research papers
Mix and measure II: joint high-energy laboratory powder diffraction and microtomography for cement hydration studies
aDepartamento de Química Inorgánica, Cristalografía y Mineralogía, Universidad de Málaga, 29071 Málaga, Spain, and bServicios Centrales de Apoyo a la Investigación, Universidad de Málaga, 29071 Málaga, Spain
*Correspondence e-mail: g_aranda@uma.es
This article is part of a collection of articles from the IUCr 2023 Congress in Melbourne, Australia, and commemorates the 75th anniversary of the IUCr.
Portland cements (PCs) and cement blends are multiphase materials of different fineness, and quantitatively analysing their hydration pathways is very challenging. The dissolution (hydration) of the initial crystalline and amorphous phases must be determined, as well as the formation of labile (such as ettringite), reactive (such as portlandite) and amorphous (such as calcium silicate hydrate gel) components. The microstructural changes with hydration time must also be mapped out. To address this robustly and accurately, an innovative approach is being developed based on in situ measurements of pastes without any sample conditioning. Data are sequentially acquired by Mo Kα1 laboratory X-ray powder diffraction (LXRPD) and microtomography (µCT), where the same volume is scanned with time to reduce variability. Wide capillaries (2 mm in diameter) are key to avoid artefacts, e.g. self-desiccation, and to have excellent particle averaging. This methodology is tested in three cement paste samples: (i) a commercial PC 52.5 R, (ii) a blend of 80 wt% of this PC and 20 wt% quartz, to simulate an addition of supplementary cementitious materials, and (iii) a blend of 80 wt% PC and 20 wt% limestone, to simulate a limestone Portland cement. LXRPD data are acquired at 3 h and 1, 3, 7 and 28 days, and µCT data are collected at 12 h and 1, 3, 7 and 28 days. Later age data can also be easily acquired. In this methodology, the amounts of the crystalline phases are directly obtained from Rietveld analysis and the amorphous phase contents are obtained from mass-balance calculations. From the µCT study, and within the attained spatial resolution, three components (porosity, hydrated products and unhydrated cement particles) are determined. The analyses quantitatively demonstrate the filler effect of quartz and limestone in the hydration of alite and the calcium aluminate phases. Further hydration details are discussed.
Keywords: Portland cements; cement blends; in situ studies; Rietveld quantitative phase analysis; X-ray imaging; filler effect.
1. Introduction
Understanding the hydration of Portland cements (PCs) and PC blends (mixtures with other materials) is very challenging because they are multicomponent (Taylor, 1997; Hewlett & Liska, 2017). The low crystallinity of some phases is the main problem for X-ray powder diffraction characterization, while the small sizes of pores and of some particles, and the low contrast in the X-ray absorption of the different components, are the main issues for X-ray imaging studies. PC CEM I type is composed of Portland clinker with two minor additions: (i) a sulfate carrier (gypsum/bassanite/anhydrite) to delay the hydration of tricalcium aluminate which contributes to regulate setting, and (ii) limestone (mainly calcite) to optimize the rheology without degrading the mechanical performance. However, most of the Portland-based cements used have other additions. PC clinker replacement by supplementary cementitious materials (SCMs) (Juenger & Siddique, 2015; Juenger et al., 2019; Snellings et al., 2023), like slag, fly ashes, kaolinitic calcined clays or natural pozzolans, is key to decreasing the CO2 footprint of the resulting mortars and concretes. Naturally, these additions add complexity to the hydration of the resulting binders.
PCs and PC–SCM blends are multiphase systems with different elemental compositions, phases (type and content) and textural properties, such as specific surface areas and particle size distributions. The hydration processes happen under various conditions, including water-to-binder mass ratio (w/b), temperature and pressure. The complexity of binder hydration stems from the evolution of the phases and the resulting microstructures. After initial partial dissolution and ; Hewlett & Liska, 2017). Hence, a large number of analytical techniques are employed to study the hydration processes with accuracy. The most common techniques, including laboratory X-ray powder diffraction (LXRPD), have been described in detail in a book that was published in 2016 (Scrivener et al., 2016) and which is currently the standard in the field. However, X-ray microcomputed tomography (µCT) (Maire & Withers, 2014; Brisard et al., 2020; Withers et al., 2021) was not included in that book.
a set of coupled reactions leads to the precipitation of several hydrates within evolving microstructures (Taylor, 1997Cement notation will be used hereafter (Taylor, 1997). Before being mixed with water, PCs consist of more than six crystalline components: (CaSO4·2H2O, gypsum and/or other calcium sulfates), C3S (Ca3SiO5, alite), C3A (Ca3Al2O6, tricalcium aluminate), C4AF (Ca4Al2Fe2O10, tetracalcium aluminoferrite), Cc (CaCO3, calcite/limestone) and C2S (Ca2SiO4, belite), ordered by their hydration reaction rates. After water mixing and at different timescales, more than five new hydration products are formed: AFt [Ca6Al2(SO4)3(OH)12·26H2O, ettringite], C–S–H gel (nanocrystalline, nearly amorphous, calcium silicate hydrate), CH [Ca(OH)2, portlandite], Fe–Si–H (amorphous iron–siliceous hydrogarnet), Hc [Ca4Al2(OH)13(CO3)0.5(H2O)5.5, hemicarboaluminate] and Mc [Ca4Al2(OH)12(CO3)(H2O)5, monocarboaluminate], ordered by their approximate formation hydration kinetics. The Hc and Mc phases are AFm-type crystalline phases, but other AFm phases, with variable stoichiometries in the interlayer space, are also known, including amorphous variants (Balonis & Glasser, 2009; Matschei et al., 2007).
