electrical Measurement of Cement-Based Materials. (2011)
    [38]. Determination of Interfacial Transition Zone in Cementitious Materials by Dynamic Displacement. (2011)
    [37]. Manufacturing and Polarization Process of 0-3 Cement-Based PZT Composites.
    (0-3型PZT水泥基壓電複合材料製程與極化行為)     		(2011)
    [36]. Composite Approach to High Strain-Rate Stress-Strain Curve of Reactive Powder Concrete. [Proceedings of the 4th ACF International Conference] (2010)
    [35]. Desulfurization Slag/Granulated Blast Furnace Slag Binder and Mortar without Portland Cement. (2010)
    [34]. Electrical Resistivity Measurement of Cement-Based Binders Using Embedded Four-Terminal Probe Method. (2010)
    [33]. ESPI Measurement to Determine Interfacial Transition Zone in Cementitious Materials under Temperatures. (2010)
    [32]. Study on the Strain-Rate Sensitivity of Cementitious Composites. (2010)
    [31]. Effect of Temperature to Micro-Displacement of Interfacial Transition Zone in Cementitious Materials by ESPI Measurement. (2010)
    [30]. Residual Strength and Deformation of Steel Fiber Reinforced Reactive Powder Concrete After Elevated Temperature.
    (高溫作用後鋼纖維活性粉混凝土殘留強度與變形性能)     		(2010)
    [29]. Properties of natural fiber cement boards for building partitions. (2009)
    [28]. Effect of Micro and Nano-Cracks for the Mechanical Properties of Cementitious Materials. (2009)
    [27]. Micromechanics-Based Predictions on the Overall Stress-Strain Relations of Cement-Matrix Composites. (2008)
    [26]. Composite-Based Approach for Strain-Rate Sensitivity of Stress-Strain Curves of Cement-Matrix Composites. [The 3rd ACF International Conference-ACF/VCA 2008](2008)
    [25]. The Accelerated Method for Estimating Corrosion of Reinforced Concrete Structure in Seawater. (2008)
    [24]. Evaluation and Analysis of Replacement Materials for Cast Iron Ditch Covers of Rainwater Sewer System.
    (雨水下水道鑄鐵清掃孔蓋替代材料分析與評估)     		(2008)
    [23]. Determination of Representative Crack Density of Cementitious Materials. (2007)
    [22]. Micromechanics Approach for Long-Term Stress-Strain Relationships of Cement-Matrix Composites. (2006)
    [21]. Solid-Particle Abrasion of Hydraulic Concrete. (2006)
    [20]. Effect of Nano-Silica Powder on the Durability Properties of High Performance Concrete. (2005)
    [19]. Zirconia Strengthened High Performance Concrete. (2005)
    [18]. Long-Term Stress-Strain Relations of the Cement-Matrix Composite. (2004)
    [17]. Stress-Strain Relationship of Damaged Solids Containing Elliptic Cracks. (2003)
    [16]. Influence of the Constituents on the Elastic Moduli and the Strength of Concrete. (2003)
    [15]. Transformation Toughening of a Two-Phase, Transversely Isotropic Solid. (2003)
    [14]. Effective Toughness of Damaged Solids Containing Ribbon Cracks. (2002)
    [13]. A Micromechanical Theory for the Determination of the Stress-Strain Relation of Cement-Matrix Composites. (2002)
    [12]. A Micromechanics Theory for the Transformation Toughening of Two-Phase Ceramics. (2002)
    [11]. The Toughness and Elastic Moduli of Rigid-Reinforced Composites. (2001)
    [10]. Residual Stress on Toughening with Spherical Inclusions Accompanying Phase Transformation. (2000)
    [9]. A Theory for Elastic Potential Energy Change and Applied Stresses Accompanying Phase Transformation. (2000)
    [8]. The Influence of Material Temperature on the Workability and the Strength of High Performance Concrete.
    (材料溫度對高性能混凝土工作性及抗壓強度之影響)     		(2000)
    [7]. An Overall Approach for Microcrack and Inhomogeneity Toughening in Brittle Solids. (1999)
    [6]. On the Application of Willis' Bounds Involving Ellipsoidal Inclusions. (1998)
    [5]. Elastic Moduli of Heterogeneous Solids with Ellipsoidal Inclusions and Elliptic Cracks. (1995)
    [4]. Thermal Stress Relief by Plastic Deformation in Aligned Two-Phase Composites. (1993)
    [3]. Determination of Transient and Steady-State Creep of Metal-Matrix Composites by a Secant-Moduli Method. (1993)
    [2]. Effect of Crack Shape on the Properties of Isotropic and Brittle Materials.
    (裂縫形狀對等向性脆性材料性質的影響)     		(1993)
    [1]. Thermal Stress and Volume Change During a Cooling Process Involving Phase Transformation. (1992)

    Designed by James 。 Last Update: 10:38 Jul 09, 2013