Chaotropic substances and their effects on the mechanical strength of Portland cement-based materials

Rossetto, Hebert Luis; Souza, Milton Ferreira de; Pandolfelli, Victor Carlos

doi:10.1590/S1516-14392008000200012

Abstract

Portland cement-based materials are present in our everyday life. Over the last two decades, important developments have been made to improve their mechanical strength, mainly through microstructural design. In addition, another promising parameter still remains in the early stages of understanding: that of adhesion. Recently, interdisciplinary researchers have considered the issue of water confinement by the hydrated cementitious surfaces. It could contribute to increase the adhesion and strength in these materials. On the other hand, ionic and non-ionic chaotropic substances might be able to disorder the structure of such special water. The results presented in this paper show important effects of these chaotropic substances on the strength of cementitious materials. They highlight the role of the confined water on the adhesion, when the microstructural parameters are kept constant. More than contributing to the fundamental understanding of adhesion within cement paste, these results provide basic insights on in-situ nanotechnology.

adhesion; microstructure; mechanical properties; Portland cement

REGULAR ARTICLES

Chaotropic substances and their effects on the mechanical strength of Portland cementbased materials

Hebert Luis Rossetto^{I, II,}^* * email: hebert@if.sc.usp.br ; Milton Ferreira de Souza^II; Victor Carlos Pandolfelli^I

^IMaterials Engineering Department, Federal University of São Carlos, Rod. Washington Luiz, Km 235, 13565905 São Carlos SP, Brazil

^IIPhysics Institute of São Carlos, University of São Paulo at São Carlos, Av. Trabalhador SãoCarlense, 400, 13566590 São Carlos SP, Brazil

ABSTRACT

Portland cementbased materials are present in our everyday life. Over the last two decades, important developments have been made to improve their mechanical strength, mainly through microstructural design. In addition, another promising parameter still remains in the early stages of understanding: that of adhesion. Recently, interdisciplinary researchers have considered the issue of water confinement by the hydrated cementitious surfaces. It could contribute to increase the adhesion and strength in these materials. On the other hand, ionic and nonionic chaotropic substances might be able to disorder the structure of such special water. The results presented in this paper show important effects of these chaotropic substances on the strength of cementitious materials. They highlight the role of the confined water on the adhesion, when the microstructural parameters are kept constant. More than contributing to the fundamental understanding of adhesion within cement paste, these results provide basic insights on insitu nanotechnology.

Keywords: adhesion, microstructure, mechanical properties, Portland cement

1. Introduction

Portland cement is the most important commodity for mankind, being widely used in everyday construction. Besides this importance, Double¹, over two decades ago, highlighted that the familiarity could inhibit further developments of this material. At that time, a group of researchers reported significant improvements on the mechanical strength of cementitious materials², by manipulating microstructural parameters such as pore size. They showed that the intrinsic mechanical weakness of cementitious materials was misleading. It triggered the development of new cement products³. Double also suggested that researchers must also pay attention to promote greater cohesion within the cement paste in order to have additional breakthroughs in this area. This can be understood from the equation recently presented by Kendall⁴, which shows that work of adhesion (W) is vital to increase the tensile strength (σ) as follows:

where, packing fraction (Ф), particle diameter (D), and crack length (c) represent the microstructural parameters.

Nevertheless, a more feasible way to verify the adhesion effect would be by Griffith's equation. Considering that W is related to K_IC and that in the lower part of both equations the critical crack length (c) is dominant, the adhesion changes (W or K_IC) could be, at first, evaluated by the tensile strength (σ) values. This would avoid the direct measurement of the different variables in Equation 1 or the K_IC (Equation 2) in a low toughness and notch sensitive material, such as cement.