On the one hand, time-dependent quantification of the crystalline components for neat PC hydration is nowadays well established (Aranda et al., 2012, 2017, 2019; Scrivener et al., 2016; Jansen et al., 2012; Qoku et al., 2023). The overall amorphous content can be determined using external (Jansen, Goetz-Neunhoeffer et al., 2011) or internal (De la Torre et al., 2001) standard methodologies. However, obtaining the degree of hydration of SCMs in PC–SCM blends is very challenging (Juenger & Siddique, 2015; Juenger et al., 2019; Snellings et al., 2023). This is due to several factors, including the presence of several amorphous components: C–S–H gel, Fe–Si–H, free water (FW), the amorphous phase within the SCM (for instance, SiO2 in natural pozzolans) and C–(A)–S–H gel. In addition, X-ray diffraction with a flat sample geometry is prone to some systematic errors, such as and water/solid bleeding. Specifically, for cements, special care has to be exercised to avoid carbonation of CH, as accurately measuring portlandite content is critical to determine the pozzolanic reaction degree, i.e. the reaction between siliceous/aluminium oxides with Ca(OH)2 to yield C–(A)–S–H gel and other hydrates, such as AFt, Hc and Mc, depending upon the SCMs employed. It is thus important to develop experimental approaches which minimize experimental errors.
On the other hand, even after 15 years of research, analysing the time evolution of components and microstructures in cement hydration by µCT (Withers et al., 2021) remains a significant challenge. The uses of µCT in cements have been reviewed elsewhere (da Silva, 2018; du Plessis & Boshoff, 2019; Brisard et al., 2020; Kong et al., 2020; Sugiyama & Promentilla, 2021; Chung et al., 2019). Here, it is noted that synchrotron µCT, in the different modalities (absorption-based, phase-contrast, ptychography etc.) (Aranda, 2016; Shirani et al., 2023; Qoku et al., 2023), yields more information than laboratory µCT, but access to this set of techniques is very limited and demanding. The spatial resolution of synchrotron µCT, for hydration studies, depends upon the chosen modality and tested field of view. The voxel sizes can be two to three times smaller. The spatial resolution of laboratory µCT for hydration studies also depends upon the measured field of view and it is usually 2–3 µm or worse. Features smaller than the spatial resolution cannot be determined in conventional laboratory-based X-ray imaging, which is a problem because (i) the gel porosity of cement pastes ranges from 5 to 100 nm, (ii) the capillary porosity varies between 100 nm and a few micrometres, and (iii) several cement components have quite a significant fraction of particle sizes smaller than 2 µm. Nevertheless, research on cement hydration using laboratory µCT is increasing as this technique does not require sample preparation which is known to alter the labile microstructures of hydrating binders.
The research presented here is aimed at the in situ analysis of cement hydration by combining LXRPD and µCT. These techniques require no sample preparation and allow automation of data analysis. Our approach is based on sequential analysis of the same volume, which imposes constraints on the results. This approach helps to deal with the complexity of the studied problem. The reported investigation is part of a long-term project finally to address the development of an accurate methodology to analyse PC–SCM blends, including the analysis and understanding of the pozzolanic set of reactions. For this purpose, and in our first report, XRPD and µCT were used to analyse a PC paste-filled capillary (Salcedo et al., 2021). That work established some experimental parameters but it did not carry out any time-dependent hydration study. In a second recent report (Shirani et al., 2024), we extended this approach to study a hydrating cement, PC 42.5 R, at 1, 3, 7 and 77 d. The results of the analyses at 7 d within the hydrating capillary were compared with ex situ prepared pastes which were additionally studied by and XRPD. The results for the ex situ and in situ analyses were very similar, allowing us to establish the accuracy of the procedures. Here, we further broaden this methodology by studying the hydration of three related pastes: (i) another fine PC 52.5 R, and two blends of this cement with (ii) quartz and (iii) limestone. The obtained results are proven to be very robust and accurate. Portlandite easily carbonates but this methodology can measure it very reliably. Ettringite is very labile and the reported approach can measure it faithfully. These are necessary steps before extending this methodology to key PC–SCM blends, which are more challenging to analyse because of the extra difficulty of following the additional reactions during hydration. The final objective is to determine robustly the pozzolanic activity of SCMs by employing this combination of techniques.
2. Experimental
2.1. Materials
For this study, a CEM I 52.5 R commercial Portland cement was used that fulfils EN 197-1. Hereafter, this sample is abbreviated as PC-525. To prepare the corresponding blends, commercial quartz (Qz) and limestone (LS) were also employed. Qz was supplied by José Sanchís Penella, S.A. (Spain). LS was supplied by Omya Clariana S.L.U. (Spain) and its trademark is Omyacarb 12 Extra-PU.
The preparation of the two blends, (i) 80% of PC-525 and 20% of Qz, and (ii) 80% of PC-525 and 20% of LS, is detailed next. PC-525 (120 g) and Qz (or LS) (30 g) were weighed and subsequently introduced into a ∼1.3 l vessel with three steel balls of 33 mm in a Micro-Deval ball mill (Proeti). The mixtures were stirred at 100 rev min−1 for 1.5 h. After a 30 min resting period, the mixtures were stirred again for another 1.5 h. The blends are hereafter abbreviated as PC-20Qz and PC-20LS.
2.2. Paste preparation
The pastes were prepared using the same protocol for all measurements. Neat PC-525 (8.00 g) was weighed and mixed with twice-boiled distilled water (4.00 g) to give a water-to-cement mass ratio (w/c) of 0.50. For the blends, PC-20Qz (or PC-20LS) (8.00 g) and twice-distilled water (3.20 g) were mixed to yield a water-to-binder mass ratio (w/b) of 0.40. The mixtures were manually stirred for 60 s and then stirred in a vortex mixer for another 60 s. Boiled water was used to eliminate any dissolved CO2, and a plastic film covering was used to prevent CO2 diffusion during cooling.
For in situ LXRPD and µCT analyses, the pastes were syringed into 2.0 mm nominal (outer) diameter glass tubes, with a wall thickness of 0.01 mm. Using the Dragonfly software [version 2022.1 for Windows; Object Research Systems (ORS) Inc., Montreal, Canada], the internal diameter in the measured region was estimated to be approximately 1.7 mm. UV-curing adhesive was used to seal both ends to prevent carbonation and loss of water, as previously described (Shirani et al., 2024). For the calorimetric studies, 6 g samples of the pastes described above were injected into the calorimeter glass ampoules.
2.3. Methods
2.3.1. Textural characterization techniques
Particle size distributions (PSDs), and hence particle sizes, were measured by laser diffraction with a Mastersizer 3000 instrument (Malvern Panalytical) provided with a dry chamber (Aero S). The refractive and absorption indexes used were 1.68 and 0.1 for PC, 1.54 and 0.01 for quartz, and 1.66 and 0.01 for limestone, respectively. These values are provided by Malvern Panalytical in their software database, Mastersizer-v3.81. The was measured by nitrogen isotherm employing the BET approach using an ASAP 2420 instrument (Micromeritics, USA). The density was measured by He pycnometry using an Accupyc II 1320 pycnometer (Micromeritics).
