Effect of Iron-Doped TiO2 Nanotubes on the Hydration of Tricalcium Silicate
Abstract
:1. Introduction
2. Experimental Procedure
2.1. Materials and Methods
2.2. Methods and Sample Preparation
2.2.1. Preparation of Saturated Ca(OH)2 Solution
2.2.2. Interaction of TiNTs and Fe/TiNTs with Supersaturated Ca(OH)2 Solution
2.2.3. Effect of TiNTs and Fe/TiNTs on the Hydration of C3S
3. Results and Discussion
3.1. Characterization of Educts
3.2. Incorporation of Synthesized TiNTs and Fe/TiNTs in a Cementitious System
3.2.1. Interaction of TiNTs and Fe/TiNTs with Supersaturated Ca(OH)2 Solution via pH, Conductivity and BET Specific Surface Area Measurement
3.2.2. Influence of TiNTs and Fe/TiNTs on the Hydration of C3S
- Course of hydration reaction
- 2.
- Study on the hydrated paste of C3S
- Characterization of C3S hydration products
- Phase composition and determination of the degree of hydration after 8 h, 1 d and 7 d
- Determination of BET specific surface area of hydration products
- Mechanical study of hydrated C3S prism
4. Conclusions
- Treatment with supersaturated Ca(OH)2 solution.
- A strong interaction between Ca2+-ions and both TiNTs and Fe/TiNTs was observed as a result of treatment with super saturated Ca(OH)2 solution. The results were proved by pH, conductivity and gas adsorption measurements.
- The pH and conductivity measurements showed a decrease as a result of Ca2+ ions being sorbed by the nanotubes.
- The amount of sorbed Ca2+-ions by nanotubes were quantitatively determined via EDTA titration and thermal analysis using STA.
- The gas adsorption measurement showed lower BET specific surface area and porosity for both type of nanotubes after treatment with super saturated Ca(OH)2 solution, indicating sorption of Ca2+-ions by nanotubes.
- The effect of Fe/TiNTs on the sorption of Ca2+-ions in supersaturated were superior compared to TiNTs.
- Incorporation of Fe/TiNTs and TiNTs with C3S.
- In terms of hydration course, a shortening of the induction period and earlier acceleration period was observed for the samples containing nanotubes. However, the effect of Fe/TiNTs was found to be superior compared to the control sample (pure C3S) and the sample with TiNTs.
- Concerning the studies on hydration products, more hydration products were formed in the presence of Fe/TiNTs and TiNTs, particularly for the samples with Fe/TiNTs content.
- The degree of hydration increased, especially in the presence of Fe/TiNTs. The BET specific surface area of hydration products was quantitatively determined via combing XRD and gas adsorption data.
- A 36%, 16% and 9% increase in compressive strength of Fe/TiNTs samples for 7 d, 14 d and 28 d hydrated C3S paste was obtained.
- On the basis of above obtained results, the following conclusions were achieved:
- Iron-doped TiNTs (Fe/TiNTs) can serve as a promising reinforcement nanomaterial for cement-based construction materials.
- Lowering the values of pH and conductivity, decreasing the concentration of Ca2+-ions in supersaturated Ca(OH)2 solution and decreasing the specific surface area of nanotubes after the treatment with supersaturated Ca(OH)2 are indications of improvement in hydration reactions.
- The main hydration products of cement, such as C-S-H and CH phases, are formed in the media of saturated Ca(OH)2 solution. Finding a strong interaction between Fe/TiNTs and Ca2+-ions from the Ca(OH)2 solution treatment is an indication of improvement of C3S hydration, resulting in a higher amount of hydration products.
- One of the remarkable features of Fe/TiNTs is their enhanced photocatalytic activity at higher wavelengths. This makes them a viable option for the production of self-cleaning concrete in indoor environments where the intensity of UV radiation is low.
