Yoshikazu Araki 
- (2022): Low-cycle fatigue behavior of Cu–Al–Mn superelastic alloys at different temperatures. In: Smart Materials and Structures, v. 31, n. 11 (September 2022).
- (2022): Long-term corrosion resistance of Cu-Al-Mn superelastic alloys and steel rebar for use in bridges. In: Construction and Building Materials, v. 350 (October 2022).
- (2021): Feasibility of Roll-Threading Superelastic Cu-Al-Mn SMA Rods. In: Journal of Materials in Civil Engineering (ASCE), v. 33, n. 9 (September 2021).
- (2021): Rubble Stone Masonry Buildings with Cement Mortar: Base Shear Seismic Demand Comparison for Selected Countries Worldwide. In: Frontiers in Built Environment, v. 7 (January 2021).
- (2021): Orientation Dependence of Plasticity and Fracture in Single-Crystal Superelastic Cu-Al-Mn SMA Bars. In: Journal of Materials in Civil Engineering (ASCE), v. 33, n. 4 (April 2021).
- (2011): Response of vibration-isolated object to ground motions with intense vertical accelerations. In: Engineering Structures, v. 33, n. 12 (December 2011).
- (2020): Rubble Stone Masonry Buildings With Cement Mortar: Design Specifications in Seismic and Masonry Codes Worldwide. In: Frontiers in Built Environment, v. 6 (January 2020).
- (2021): Chemical Resistance of Cu-Al-Mn Superelastic Alloy Bars in Acidic and Alkaline Environments. In: Journal of Materials in Civil Engineering (ASCE), v. 33, n. 1 (January 2021).
- (2019): School Buildings in Rubble Stone Masonry With Cement Mortar in Seismic Areas: Literature Review of Seismic Codes, Technical Norms and Practical Manuals. In: Frontiers in Built Environment, v. 5 (November 2019).
- (2019): Cost Analysis of Mountain Schools in Nepal: Comparison of Earthquake Resistant Features in Rubble Stone Masonry vs. Concrete Block Masonry. In: Frontiers in Built Environment, v. 5 (November 2019).
- (2013): Pinning retrofit technique in masonry with application of polymer-cement pastes as bonding agents. In: Earthquakes and Structures, v. 5, n. 4 (October 2013).
- (2011): Applicability of Cu-Al-Mn shape memory alloy bars to retrofitting of historical masonry constructions. In: Earthquakes and Structures, v. 2, n. 3 (September 2011).
- (2019): Reaction, Phases, and Microstructure of Fly Ash-Based Alkali-Activated Materials. In: Journal of Advanced Concrete Technology, v. 17, n. 3 (March 2019).
- (2016): Functional Fatigue of Polycrystalline Cu-Al-Mn Superelastic Alloy Bars under Cyclic Tension. In: Journal of Materials in Civil Engineering (ASCE), v. 28, n. 5 (May 2016).
- (2016): Use of shape-memory alloys in construction: a critical review. In: Proceedings of the Institution of Civil Engineers - Civil Engineering, v. 169, n. 2 (May 2016).
- (2018): Structural control with tuned inertial mass electromagnetic transducers. In: Structural Control and Health Monitoring, v. 25, n. 2 (February 2018).
- (2014): Feasibility of tension braces using Cu-Al-Mn superelastic alloy bars. In: Structural Control and Health Monitoring, v. 21, n. 10 (October 2014).
- (2014): Loading rate and temperature dependency of superelastic Cu–Al–Mn alloys. In: Construction and Building Materials, v. 53 (February 2014).
- (2017): Adjustable vertical vibration isolator with a variable ellipse curve mechanism. In: Earthquake Engineering and Structural Dynamics, v. 46, n. 8 (10 July 2017).
- (2016): Shaking table tests of steel frame with superelastic Cu-Al-Mn SMA tension braces. In: Earthquake Engineering and Structural Dynamics, v. 45, n. 2 (February 2016).
- (2013): Effectiveness of superelastic bars for seismic rehabilitation of clay-unit masonry walls. In: Earthquake Engineering and Structural Dynamics, v. 42, n. 5 (25 April 2013).
- (2009): Vertical vibration isolator having piecewise-constant restoring force. In: Earthquake Engineering and Structural Dynamics, v. 38, n. 13 (25 October 2009).
- (2018): Enhancing the seismic performance of historic timber buildings in Asia by applying super-elastic alloy to a Chinese complex bracket system. In: International Journal of Architectural Heritage, v. 12, n. 4 (March 2018).
- (2013): Feasibility of Cu–Al–Mn superelastic alloy bars as reinforcement elements in concrete beams. In: Smart Materials and Structures, v. 22, n. 2 (February 2013).
- (2012): Rate-dependent response of superelastic Cu–Al–Mn alloy rods to tensile cyclic loads. In: Smart Materials and Structures, v. 21, n. 3 (March 2012).
- (2014): Feasibility of externally activated self-repairing concrete with epoxy injection network and Cu-Al-Mn superelastic alloy reinforcing bars. In: Smart Materials and Structures, v. 23, n. 10 (October 2014).
- (2017): Consistent DOF reduction of tall steel frames. In: Earthquake Engineering and Structural Dynamics, v. 46, n. 10 (August 2017).
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