2.3.2. X-ray fluorescence
data were measured in an ARL ADVANT'XP+ Thermo Fisher instrument. Samples were prepared in fused beads.
2.3.3. Isothermal calorimetry
The analyses were performed in an eight-channel thermal activity monitor microcalorimeter from TA Instruments. Measurements were taken up to 7 d at 20°C, excluding the first 45 min after mixing to stabilize the equipment thermally.
2.3.4. Laboratory X-ray powder diffraction
Transmission powder X-ray diffraction data were recorded using a Bruker D8 ADVANCE diffractometer with monochromatic Mo Kα1 (λ = 0.7093 Å) radiation. The experimental setup has been previously reported (Shirani et al., 2024). The powder diffraction patterns for the pastes were collected sequentially with the µCT data acquisition, measuring the same volume of the capillary.
2.3.5. Laboratory X-ray computed microtomography
A Bruker SKYSCAN 2214 µCT system was employed to acquire the µCT data sets. As previously described (Shirani et al., 2024), the capillaries were positioned in a custom-designed sample holder to scan the same volume with time (field of view 2.2 × 1.5 mm, horizontal × vertical). The samples were scanned using an LaB6 source filament operated at 55 kV and 130 µA. To reduce beam hardening artefacts, a 0.25 mm Al foil was positioned in front of the CCD3 detector (physical pixel size of 17.4 µm). A 1.1 µm voxel size was achieved by setting a sample-to-source distance of 9.953 mm and a sample-to-detector distance of 305.496 mm and employing 2 × 2 binning. A total of 1801 projections were taken over 360° (0.2° rotation step) with an exposure time of 1.9 s and three-frame averaging; hence the data set resulted in a total recording time of 225 min.
Images were reconstructed using the NRecon software (Version 2.2.0.6, Bruker) employing (i) the required post-alignment, (ii) 30% of beam hardening correction, (iii) smoothing = 1 with smoothing kernel = 2 (Gaussian), (iv) a minimum for CS (cross section) to image conversion of −0.045, −0.010 or −0.020, and (v) a maximum for CS to image conversion of 0.550, 0.550 and 0.700 for PC-525, PC-20Qz and PC-20LS, respectively.
Manual registration was required to align the different scans for adequate data analysis. The procedure is detailed elsewhere (Shirani et al., 2024).
2.3.6. X-ray powder diffraction data analysis
Analysis of the XRPD data was carried out by the GSAS suite of programs (Larson & Von Dreele, 2004). The pseudo-Voigt peak shape function was corrected to account for the observed axial asymmetry (Thompson et al., 1987; Finger et al., 1994). The overall varied parameters included background coefficients, zero-shift error/sample displacement, phase scale factors, unit-cell parameters and peak shape parameters, and when needed. The employed crystal structures are described elsewhere (De la Torre et al., 2017; Aranda et al., 2017; Shirani et al., 2024). To make comparisons, the data must be referred to a constant basis. In this approach, the results are referred to 100 g of paste, as explained below. When referring to a constant base, it is easy to calculate the degree of hydration for each component.
with the2.3.7. Cement paste phase content normalization
The procedure described here is intended to estimate the overall quantity of amorphous phases in the hydrating cement paste in order to refer the analyses to a constant basis, i.e. 100 g of cement/binder paste. This approach does not require internal or external standards, as it is based on the hydration reactions that take place during cement hydration. However, it does require knowledge of the stoichiometries of the reactions yielding the amorphous phases. The amounts of the different amorphous phases are calculated from the reactions of the corresponding crystalline phases (Shirani et al., 2024). The procedure has been recently sketched out (Shirani et al., 2024) and it is thoroughly described here. Table 1 displays the hydration reactions that can take place in neat Portland cement hydration, i.e. not including any pozzolanic hydration reaction(s).
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The calculated amounts of hydrated phases (crystalline and amorphous) were obtained by the hydration equations given in Table 1 considering the amounts of the reactants. The steps for the calculations are shown graphically in Fig. 1 and are based on previous publications (Avet et al., 2018; Huang et al., 2021; Briki, Avet et al., 2021; Shirani et al., 2024), but they are adapted here. Initially, the phase contents of the anhydrous binders are referred to 100 g of paste. For the PC-525 paste, since the w/c ratio was 0.50, the normalization factor was 0.667, i.e. 100/150. For the other two pastes, the employed w/b ratio was 0.40 and therefore the rescaling factor was 0.714. In a second step, the reacted amounts in a given time interval, for instance from initial mixing (t = 0) to 3 h, are determined by subtraction. Because of the existence of experimental errors, if the amount of a given phase is (slightly) larger at a later hydration age, the result of this subtraction is set to 0.
In the 0–3 h time period, the reacted crystalline C4AF fraction is computed according to equation (4a). This yields calculated amounts of amorphous iron–siliceous hydrogarnet C3FS0.84H4.32 (Fe–Si–H), AFt and CH. The stoichiometry assumed for Fe–Si–H was initially reported by Dilnesa et al. (2014) and it is being widely adopted (Avet et al., 2018; Shirani et al., 2021; Zunino et al., 2022). The reacted amount of C3S, after subtraction of the C3S required for equation (4a), is computed according to equation (1). This yields calculated amounts of C–S–H and CH. The assumed stoichiometry for C–S–H gel is (CaO)1.8SiO2(H2O)4.0, which includes the gel pore water. The C/S ratio in C–S–H/C–A–S–H gels is variable but for the hydration of neat PC pastes is close to 1.8 (Zhu & Richardson, 2023; Cuesta et al., 2018). The total amount of CH is obtained by equations (4a) and (1). At this time interval, the reacted C3A fraction is computed according to equation (3a). This yields a calculated value of AFt which is added to the one resulting from C4AF hydration.
