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Enhanced elastomer-like auxetic cementitious materials through strain-hardening cementitious composites (SHCC) with extended softening properties

Jinbao Xie, Shan He, Yading Xu, Zhaozheng Meng, Wen Zhou, Erik Schlangen, Branko Šavija

2025Cement and Concrete Composites15 citationsDOIOpen Access PDF

Abstract

Auxetic cementitious cellular composites (ACCCs) exhibit hinge-type recoverable deformation during auxetic behavior phase, a rare pseudo-elastic property in cementitious materials. However, their low load-bearing capacity during this phase restricts their use in high-load applications. This study developed ACCCs using strain-hardening cementitious composites (SHCCs) with short (SHCC-SS) and long (SHCC-LS) softening tails, fabricated by additive manufacturing-assisted casting. Uniaxial compression tests employing Digital Image Correlation (DIC) evaluated their compressive behavior, peak strength, Poisson's ratio variation, and energy dissipation. Cyclic tests after pre-compression assessed their recoverable deformation resilience, with fiber bridging at joint cracks examined using digital optical microscope. Results were compared to a reference using fiber-reinforced cementitious materials with strain softening (SS). Compared to the reference (SS), ACCCs using SHCC mixtures exhibit superior load-bearing capacity and stable auxetic behavior under compression. After self-contact, they maintain a negative Poisson's ratio up to a considerably high compressive strain, preventing splitting failure and preserving structural integrity. This is because incorporating SHCC enables greater joint rotation by promoting multiple cracks with strain hardening, which delays primary crack formation and reduces its opening. During cyclic tests, P1-shaped ACCCs with SHCC-LS and SHCC-SS enhance the elasticity modulus of recoverable deformation by 4.8 and 3.0 times, respectively, compared to SS. SHCC-LS outperforms SHCC-SS in compressive resilience due to its prolonged softening tail, which improves fiber bridging in primary cracks and increases rotational stiffness in hinge joints. SHCC mixtures with initial strain hardening and extended softening enable scalable design of advanced auxetic cementitious materials across various load levels. • ACCCs made from SHCC mixtures were fabricated using additive manufacturing assisted casting. • ACCCs with SHCC exhibit enhanced load-bearing capacity under uniaxial compression. • ACCCs with SHCC improve compressive deformation resilience under cyclic loading. • ACCCs with short and long softening SHCC were compared.

Topics & Concepts

Materials scienceComposite materialElastomerStrain hardening exponentSofteningCementitiousAuxeticsHardening (computing)CementLayer (electronics)Innovations in Concrete and Construction MaterialsBone Tissue Engineering MaterialsCellular and Composite Structures