Even though, only a few papers have dealt with adhesion. Pellenq et al.⁵ related it to the interaction of the hydrated cementitious phases with the adsorbed water⁶. In addition, it has been shown that the structure of water in the vicinity of most hydrophilic surfaces, in a distance range of 1.01.5 nm from a surface (the socalled "confined water"), is quite similar to that of supercooled water at a lower temperature⁷. The hydrophilic surfaces tend to structure the water molecules for a particular distance. As a hydrated material, it is reasonable to suppose that cement paste presents structured confined water among the particle surfaces. It has in fact been simulated by computer⁸ and seen by inelastic neutron scattering⁹. Hence, the substances which affect the confined water structure might be expected to influence the mechanical strength of Portland cementbased materials. For this reason the use of ionic and nonionic solutions and their correlation with adhesion forces in cementitious materials is an interesting area of research to further change the mechanical strength of these materials.

2. Experimental Procedure

2.1. Preparation of Portland cement plates

Brazilian Type V cement (Holcim: 64.50 wt (%) C₃S; 3.78 wt (%) C₂S; 11.50 wt (%) C₃A; 7.05 wt (%) C₄AF; 7.68 wt (%) gypsum, where, C = CaO, S = SiO₂, A = Al₂O₃, F = Fe₂O₃ and H = H₂O) was used to produce rectangular plates at a compaction pressure of 20 MPa. This processing suitably controls the microstructural reproducibility when a watertocement ratio (w/c) close to 0.15 is used. After being withdrawn from the die, the plates (20 x 70 x 15 mm³) had sufficient strength to support their own weight. They were cured in a humid chamber for 24 hours. At this time, the Portland cement plates achieved nearly 2/3 of their highest strength attained in this work, the latter being reached after curing for 7 days by immersion in room temperature water (reference samples).

Other samples were cured in solutions of either ionic or nonionic substances (all of them were laboratory graded). The following ionic solutions were prepared and used: calcium hydroxide (Ca(OH)₂: 30 mmol.L¹ and 1 mol.L¹), lithium hydroxide (LiOH: 30 mmol.L¹ and 1 mol.L¹), sodium hydroxide (NaOH: 1 mol.L¹), ammonium hydroxide (NH₄OH: 1 mol.L¹), and lithium citrate (30 mmol.L¹). For nonionic solutions, acetone (DMK: 1 mol.L¹), dimethylacetamide (DMA: 1 mol.L¹), and dimethylformamide (DMF: 30 mmol.L¹), were prepared and tested.

2.2. Characterization

After curing, all samples were oven dried at 30 °C for 24 hours and, then, their mechanical strength was measured in 3point bending (span = 45 mm) using MTS (model 810) universal testing equipment. Each set of samples contained, at least, five cementitious plates. The fracture surface of the samples were characterized by scanning electron microscopy (SEM, Zeiss DSM960) in order to evaluate the microstructural changes after curing within the aforementioned solutions. Nuclear magnetic resonance (²⁹Si MASNMR) was used to evaluate differences at the hydration degree of the cementitious samples. Finally, all the ionic solutions had their pH measured and, for nonionic solutions, their surface tensions were evaluated by the De Nouy ring test.

3. Results and Discussion

All samples had the same apparent density (ρ = 2.24 ± 0.02 cm³.g¹), regardless the curing procedures. This aspect, associated to the same microstructural features (Figure 1), indicated that it is very likely that only the adhesion forces were influenced by the curing solutions. This is further supported by ²⁹Si MASNMR analysis which showed only small variations in the hydration degrees of all the samples (42 ± 3%), including the reference ones.

Figure 2a presents the bending strengths of the Portland cement plates after curing in the presence of the ionic solutions. All had a decrease in the strength compared to the reference sample (23 ± 3 MPa). It is noteworthy that the strength decrease was not directly related to the pH of the solution, but mainly to the particular ion in the solutions.

The ions follow the Hofmeister series (Figure 2b), which were originally used to classify them according to their power of precipitating or solubilizing proteins¹¹. Lately, it has been observed that these series also reflect the ions influence on the surrounding water molecules, ranging from stabilization (kosmotropes) to disruption (chaotropes). Still, there is controversy in the scientific community about the mechanism whereby an ion can disturb the water structure¹², although it is generally accepted that salts have a disordering effect on the Hbonding¹³ network. By comparing the results of Figure 2a to the Hofmeister series (Figure 2b), some general guidelines are evident.