In the 3 h to 1 d time period, because AFt keeps increasing and Hc is not formed, the same equations detailed above are applied. In the 1–3 d time period, AFt does not significantly increase and Hc and Mc are formed. Therefore, different chemical reactions are applied for C3A and C4AF. The C4AF fraction is computed according to equation (4c). This yields calculated amounts of amorphous Fe–Si–H, Mc and CH. The reacted C3S content, after subtraction of the C3S required for equation (4c), is computed according to equation (1). The reacted C3A fraction is computed according to equation (3b), yielding Hc. In the 3–7 d time period, exactly the same equations detailed for the previous time interval are applied. In the 7–28 d time interval, C3A reaction is not considered as its content at 7 d is negligible, but C2S starts to hydrate which should be considered. Therefore, the C4AF fraction is computed according to equation (4c), C3S is computed according to equation (1) and the C2S reacted fraction is considered by equation (2). At later ages, the hydration of C3S and C2S is considered with equations (1) and (2), respectively. However, at later ages, C4AF is considered to react according to equation (4d) which is a modified version where the iron–siliceous hydrogarnet also contains aluminium. This approach can be adapted to the different binders depending upon the consumption of the reactants and the formation of the crystalline products.
The procedure sketched above has been implemented in an Excel (Microsoft) file allowing us to refer the results to 100 g of paste. In order to do so, several assumptions are made.
(i) The (possible) amorphous contents of the initial binders are not considered and the amorphous content of the pastes is just the added amounts of water.
(ii) The amorphous content at a given time is the sum of the calculated amorphous components, C–S–H gel, Fe–Si–H and FW. FW is calculated as the amount of nominal (added) water minus the amount of chemically bound water, taking into account the chemical hydration reactions listed in Table 1.
(iii) Other (possible) amorphous phases, for instance, AFm-type, are neglected. The assumption of no amorphous AFm content is an approximation but is in line with recent findings showing that the reacted Al content is mainly within crystalline AFt, Hc and Mc and incorporated within C–S–H (Hemstad et al., 2024).
With these three considerations, the normalization factor is iteratively varied, starting with the value obtained in the previous hydration time, until the best possible agreement is achieved between the measured CH value and the calculated one after applying the normalization. The results for unreactive phases such as quartz, calcite and belite (at early ages) allow us to check the procedure.
Importantly, because C–S–H and Fe–Si–H phases are formed, the overall amount of amorphous phases keeps smoothly increasing with hydration time. In other words, the normalization factor, i.e. 0.667 for PC-525 paste, decreases with time. There are other cements, e.g. calcium sulfoaluminate cements, where ye'elimite reacts with water to yield ettringite and minor amounts of amorphous aluminium hydroxide. In this particular case, the mass of the crystalline products is larger than that of the reactants and this normalization factor increases with time. This type of cement is being currently studied and the results will be reported elsewhere.
3. Results and discussion
This section is structured as follows. In the first subsection, the initial characterization of the employed materials is reported. This subsection also reports the calorimetric study of the pastes and the continuous study of the powder diffraction patterns for the PC-20Qz paste for about 3 d. In the following three subsections, the results for the in situ XRPD studies of PC-525, PC-20Qz and PC-20LS are presented and discussed. This characterization includes the calculated amounts based on the hydration reactions given in Table 1. The in situ µCT studies for the pastes are then reported, i.e. including the results previously obtained for PC-425.
3.1. Initial characterization
The elemental compositions of the materials used here are given in Table 2. This table also displays the values previously published (Shirani et al., 2024) for PC-425, for easy access to the information. The corresponding mineralogical compositions are given in Table 3. Potassium sulfates, single or double salts, were not considered as their diffraction peaks are very broad and severely overlap. Microstructural properties are as important as the elemental and mineralogical compositions to understand the reactivity of cements. Therefore, Fig. 2 displays the PSD traces, and Table 4 gathers the corresponding values and the specific surface areas and Blaine fineness. The particle sizes of quartz and limestone are quite similar to those of PC-525.
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The overall hydration kinetics of the studied pastes have been investigated by isothermal ). Fig. 3(a) displays the heat flows for up to 2 d, for better visualization, while Fig. 3(b) shows the cumulative heat up to the final time of the measurements, i.e. one week. The released heats at 7 d of hydration were 342.2, 359.0, 359.3 and 310.0 J g−1 of cement for PC-525, PC-20Qz, PC-20LS and PC-425, respectively. The results are totally in line with cement chemistry knowledge (Taylor, 1997; Scrivener et al., 2016). PC-525 releases more heat and is faster than PC-425, mainly because of the smaller particle sizes of its constituents. Cements PC-20Qz and PC-20LS yield more heat and are faster than PC-525, as expected because of the filler effect (Oey et al., 2013; Berodier & Scrivener, 2014; Kumar et al., 2017). The additional surface available, due to the added quartz or calcite, mainly promotes the and growth of C–S–H gel from alite hydration.
(Fig. 3An initial XRPD study was performed for the PC-20Qz paste, which was repeatedly scanned after water mixing for 66 h. This work was carried out in addition to the powder patterns collected for the joint Rietveld and µCT study discussed below. The paste was the same but the capillary was different. Fig. 4 displays a 3D view of all the patterns over a selected 2θ range, i.e. 1.5 to 10° 2θ (Mo Kα1 radiation), for better visualization. Related to the unhydrated cement phases, gypsum is fully dissolved at ∼12–14 h [dashed line in Fig. 3(a)] after water mixing. This is the time where the overlapped peak (shoulder) in the signal is observed [Fig. 3(a)]. This peak is usually named the sulfate depletion peak and it signals a reduction in the sulfate concentration in the pore solution. Fig. 4 demonstrates that crystalline AFm-type phases are not formed at this hydration time.
Concerning formation of the crystalline hydrated phase, several conclusions can be drawn.
(i) The powder diffraction peaks of AFt are already present during the first powder pattern collected at 2 h because the hydration reaction described by equation (3a) is very fast.
(ii) The integrated intensities of AFt grow rapidly at early ages, i.e. during the first 24 h.
(iii) AFt crystallization keeps occurring well after full gypsum dissolution at ∼14 h. This has been repeatedly reported (Jansen et al., 2018; Bérodier et al., 2020; Morales-Cantero et al., 2024). The necessary sulfates come from from the C–S–H gel.
