Your search keyword '"Al-Tabbaa, Abir [0000-0002-5746-6886]"' showing total 5 results

1. Biobased Acrylate Shells for Microcapsules Used in Self-Healing of Cementitious Materials

Author

Souza, Lívia Ribeiro De, Whitfield, Briony, Al-Tabbaa, Abir, Souza, LRD [0000-0002-0241-2880], Al-Tabbaa, A [0000-0002-5746-6886], Apollo - University of Cambridge Repository, Souza, Lívia Ribeiro de [0000-0002-0241-2880], Al-Tabbaa, Abir [0000-0002-5746-6886], and Ribeiro De Souza, Livia [0000-0002-0241-2880]

Subjects

microcapsules, Renewable Energy, Sustainability and the Environment, Geography, Planning and Development, biobased acrylates, microfluidics, self-healing, Building and Construction, Management, Monitoring, Policy and Law, Article

Abstract

Peer reviewed: True, To facilitate the ongoing transition towards carbon neutrality, the use of renewable materials for additive manufacturing has become increasingly important. Here we report for the first time the fabrication of microcapsules from biobased acrylate shells using microfluidics. To select the shell, a wide range of biobased acrylates disclosed in the literature was considered according to their tensile strength, ductile transition temperature and global availability. Once acrylate epoxidised soybean oil (AESO) was selected, its viscosity was adjusted to valuables suitable for the microfluidic device using two different diluting agents. Double emulsions were successfully produced using microfluidics, followed by photopolymerisation of the shell and characterisa-tion of the capsules. Microcapsules containing AESO and isobornyl acrylate (IBOA) were pro-duced with an outer diameter ~ 490 μm, shell thickness ranging between 36 and 67 μm, and production rates around 2.4 g/h. The mechanical properties of the shell were characterised as tensile strength of 29.2 ± 7.7 MPa, Young’s modulus of 1.7±0.4 GPa and the ductile transition temperature was estimated as 42°C. To investigate physical triggering, microcapsules produced with a size of 481 ± 4 μm and with a measured shell thickness around 6 μm were embedded in the cementitious matrix. The triggered shells were observed with scanning electron microscopy (SEM) and the uniform distribution of the capsules in cement paste was confirmed using X-ray computed tomography (XCT). These advances can facilitate the wide application of biobased resins for the fabrication of microcapsules for self-healing in cementitious materials., Aspects of this work reported here was carried out as part of an MEng research project by the second author [35]. The authors also acknowledge the financial support provided to the first au-thor from the UKRI-EPSRC, grant number EP/P02081X/1 (Resilient Materials 4 Life, RM4L).

Published

2022

2. Carbon Nanofibers Grown in CaO for Self-Sensing in Mortar

Author

De Souza, Lívia Ribeiro, Pimentel, Matheus, Milone, Gabriele, Tristão, Juliana Cristina, Al-Tabbaa, Abir, de Souza, Lívia Ribeiro [0000-0002-0241-2880], Pimentel, Matheus [0000-0002-5081-4016], Milone, Gabriele [0000-0003-1131-5828], Al-Tabbaa, Abir [0000-0002-5746-6886], and Apollo - University of Cambridge Repository

Subjects

carbon nanofibers, General Materials Science, piezoresistivity, self-sensing, CVD