Firstly, the chaotropic cations (such as Ca²⁺, Li⁺, and Na⁺) effect on the bending strength of cementitious plates followed the destabilizing sequence of Ca²⁺> Li⁺≈ Na⁺. Secondly, the lower the ion concentration, the less is the bending strength decrease. These chaotropic cations were all evaluated with the same chaotropic anion: the hydroxyl (OH). Thirdly, this latter chaotropic anion prevailed over the kosmotropic ammonium cation effect. As expected, the anions more effectively influence the H···OH bonds¹⁰. Thus, when a strong kosmotropic anion was used in the curing solution, such as for citrate, less severe reduction was imparted to the mechanical strength.

Nevertheless, the chaotropic behavior, related to the ability to break the hydrogen bonding network of structured water, is not restricted to the ionic solutions. Nonionic substances, such as those studied in this paper (Figure 3), have the same behavior. These include dimethylformamide (DMF), dimethylacetamide (DMA), and acetone (DMK). They have a carbonyl group (C = O) whose chaotropic tendency arises from its competition for Hbonding with the H₂O molecules. In other words, C = O···HOH is more likely to be formed than HOH···HOH. The aqueous solutions of these chaotropic nonionic substances also decreased the bending strength of the Portland cementbased plates, as shown in Table 1. This is further evidence of adhesion through water confined among cementitious surfaces. Nevertheless, two other possible adhesion forces could also be actuating: the attractive van der Waals forces and the capillary ones.

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Van der Waals attractive forces are inversely proportional to the medium dielectric constant (k): the lower the constant, the higher the forces¹⁴. Table 1 shows that all the nonionic chaotropic solutions used in this work have a dielectric constant lower than that of deionized water; conversely, the mechanical strength of the cementitious plates decreased. This further strengthens the evidence that adhesion was determined by the confined water. Additionally, capillary forces depend on the surface tension of the liquid (γ): the lower this parameter, the lower the force¹⁵. The DMF in Table 1 had minor effects on the water surface tension, yet a large influence on the mechanical strength. The others, DMA and DMK, yielded a discrete drop of the water surface tension that cannot be correlated with their effect on the bending strength of Portland cementitious plates. It indicates that their water structurebreaking ability prevails over their capillary force contributions.

4. Conclusions

Understanding the bonding of the hydrated phases of Portland cement is the first step to explore the adhesion in future developments capable of providing new cement materials or, perhaps, new applications for this old one. Although there is a lack of understanding regarding the behavior of ions or molecules to explain how they compete with water molecules near to the hydrated surfaces, this paper has shown the effects of some chaotropic substances (i.e. waterstructure breaker) and how they directly influenced the bending strength of cement plates.

Acknowledgements

Our special thanks to Dr. Eduardo Azevedo (IFSCUSP) by the NMR analysis and to FAPESP and CNPq for supporting the corresponding author with academic research (02/104923 and 151329/20079). The authors also acknowledge Prof. R. Bradt for his comments to this paper.