(iv) CH diffraction peaks have low intensity in the first 4 h and their intensities start to increase rapidly after the end of the induction period.
(v) Hc diffraction peaks start to appear at ∼34 h [dashed line in Fig. 3(a)]. This has no clear associated thermal effect in the signal [Fig. 3(a)]. However, detailed inspection shows a slight bump upwards compared with the smooth descending behaviour in the 15–21 h time interval; this bump is often related to AFm precipitation.
(vi) Finally, an increase in the low-angle scattering due to the precipitation of nearly amorphous C–S–H gel, located in the 1.5–2.5° range, is measured after 4 h, when the
ends.3.2. In situ XRPD study for PC-525
XRPD patterns for PC-525 paste were collected at six hydration ages. The Rietveld analyses were carried out as described in the Experimental section. The resulting Rietveld plots are displayed on a linear scale in Fig. 5(a) and on a logarithmic scale in Fig. 6(a). Displaying the Rietveld plots on a logarithmic scale allows us to follow low-intensity/scattering features which are more difficult to observe on a linear scale. Additional scattering is measured between 4.5 and 6° (2θ/Mo Kα1) at 3 d and afterwards. This signals the precipitation of poorly crystalline AFm-type phases. This precipitation takes place in addition to the crystallization of the Hc (hemicarbonate) and Mc (monocarbonate) phases. Additional scattering (i.e. background increase) is also observed between 13 and 16° (2θ/Mo Kα1). This scattering is due to the precipitation of C–S–H gel. Finally, note that the portlandite peak at 8.5° (2θ/Mo Kα1) is not perfectly fitted, but additional diffraction is observed in the low-angle region of these peaks. This is very likely due to the presence of crystallization defects in layered Ca(OH)2, which has been previously reported (Chaix-Pluchery et al., 1983; Madeja et al., 2023).
The Rietveld quantitative phase results, without any normalization procedure, are given in Table 5. They are not referred to a constant basis and therefore they need elaboration. The normalization procedure, from the raw results to the data referred to 100 g of paste, has been carried out as detailed in Section 2.3.7. The results referred to 100 g of paste are displayed in Table 6. At t0 the normalization factor is the nominal amount of cement in the paste, i.e. 0.667. As the hydration reactions progress, the amount of amorphous material increases and therefore this normalization factor (smoothly) decreases (Table 6). At 7 d of hydration the measured amount of portlandite is 14.4 wt%, which is slightly larger than that measured at the same age for PC-425 (12.5 wt%; Shirani et al., 2024). This was expected as PC-525 is slightly more reactive due to its smaller particle sizes [see also Fig. 3(b)]. This comparison shows the robustness of the reported experimental procedure. Concerning the ettringite phase, Table 6 shows that the maximum measured amount was 8.7 wt%. As expected, this value is smaller than that for PC-425, i.e. 11 wt%, because the SO3 contents for PC-525 and PC-425 are 3.3 and 3.9%, respectively. The maximum amount of AFt, considering SO42− as the limiting reactant, would be 10.8 wt% and this value is never reached (Table 6). The higher calculated values for AFt from C3A dissolution (Table 6) mean that after 1 d the aluminates are not the limiting reactant. Therefore, AFm-type phases (amorphous and/or crystalline) should precipitate. Concerning Hc and Mc phases, larger amounts of Hc component are measured up to 7 d. At 31 d and later, the situation reverses and larger amounts are measured for Mc, the thermodynamically stable phase. This behaviour has been repeatedly reported in the literature in many cement systems, not only for neat Portland cements (Georget et al., 2022). Quantitatively, this study shows that a small amount of amorphous AFm-type phase(s) should precipitate, which agrees with the qualitative observation of an increase in background scattering at 4.5–6° (2θ/Mo Kα1). In this context, it must be noted that recent thermodynamic work (Lothenbach et al., 2019) indicates that iron–siliceous hydrogarnet is the stable phase, in preference to AFm, under many conditions. Therefore, partial Al substitution within iron–siliceous hydrogarnet could be expected, which would lead to lower contents of (Al-rich) AFm-type phases.
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The hydration degree of every clinker phase can be readily obtained from the data in Table 6 at the studied hydration ages as their contents are referred to a constant basis. These values will be considered for all the studied binders in the General discussion section. It is clarified that the crystalline C3A contents at 0 and 3 h were measured as 3.2 and 3.4 wt%, respectively. We interpret this as the variability inherent in any experimental result and not due to an actual increase in C3A amount. Hydration between 31 and 128 d is proved, as the alite and belite contents decrease and the portlandite content increases. This shows that hydration does not stop because of the self-desiccation effect (Wyrzykowski & Lura, 2016) with the employed experimental setup, i.e. a capillary with a thickness of 2 mm.
3.3. In situ XRPD study for PC-20Qz
Five Mo Kα1 XRPD patterns were collected for the PC-20Qz paste. The Rietveld plots are displayed on a linear scale in Fig. 5(c) and on a logarithmic scale in Fig. 6(c). As discussed above, additional scattering due to poorly crystalline AFm phases is observed between 4.5 and 6° (2θ/Mo Kα1) at 3 d and afterwards. C–S–H gel precipitation is also detected at 1 d and later ages as the background increases at 3.5° (2θ/Mo Kα1), and also between 13 and 16° (2θ/Mo Kα1).
The direct Rietveld results are given in Table 7 and the component percentages, referred to 100 g of paste, are gathered in Table 8. At t0 the normalization factor is the nominal amount of binder in the paste, i.e. 0.714. The w/b = 0.40 used corresponds to a water/cement phase mass ratio of 0.50, i.e. 40 g of water for 80 g of pristine cement. Hence, a possible difference in reactivity will not arise from a different w/c ratio with respect to PC-525 phases. As expected and discussed previously, the relative amount of amorphous phases increases with hydration time and therefore the normalization factor decreases smoothly with time. The measured amount of portlandite at 7 d is 12.7 wt%, which is slightly larger than that measured for PC-525 after 20% dilution, i.e. 11.5 wt%. This is very likely due to the enhanced reactivity of C3S because of the filler effect, as discussed in the calorimetric study in Section 3.1. This comparison shows again the high accuracy and robustness of the reported experimental procedure. Concerning the ettringite phase, the results are also very robust: 80% of the maximum amount of AFt measured for PC-525 would be 7.0 wt%, which agrees very well with the maximum amount of AFt measured for PC-20Qz, 6.9 wt% (Table 8). The evolution of the contents of Hc and Mc in PC-20Qz is totally in line with the values obtained for PC-525.
