Creep and relaxation of cement paste caused by stress‐induced dissolution of hydrated solid components

Li, Xiaodan; Grasley, Zachary; Bullard, Jeffrey W.; Pan, Feng

doi:10.1111/jace.15587

Cited by 19 publications

(9 citation statements)

References 69 publications

(127 reference statements)

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“…However, the fact that the equivalent systems where the hydration-related dissolution is not active still show nonnegligible creep (the same holds for the creep response of the very old, fully hydrated systems) cannot be explained with the hydration-induced dissolution theory and hence confirms that at least part of the measured creep is due to the intrinsic viscoelastic properties of the cement-paste, which is also in line with findings of indentation studies [4,5,22]. Another hypothesis that could explain at least part of the creep visible in the equivalent systems and real systems at later ages stems from the stress-induced dissolution of hydrates, as postulated in [8,50,51].…”

Section: Interpretation Of the Results Of The Equivalent Systemssupporting

confidence: 79%

“…This means that the average stress on the hydrates increases along with hydration as load is redistributed to them from the elastic unhydrated phase that dissolves. This constitutes a major difference compared to the solidification theory of creep [10], where stress carried by the hydrates decreases with Grasley et al [50] proposed based on theoretical considerations that the stress-induced dissolution of hydrated phases could further contribute to the apparent creep in hydrated systems; this approach was also supported by the simuations by Li et al [51] . Also, Pignatelli et al [8], based on some experimental evidence argued that dissolution of C-S-H due to applied stress could contribute to creep.…”

Section: Dissolution Theorymentioning

confidence: 99%

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Basic creep of cement paste at early age - the role of cement hydration

Wyrzykowski

Scrivener

Lura

2019

Cement and Concrete Research

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In this work, the uniaxial creep in compression during the first days of hydration is studied experimentally on cement pastes with w/c of 0.50. In order to assess the effect of the evolving microstructure on creep, the so-called equivalent systems are employed. In these systems, part of the otherwise unhydrated cement is replaced with inert filler (quartz powder). With this approach, non-aging systems are obtained that can emulate specific microstructural features of the real hydrating systems. Despite the very similar elastic Young's moduli of the real and their corresponding equivalent systems, the real hydrating systems experienced much higher creep in the first weeks after loading than the equivalent, inert systems. The differences in creep could be explained either by possibly different morphologies of the hydrates in the two types of systems, intrinsic aging or with the active role of the hydration process in increasing creep (dissolution theory of creep).

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Section: Interpretation Of the Results Of The Equivalent Systemssupporting

confidence: 79%

Section: Dissolution Theorymentioning

confidence: 99%

Basic creep of cement paste at early age - the role of cement hydration

Wyrzykowski

Scrivener

Lura

2019

Cement and Concrete Research

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“…Microstructural models have been widely used to study the development of the mechanical properties of hydrating cement pastes, mortars, or concrete. While most of the work has been limited to modelling of the paste as a linear elastic solid [8,52,53], some work on the non-linear behavior, brittle fracture [54][55][56][57], and viscoelastic/viscoplastic properties of the paste [58][59][60][61][62] is also available. Two main approaches, analytical and numerical, have been used to homogenise the properties of cement paste for these purposes.…”

Section: Mechanical Propertiesmentioning

confidence: 99%

Microstructure models of cement: their importance, utility, and current limitations

Bishnoi

Bullard

2022

RILEM Tech Lett

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Microstructure models seek to explain or predict various material properties in terms of the structure or chemical composition at scales of several hundred nanometres to several hundred micrometres. Such models therefore bridge the scaling gap between atomistic models and continuum methods, and consequently can help establish and validate scaling relations across those scales. Microstructure models have been applied to cementitious materials for at least four decades to help understand setting, strength development, rheological properties, mechanical behavior, and transport properties. This letter describes the current state of cement microstructure modelling in several areas that are important for engineering. It is not meant to be an exhaustive review, instead highlighting the kinds of models that can now be applied to different aspects of cement binder behaviour. Special attention is paid to challenges or limitations of each kind of model. This is done to promote the judicious use and interpretation of models and especially to indicate where future research could make inroads on problems that are currently inaccessible to microstructure models.

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“…There are several mechanisms that have been proposed to explain creep in C-S-H. The most common is the sliding of the aforementioned sheets with respect to each other under sustained stress (Ulm et al 1999;Alizadeh et al 2010;Tamtsia and Beaudoin 2000;Thomas 1937;Lynam 1934;Jennings 2004;Acker 2004;Vandamme and Ulm 2009a), but other mechanisms, such as dissolution under stress (Li et al 2018;Moradian et al 2018;Pignatelli et al 2016) or a change of site of a particular bond between Ca ions bridging oxygen atoms in silicate groups due to stress or thermal activation (Gartner et al 2017), have also been discussed in the literature. Additionally, creep and stress relaxation are not independent of one another and the combined viscoelastic response is termed 'creeprelaxation'.…”

Section: Creepmentioning

confidence: 99%

MOSAIC: An Effective FFT-based Numerical Method to Assess Aging Properties of Concrete

Torrence

Giorl

et al. 2021

ACT

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As the nuclear fleet in the United States ages and subsequent license renewal applications grow, the prediction of concrete durability at extended operation becomes more important. To address this issue, a Fast-Fourier Transform (FFT) method is utilized to simulate aging-related degradation of concrete within the Microstructure Oriented Scientific Analysis of Irradiated Concrete (MOSAIC) software. MOSAIC utilizes compositional phase maps to simulate damage from radiation-induced volumetric expansion (RIVE), applied force, creep, and thermal expansion. This compositional detail allows each mineral in the microstructure to be assigned specific material properties, allowing the simulation to be as accurate and representative as possible. The principal goal of MOSAIC is to simulate the effects of nonlinear aging mechanisms occurring in nuclear concrete on the macroscopic mechanical properties, using only the aggregate microstructure compositional information as a starting point. Several realistic example simulations are shown to demonstrate the utility and uniqueness of the MOSAIC software.

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Creep and relaxation of cement paste caused by stress‐induced dissolution of hydrated solid components

Cited by 19 publications

References 69 publications

Basic creep of cement paste at early age - the role of cement hydration

Basic creep of cement paste at early age - the role of cement hydration

Microstructure models of cement: their importance, utility, and current limitations

MOSAIC: An Effective FFT-based Numerical Method to Assess Aging Properties of Concrete

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