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Micro- and nanostructural investigations of high and ultra-high performance concrete under fatigue

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  • NETL
  • NSTL
  • Elsevier
A fine-grained UHPC, both undamaged and damaged by fatigue loading, was comparatively examined by various microstructural analytical methods, to evaluate the different techniques with respect to their applicability and relevance for the investigation of fatigue damage processes. The fatigue tests were stopped at the transition from phase Ⅱ to phase Ⅲ of the s-shaped strain development. The cyclic compression loading was performed with a frequency f_t = 1 Hz, and a stress level between S_(min) = 0.05 and S_(max) = 0.75 (f(cm) = 170.2 MPa). The fatigue process under these loading conditions is dominated by alterations and damages on the nano-scale, that can be observed by transmission electron microscopy. The resulting coarsening of the pore structure was also visible with dynamic vapor sorption. Nanoindentation indicates, that changes of the HD-C-S-H-phase occur. IR spec-troscopy also indicates changes of the C-S-H phase and thermal analysis changes of the water content. Dynamic mechanical analysis (DMA) gave insight into the complex Young's modulus and Poisson's ratio changes. The acoustic emission technique gives information on the different processes during the single phases of fatigue and reveal a very different damage behaviour of dry and moist materials. Some microcracks are visible with light microscopy. It appears, that the number of cracks after fatigue is higher than before. With X-ray computed tomography, X-ray powder diffraction, the drying behaviour, the free water uptake, the water uptake under vacuum and by mercury intrusion porosimetry no significant differences between specimens with and without fatigue loading could be observed in this examination.

FatigueHPCUHPCMicrostructureTesting Methods

Michael Engelhardt、Andreas Kalytta-Mewes、Dirk Volkmer、Jessica Lohmann、Martin Ritter、Gunnar Schaan、Frank Schmidt-Doehl、Mohamed Abubakar Ali、Marco Basaldella、Michael Haist、Bianca Kern、Ludger Lohaus、Nadja Oneschkow、Corinna Rozanski、Tim Timmermann、Christian U. Grosse、Veit Birtel、Harald Garrecht、Hamid Madadi、Martin Markert、Holger Steeb

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University of Augsburg, Universiiatsstrufie 2, 86159 Augsburg, Germany

Hamburg University of Technology, Am Schwarzenberg-Campus 1, 21073 Hamburg, Germany

Leibniz University Hannover, Welfengarten 1, 30167 Hannover, Germany

Technical University of Munich, Arcisstrasse 21, 80333 Munich, Germany

University of Stuttgart, Keplerstrasse 7, 70174 Stuttgart, Germany

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2025

10.1016/j.ijfatigue.2025.109038

International journal of fatigue

International journal of fatigue

SCI
ISSN:0142-1123
年,卷(期):2025.199(Oct.)
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