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Quartz is an unreactive phase. Therefore, if the normalization procedure is correct the obtained values should be constant. This is indeed the case, and the measured values between 3 h and 28 d are in the range 15.1–15.4 wt%. The t0 value of 14.4 wt% is the nominal (weighed) one, considering that the cement has no amorphous or unaccounted phases. We considered this comparison quite satisfactory and we speculate that the small difference between 14.4 and 15.2 wt% is mainly due to the employed assumption of no amorphous phases in PC. Portland clinker could have a small fraction of subcooled (non-crystalline) liquid. It is acknowledged that the presence of non-diffracting phase(s) in grey Portland clinkers is debatable, with reports both for (Aranda et al., 2012; Christidis et al., 2021; Kang et al., 2023) and against (Jansen, Stabler et al., 2011; Snellings et al., 2014). Additionally, the clinker is milled with calcium sulfate and limestone additions from quarries which are known to be of limited purity.
3.4. In situ XRPD study for PC-20LS
Five Mo Kα1 XRPD patterns were also collected for the PC-20LS paste. The Rietveld plots are displayed in Figs. 5(d) and 6(d). The direct results are given in Table 9 and the phase contents based on 100 g of paste are shown in Table 10. This paste also had a w/b ratio of 0.40 and therefore, at t0, the normalization factor is 0.714. The obtained values for this normalization factor with time are very similar to those determined for PC-20Qz, which agrees with the very similar calorimetric traces (Fig. 3).
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The amount of portlandite measured at 7 d for PC-20LS is 12.5 wt%. This value is the same, within error, as that measured for PC-20Qz, i.e. 12.7 wt%. Concerning ettringite, the results are again very robust. The AFt measured content ranges from 6.6 to 6.8 wt% in the 1–7 d interval. For PC-20Qz during this period, the AFt measured content ranges from 6.5 to 6.9 wt%. Interestingly, the Hc and Mc contents for PC-20LS are the same, within error, as those measured for PC-20Qz. This highlights that the carbonate content of the pristine cement is enough for aluminate reactivity and that the additional limestone in this blend only has filler and dilutive effects.
Calcite is partly reactive, but the measured amounts of Hc and Mc require the dissolution of less than 0.40 g of calcite, referred to 100 g of paste. The measured values of calcite between 3 h and 28 d range from 18.5 to 18.8 wt%. The t0 value, 17.4 wt%, is again a nominal one, considering that the cement has no amorphous or unaccounted phases. We consider this comparison also satisfactory and we speculate that the small difference between ∼17.0 and 18.6 wt% is mainly due to the assumption that PC has no amorphous phase(s).
3.5. In situ µCT study
When there is sufficient contrast between the components and sufficient spatial resolution, the dissolution of anhydrous phases can be directly visualized by µCT. This technique is complementary to LXRPD as it could allow us to quantify the dissolution of amorphous particles if they could be disentangled. For in situ studies interrogating the same volume of a sample, there is a significant constraint in the data analysis because anhydrous particles can only decrease in volume. This could be quite helpful for advanced data analysis approaches. Unfortunately, conventional laboratory X-ray attenuation µCT is unable to detect features smaller than the spatial resolution, and the contrast between the different components is not always enough for accurate segmentation.
With these caveats, Fig. 7 shows selected orthoslices for the studied pastes. The favoured dissolution of the smallest cement particles (brightest regions) is clearly noticeable, as is paste densification over time. PC-20Qz also shows tiny bubbles of entrained air. Fig. 8 displays enlarged views for PC-525, underlining the three components that can be easily identified: porosity (darkest regions), hydrated products (HPs, intermediate grey values) and unhydrated cement particles (UCPs, whitish particles). The HP regions include capillary water.
Pixel size is related to, but not the same as, spatial resolution. Currently, there is no general method for quantifying and reporting the resolution of a given tomogram. The spatial resolution was estimated by employing edge sharpness across interfaces. According to ISO/TS 24597 (Donnelly et al., 2020), the resolution is defined as the Gaussian radius of the point spread function, which is the change between 25 and 75% grey value across the studied sharp interface (Donnelly et al., 2020; Li et al., 2023; Shirani et al., 2023). This method, applied to the air/capillary outer wall boundary, gave 2.2 (3) µm from six measurements in three different capillaries. Fig. 9 displays one example of this type of plot. The obtained value for the spatial resolution is fully consistent with a former report (Shirani et al., 2024). The spatial resolution, approximately 2.2 µm, has a significant impact. Particles smaller than this threshold cannot be identified and are instead considered part of a neighbouring component, which is likely to be the most abundant one, i.e. a hydrated phase. As demonstrated below, this feature results in a slight overestimation of HP and a small underestimation of the UCP fraction.
The PC–quartz blend has been employed here as a starting point for the PC–SCM blends to be investigated in a forthcoming report. Fig. 10(a) displays an enlarged view of an orthoslice of PC-20Qz showing quartz particles. The grey values of quartz are very similar to those shown by HPs, which makes its segmentation difficult as global thresholding cannot be employed. More sophisticated approaches, for instance using machine learning, are needed and this is currently being pursued. The PC–limestone blend was investigated as calcite is a very common addition in a range of low-carbon cements (Voglis et al., 2005; Juenger et al., 2019; Briki, Zajac et al., 2021). Fig. 10(b) displays an enlarged view of an orthoslice of PC-20LS showing limestone particles. The grey values of calcite are slightly larger than those of HPs and lower than those of UCPs. This makes direct quantification of limestone also challenging.
A semiquantitative evaluation can be done on the basis of the time evolution of the grey-value histograms (Fig. 11). Several features merit discussion, being in line with our previous publication (Shirani et al., 2024):
(i) The employed experimental setup permits separation of UCPs from HPs for particles larger than the spatial resolution. Nevertheless, partial volume effects cannot be avoided in cements as many particles are smaller than the spatial resolution (Aranda, 2016).