Received: January 24, 2008; Revised: May 10, 2008

1. Double DD. Cement a respectable material? Nature 1981; 289(5796):348349.
2. Birchall JD, Howard AJ, Kendall K. Flexural strength and porosity of cements. Nature 1981; 289(5796):388389.
3. Richard P, Cheyrezy M. Composition of reactive powder concretes. Cement and Concrete Research 1995; 25(7):15011511.
4. Kendall K. Molecular adhesion and its applications: the sticky universe New York: Kluwer Academic/Plenum Publishers; 2001.
5. Pellenq RJ, Van Damme H. Why does concrete set? Materials Research Society Bulletin 2004; 29(5):319323.
6. Jarvis SP. Adhesion on nanoscale. In: Rosoff M, editor. Nanosurface chemistry New York: Marcel Dekker Inc; 2002. p. 758.
7. Teixeira J, Zanotti JM, BellissentFunel MC, Chen SH. Water in confined geometries. Physica B 1997; 234236:370374.
8. Kalinichev AG, Wang J, Kirkpatrick RJ. Molecular dynamics modeling of the structure, dynamics and energetics of mineralwater interfaces: applications to cement materials. Cement and Concrete Research 2007; 37(3):337347.
9. Padureanu I, Aranghel D, Rotarescu G, Dragolici F, Turcanu C, Kozlov ZA, Semenov VA. An inelastic neutron scattering study of the water dynamics in cement paste. Romanian Journal of Physics 2005; 50(56):561574.
10. Chaplin M. Water structure and behavior[Online]. Avaliable from: <www.lsbu.ac.uk/water/hofmeist.html>
11. Parsegian VA. Hopes for Hofmeister. Nature 1995; 378(6555):335336.
12. Omta AW, Kropman MF, Woutersen S, Bakker HJ. Negligible effect of ions on the hydrogenbond structure in liquid water. Science 2003; 301(5631):347349.
13. Hribar B, Southall NT, Vlachy V, Dill KA. How ions affect the structure of water. Journal of American Chemical Society 2002; 124(41):1230212311.
14. Raghavan SR, Walls HJ, Khan SA. Rheology of silica dispersions in organic liquids: new evidence for solvation forces dictated by hydrogen bonding. Langmuir 2000; 16(21):79207930.
15. Israelachivili J. Intermolecular and surface forces 2^nd ed. London: Academic Press; 1992.

*

email:

hebert@if.sc.usp.br

Publication Dates

Publication in this collection
16 July 2008
Date of issue
June 2008

History

Received
24 Jan 2008
Reviewed
10 May 2008

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Double DD. Cement a respectable material? Nature 1981; 289(5796):348349.

[2] 2. Birchall JD, Howard AJ, Kendall K. Flexural strength and porosity of cements. Nature 1981; 289(5796):388389.

[3] 3. Richard P, Cheyrezy M. Composition of reactive powder concretes. Cement and Concrete Research 1995; 25(7):15011511.

[4] 4. Kendall K. Molecular adhesion and its applications: the sticky universe New York: Kluwer Academic/Plenum Publishers; 2001.

[5] 5. Pellenq RJ, Van Damme H. Why does concrete set? Materials Research Society Bulletin 2004; 29(5):319323.

[6] 6. Jarvis SP. Adhesion on nanoscale. In: Rosoff M, editor. Nanosurface chemistry New York: Marcel Dekker Inc; 2002. p. 758.

[7] 7. Teixeira J, Zanotti JM, BellissentFunel MC, Chen SH. Water in confined geometries. Physica B 1997; 234236:370374.

[8] 8. Kalinichev AG, Wang J, Kirkpatrick RJ. Molecular dynamics modeling of the structure, dynamics and energetics of mineralwater interfaces: applications to cement materials. Cement and Concrete Research 2007; 37(3):337347.

[9] 9. Padureanu I, Aranghel D, Rotarescu G, Dragolici F, Turcanu C, Kozlov ZA, Semenov VA. An inelastic neutron scattering study of the water dynamics in cement paste. Romanian Journal of Physics 2005; 50(56):561574.

[10] 10. Chaplin M. Water structure and behavior[Online]. Avaliable from: <www.lsbu.ac.uk/water/hofmeist.html>

[11] 11. Parsegian VA. Hopes for Hofmeister. Nature 1995; 378(6555):335336.

[12] 12. Omta AW, Kropman MF, Woutersen S, Bakker HJ. Negligible effect of ions on the hydrogenbond structure in liquid water. Science 2003; 301(5631):347349.

[13] 13. Hribar B, Southall NT, Vlachy V, Dill KA. How ions affect the structure of water. Journal of American Chemical Society 2002; 124(41):1230212311.

[14] 14. Raghavan SR, Walls HJ, Khan SA. Rheology of silica dispersions in organic liquids: new evidence for solvation forces dictated by hydrogen bonding. Langmuir 2000; 16(21):79207930.

[15] 15. Israelachivili J. Intermolecular and surface forces 2^nd ed. London: Academic Press; 1992.

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Chaotropic substances and their effects on the mechanical strength of Portland cement-based materials

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