- The fabricated nanotube can directly incorporate into concrete when there is a need for this material in a particular case, such as the surface of concrete, but not within the bulk of concrete. The fabricated Fe/TiNTs have high specific surface area of Fe/TiNTs; even fewer percentages (1–2% or even less) of the nanotube is sufficient to use in the construction industry compared to other additives, which can stabilize the cost-benefit. If we take this into consideration, we only need less material and only the top layer of concrete should be modified; then, the overall cost will be not that high.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Free Lime Franke Method (wt.%) | Mineralogical Composition, XRD (wt.%) | Mean Particle Size. LG (µm) | ||
---|---|---|---|---|
C | C | C3S | C2S | d50 |
0.2 | 0.0 | 100 | 0 | 10.5 |
Sample | End of Induction Period (h) | Duration of Acceleration Period (h) | Duration of Main Peak (h) |
---|---|---|---|
C3S | 4.5 | 6.8 | 15.3 |
C3S + 1.0% TiNTs | 3.5 | 6.7 | 15.1 |
C3S + 1.0% Fe/TiNTs | 3.0 | 6.8 | 15.4 |
C3S + 2.0% TiNTs | 2.3 | 6.8 | 15.2 |
C3S + 2.0% Fe/TiNTs | 2.1 | 7.0 | 15.9 |
Age | Sample | C3S 4331-ICSD (%) | CH 61185-ICSD (%) | Cc 40107-ICSD (%) | Amorphous (tot. (%)) | Tot. Phy. Water (%) |
---|---|---|---|---|---|---|
8 h | C3S | 63.47 | 0.75 | 0.50 | 11.30 | 23.97 |
C3S + 2.0 wt.% TiNTs | 51.38 | 1.94 | 0.00 | 23.49 | 23.18 | |
C3S + 2.0 wt.% Fe/TiNTs | 57.93 | 2.37 | 0.42 | 16.15 | 23.12 | |
1 d | C3S | 34.81 | 3.74 | 0.52 | 39.94 | 20.98 |
C3S + 2.0 wt.% TiNTs | 32.87 | 6.80 | 0.48 | 39.75 | 20.10 | |
C3S + 2.0 wt.% Fe/TiNTs | 31.85 | 6.82 | 0.61 | 40.25 | 20.46 | |
7 d | C3S | 22.90 | 12.67 | 1.38 | 44.18 | 18.86 |
C3S + 2.0 wt.% TiNTs | 19.18 | 11.39 | 1.97 | 49.33 | 18.13 | |
C3S + 2.0 wt.% Fe/TiNTs | 20.24 | 13.74 | 1.22 | 46.08 | 18.72 |
Age | Sample | Weight Loss <105 °C | Chemically Bound Water (105–550 °C) | Tot. C3S | Excess Water | Ca(OH)2 (400–550 °C) | CaCO3 (550–700 °C) |
---|---|---|---|---|---|---|---|
8 h | C3S | 0.44 | 2.27 | 66.67 | 31.53 | 3.37 | 0.84 |
C3S + 2.0 wt.% TiNTs | 0.86 | 3.89 | 66.67 | 30.17 | 6.45 | 0.86 | |
C3S + 2.0 wt.% Fe/TiNTs | 0.69 | 4.19 | 66.67 | 30.07 | 7.40 | 0.00 | |
1 d | C3S | 1.30 | 8.88 | 66.67 | 26.55 | 16.20 | 1.95 |
C3S + 2.0 wt.% TiNTs | 1.21 | 10.25 | 66.67 | 25.69 | 16.86 | 0.95 | |
C3S + 2.0 wt.% Fe/TiNTs | 1.34 | 10.07 | 66.67 | 25.73 | 17.51 | 0.00 | |
7 d | C3S | 1.08 | 14.03 | 66.67 | 23.26 | 24.87 | 3.45 |
C3S + 2.0 wt.% TiNTs | 2.69 | 14.12 | 66.67 | 22.13 | 21.87 | 4.68 | |
C3S + 2.0 wt.% Fe/TiNTs | 1.13 | 14.31 | 66.67 | 23.03 | 24.58 | 3.43 |
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Qattali, S.M.Y.; Pritzel, C.; Kowald, T.; Moni, S.M.F.K.; Killian, M.S.; Trettin, R. Effect of Iron-Doped TiO2 Nanotubes on the Hydration of Tricalcium Silicate. Constr. Mater. 2023, 3, 259-275. https://doi.org/10.3390/constrmater3020017
Qattali SMY, Pritzel C, Kowald T, Moni SMFK, Killian MS, Trettin R. Effect of Iron-Doped TiO2 Nanotubes on the Hydration of Tricalcium Silicate. Construction Materials. 2023; 3(2):259-275. https://doi.org/10.3390/constrmater3020017
Chicago/Turabian StyleQattali, S. Mohd. Yonos, Christian Pritzel, Torsten Kowald, S. M. Fuad Kabir Moni, Manuela S. Killian, and Reinhard Trettin. 2023. "Effect of Iron-Doped TiO2 Nanotubes on the Hydration of Tricalcium Silicate" Construction Materials 3, no. 2: 259-275. https://doi.org/10.3390/constrmater3020017
APA StyleQattali, S. M. Y., Pritzel, C., Kowald, T., Moni, S. M. F. K., Killian, M. S., & Trettin, R. (2023). Effect of Iron-Doped TiO2 Nanotubes on the Hydration of Tricalcium Silicate. Construction Materials, 3(2), 259-275. https://doi.org/10.3390/constrmater3020017