(ii) UCPs decrease over time for all pastes (as indicated by the black arrows in Fig. 11), while the amount of HP increases (as indicated by the blue arrows).
(iii) HPs densify with time and this is reflected by larger average grey values with hydration time (also blue arrows).
(iv) There are constant crossing points (brown arrows in Fig. 11) for all studied pastes. From the time evolutions, the particles with grey values above these thresholds are primarily UCPs, while particles with lower grey values are principally HPs.
(v) The signature of air porosity development, i.e. shrinkage and appearance of water-vapour-filled capillary pores, is evident in the left-hand tails of the HP bands.
(vi) As expected, the UCP/HP ratio is larger for PC-425 than for PC-525 because this last binder has smaller particle sizes which react faster. These ratios are even smaller for PC-20Qz and PC-20LS, as quartz and calcite have grey values within the HP region.
(vii) Quartz is not apparent in the histogram trace for PC-20Qz as its grey values are located at ∼14 000, which completely overlaps with the HP grey values.
(viii) Finally, calcite is barely seen in the histogram trace for PC-20LS, as a shoulder in the right-hand part of the HP bands with grey values very close to the crossing point for this paste.
Quantitative analysis of the tomograms for PC-525, i.e. segmentation, has been carried out by manual global thresholding. PC-20Qz and PC-20LS CTs have not been segmented because the quartz and limestone components cannot be separated with this approach. The volume of interest (VOI) that was treated, ∼2.0 mm3, had a cylindrical shape with a height of approximately 0.9 mm and a diameter of around 1.7 mm, as shown in Fig. 12. The segmentation of the VOI using Dragonfly resulted in three components: UCPs, HPs and porosity. The grey value for the boundary between UCPs and HPs remained constant over time, with a 26 000 grey value for the experimental conditions used. In contrast, the HP/porosity boundary varies over time and was estimated for each data set using the tangent-slope approach (Shirani et al., 2021). The grey values ranged from 10 000 to 14 000. Table 11 presents the volume percentages of the three components for PC-525 paste over time. Discussion of these results will be carried out in the next section, together with the RQPA output.
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4. General discussion
The final goal of this ongoing research project is to establish a methodology that enables precise analysis of cement components over time from in situ powder diffraction and microtomography, avoiding any sample preparation step. It also seeks to avoid the use of internal standards as these may modify the kinetics because of the additional surface and possible release of ions. In our first report (Shirani et al., 2024), PC 42.5 R was chosen because it has larger particles, i.e. Dv,50 is 17.6 µm. Here, the research is expanded to investigate another cement and two additional blends. The second cement, PC 52.5 R, has a smaller particle size, Dv,50 = 14.0 µm, and the paste also has w/c = 0.50. Two blends of 80 wt% PC 52.5 R and 20 wt% quartz (or calcite) have been studied in the form of pastes with w/b = 0.40. We note that fractions with particle sizes below the achieved spatial resolution of 2.2 µm, which are about 12 vol.% (Fig. 2), cannot be measured by µCT even if there is enough contrast for their identification.
To carry out the comparison of LXRPD–µCT results, firstly the RQPA contents given in the previous section, in wt%, must be transformed to vol.% considering the densities of the components (Balonis & Glasser, 2009). For this comparison, the clinker phases have been gathered, i.e. C3S, C2S, C3A and C4AF, within the overall UCP component. C–S–H gel comprises approximately 35 vol.% of the paste, expressed as (CaO)1.8SiO2(H2O)4.0, which includes the gel pore water but not the capillary water. Due to the intermixing of C–S–H and capillary water, when these two components are grouped they fill ∼60% of the volume. Table 11 reports the UCP/HP ratios with hydration time for PC-525 and PC-425. The UCP content comparison between in situ LXRPD and in situ µCT has to be cautiously carried out as the data are registered consecutively, i.e. with a small time difference. This could be relevant at 1 d, when the reactions are relatively fast, but is likely to be insignificant at 3 d or later. For PC-525, the agreement between UCP contents from LXRPD and µCT is within 1.3 vol.% at 1 d and within 2.5 vol.% at later hydration ages. This disagreement is considered acceptable taking into account the assumptions made, and indicates that the UCP results from µCT data are relatively accurate. As demonstrated by LXRPD and PC-425 is less reactive than PC-525. This is evident in Table 11 as, for a given age, the UCP contents for PC-425 are invariably larger than those for PC-525. Finally, note that µCT data for PC-20Qz and PC-20LS pastes have not been segmented as global thresholding does not allow the classification of quartz and calcite components. Machine learning segmentation is being tried and, if successful, it will be reported elsewhere.
This work uses absorption-based X-ray imaging, but X-ray grating-based imaging could help in the characterization of sub-resolution features. The implementation of these approaches is being extended from synchrotron beamlines to laboratory instruments (Prade et al., 2016; Blykers et al., 2022). X-ray diffraction/scattering computed tomography is also being extended to laboratory equipment (Cersoy et al., 2015). However, the implementation of laboratory diffraction computed tomography in cement samples is really challenging because of the co-existence of high- and low-diffracting components.
Finally, it is appropriate to compare the developed LXRPD methodology and the obtained degree of hydration (DoH) results with previous publications. Concerning the LXRPD data collection methodology, two approaches are usually followed in cement hydration studies. On the one hand, the pastes can be cast in plastic cylinders, sealed and cured until the required age. Immediately prior to the measurements, discs are cut and polished, usually with sandpaper (Lothenbach et al., 2008; Durdziński et al., 2017). On the other hand, the pastes can be cast in any container, sealed and cured. At a given hydration age, pieces (or ground powder) are immersed in an appropriate solvent (e.g. acetone or propan-2-ol) to arrest the hydration reactions. After solvent removal (under vacuum or by gentle heating), the powder is ground [see for instance Noguchi et al. (2021)]. This second approach gives good particle averaging for phases with larger grains, and portlandite is less susceptible to carbonation as free water is removed. It allows the use of additional techniques for the same powder, such as However, labile components, e.g. ettringite, are partly destroyed in the hydration-arresting step. The first approach better preserves the labile phases, but the cutting and polishing steps require good experimental skills, and portlandite is easily carbonated. Neither of these two procedures allows for the same region to be analysed with time. This is an additional drawback for composite cements where there is a large inherent variability. The `mix and measure methodology', very recently reported (Shirani et al., 2024) and further developed here, does not affect labile phases and portlandite cannot be carbonated. It scans a large volume and allows measurement of the same region with time. A drawback is self-drying, although this is shown here not to affect capillaries with a diameter of 2 mm or wider. Of course, the main experimental limitation is the availability of Mo Kα1 radiation.
Concerning the RQPA results, here it is shown that portlandite is not carbonated and that the AFt content does not decrease significantly even up to 128 d of hydration. Large errors in CH content determination have been reported in some cases for the paste disc methodology [see for instance Li & Scrivener (2022)] and very low AFt contents are frequently reported after hydration arresting [see for instance Elakneswaran et al. (2019)]. Because the data are referred to 100 g of paste, the calculation of the DoH at the measured hydration ages is straightforward. Table 12 displays the DoH of the clinker phases for the three studied pastes. The phase-dependent DoH can be compared with those published earlier but the comparison has to be exercised with care, as several features affect the DoH at a given time, including (i) the w/c ratio, (ii) the temperature of hydration, (iii) the fineness of the final cement, (iv) the alkali content and (v) the SO3 content.
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Several conclusions can be drawn from the content of Table 12:
(i) C3S is the most reactive phase at early ages, i.e. less than 3 d. The DoH at 28 d is in the range 88–93% for the three studied pastes. These values compare very well with 88% reported by Lothenbach et al. (2008), on the basis of the work of Parrott & Killoh (1984), for a PC paste with w/c = 0.40. For a PC paste with w/c = 0.50, the C3S DoH was reported to be above 90% by Noguchi et al. (2021).
(ii) C3A reaches full hydration at 7 d. This is in very good agreement with 100% hydration after 7 d reported by Noguchi et al. (2021) and more than 85% hydration degree reported by Lothenbach et al. (2008).
(iii) The DoH for C4AF is 60–70% at 28 d. These values are a bit lower than those reported previously, 70 and 90% by Lothenbach et al. (2008) and Noguchi et al. (2021), respectively. C4AF reactivity varies significantly depending upon the melt composition and the clinkering thermal history (Peys et al., 2022; Boháč et al., 2024). It has been reported very recently that the C4AF hydration rate can be strongly enhanced by the additional surfaces of the SCMs (Redondo-Soto et al., 2023; Morales-Cantero et al., 2024) and accelerating admixtures (Peys et al., 2022; Chang et al., 2024) that can be present in the grinding agents.
(iv) As expected, C2S is the phase with the slowest hydration kinetics. Our results suggest that additional calcite may further slow down its hydration kinetics. For neat PC, we report about 20% DoH of belite at 28 d. Previous work reported about 50% DoH of belite at 28 d (Lothenbach et al., 2008; Noguchi et al., 2021), but we consider these values to be too high and they could be affected by the strong overlap of the C2S and C3S diffraction peaks.
(v) The filler effect (Oey et al., 2013; Berodier & Scrivener, 2014; Kumar et al., 2017) by quartz and limestone of moderate fineness, Dv,50 = 15 and 11 µm, respectively, is firmly proved for C3S. The hydration kinetics of C4AF and C3A are also accelerated because of the presence of these additional surfaces.
5. Conclusions
This research extends an experimental protocol to study in situ cement hydration without any sample conditioning and avoids the use of an internal standard which would dilute the low-content phases even further. After water mixing, the pastes were syringed into 2.0 mm diameter glass capillaries whose ends were simply sealed with a polymer. The pastes underwent sequential analysis by X-ray microtomography and Mo Kα1 X-ray powder diffraction. The use of thick capillaries is crucial to prevent self-desiccation at later ages, which in turn is important to study pozzolanic materials. The sealing prevents portlandite carbonation which is an important source of errors in cement hydration studies. Other advantages of this approach, for powder diffraction, are excellent powder averaging and the minimization of This protocol is tested here with a neat Portland cement type 52.5 R and two blends, 80% PC–20% quartz and 80% PC–20% limestone. Mass-balance calculations allow an estimation of the amount of amorphous phases and, with this, the Rietveld analysis results can be related to a constant basis, 100 g of paste.
The experimental procedure is shown to be robust and accurate. PC-525 has smaller particle sizes that react faster than PC-425. This is shown by powder diffraction and microtomography. The filler effect enhances the reactivity of clinker phases due to the presence of additional surfaces, and this has been quantitatively measured for the blends. The filler effect by quartz and limestone additions is quantified for alite, Ca3SiO5, and for the aluminate phases tricalcium aluminate, Ca3Al2O6, and brownmillerite, Ca4Al2Fe2O10. Chiefly, portlandite and ettringite phases are reliably quantified. This opens an avenue for quantifying the effect of admixtures (superplasticizers, accelerators, retarders etc.) with smaller experimental uncertainties. It will also allow the study of pozzolanic reactions at later hydration ages, i.e. between one and six months.
The microtomography data for PC-525 have been segmented and the comparison with RQPA results in an agreement within 2 vol.%. A crossing point in the histograms with hydration time for the three studied pastes is confirmed. This allows us accurately to disentangle the contributions from the clinker phases and from the hydrates. Unfortunately, the grey values for quartz and limestone do not allow segmentation by global thresholding because of severe overlapping.
Acknowledgements
Author contributions: investigation, all data analysis, mass-balance calculations, preparing all figures, review and editing, JF-S; investigation, XRPD and µCT data analysis contribution, mass-balance calculations, review and editing, AC; investigation, µCT data analysis contribution, review and editing, SS; investigation, review and editing, CR-S, AGDT, IS; LXRPD and µCT data collection and processing, review and editing, IRS, LL-R; conceptualization, supervision, mass-balance calculations, writing (original draft), review and editing, MAGA. Funding for open access charge: Universidad de Málaga/CBUA.
Conflict of interest
The authors declare no conflict of interest.
Data availability
All raw data used in this paper (calorimetry, LXRPD and X-ray µCT scan files) are openly accessible on Zenodo at https://doi.org/10.5281/zenodo.10390818.
Funding information
This work has been partly supported by Agencia Estatal de Investigación (grant No. PID2020-114650RB-I00 to Isabel Santacruz, which is co-funded by the ERDF).
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