Abstract

Intelligent cementitious materials integrated with carbon nanofibers (CNFs) have the potential to be used as sensors in structural health monitoring (SHM). The difficulty in dispersing CNFs in cement-based matrices, however, limits the sensitivity to deformation (gauge factor) and strength. Here, we synthesise CNF by chemical vapour deposition on the surface of calcium oxide (CaO) and, for the first time, investigate this amphiphilic carbon nanomaterial for self-sensing in mortar. SEM, TEM, TGA, Raman and VSM were used to characterise the produced CNF@CaO. In addition, the electrical resistivity of the mortar, containing different concentrations of CNF with and without CaO, was measured using the four-point probe method. Furthermore, the piezoresistive response of the composite was quantified by means of compressive loading. The synthesised CNF was 5-10 μm long with an average diameter of ~160 nm, containing magnetic nanoparticles inside. Thermal decomposition of the CNF@CaO compound indicated that 26% of the material was composed of CNF; after CaO removal, 84% of the material was composed of CNF. The electrical resistivity of the material drops sharply at concentrations of 2% by weight of CNF and this drop is even more pronounced for samples with 1.2% by weight of washed CaO. This indicates a better dispersion of the material when the CaO is removed. The sensitivity to deformation of the sample with 1.2% by weight of CNF@CaO was quantified as a gauge factor (GF) of 1552, while all other samples showed a GF below 100. Its FCR amplitude can vary inversely up to 8% by means of cyclic compressive loading. The method proposed in this study provides versatility for the fabrication of carbon nanofibers on a tailored substrate to promote self-sensing in cementitious materials., This work is supported by UKRI-EPSRC (Grant No. EP/P02081X/1, Resilient Materials 4 Life, RM4L) and by CAPES (grant no. 88887.653331/2021-00).

Published

2022

3. SEBS-Polymer-Modified Slag–Cement–Bentonite for Resilient Slurry Walls

Author

Benyi Cao, Yunhui Zhang, Abir Al-Tabbaa, Cao, Benyi [0000-0003-1885-7152], Apollo - University of Cambridge Repository, Zhang, Yunhui [0000-0001-7134-1951], and Al-Tabbaa, Abir [0000-0002-5746-6886]

Subjects

cut-off, slurry wall, Renewable Energy, Sustainability and the Environment, SEBS, Geography, Planning and Development, cement–bentonite, slag, self-healing, resilient materials, cement-bentonite, Management, Monitoring, Policy and Law

Abstract

In spite of the well-established design and construction approaches of slag–cement–bentonite slurry walls, the materials deteriorate inevitably in contaminated land. The development of effective materials which are sustainable, resilient and self-healing over the lifetime of slurry walls becomes essential. This study, for the first time, adopts a styrene–ethylene/butylene–styrene (SEBS) polymer to modify slag–cement–bentonite materials to enhance mechanical and self-healing performance. The results show that the increase in SEBS dosage results in significantly increased strain at failure, indicating the enhanced ductility thanks to the modification by the deformable polymer. The increased ductility is beneficial as the slurry wall could deform to a greater extent without cracks. After the permeation of liquid paraffin, the SEBS exposed on the crack surface swells and seals the crack, with the post-healing permeability only slightly higher than the undamaged values, which exhibits good self-healing performance. Scanning electron microscopy and micro-computed tomography analyses innovatively reveal the good bonding and homogeneous distribution of SEBS in slag–cement–bentonite. SEBS acts as a binder to protect the slag–cement–bentonite sample from disintegration, and the swollen SEBS particles effectively seal and heal the cracks. These results demonstrate that the SEBS-modified slag–cement–bentonite could provide slurry walls with resilient mechanical properties and enhanced self-healing performance.

Published

2022

4. A novel membrane emulsification technique for microencapsulation in self-healing concrete: development and proof of concept

Author

David Palmer, Abir Al-Tabbaa, Chrysoula Litina, Litina, Chrysoula [0000-0002-8020-7524], Al-Tabbaa, Abir [0000-0002-5746-6886], and Apollo - University of Cambridge Repository

Subjects

Paper, dispersion cell, Materials science, sodium silicate, General Engineering, Nanotechnology, Sodium silicate, membrane emulsification, microcapsules, chemistry.chemical_compound, chemistry, Proof of concept, self-healing concrete, Self-healing, UV polymerisation, Membrane emulsification, 40 Engineering

Abstract

Membrane emulsification is a promising new technique that can be deployed as a scalable modular conduit for the consistent and continuous production of single and complex emulsions. This work reports on the development of a manufacturing platform based on membrane emulsification for the first time for microcapsule-based self-healing cementitious materials. The feasibility of single and double emulsion production with wall formation as a secondary step through UV radical polymerisation was explored using a discrete membrane emulsification dispersion cell. The operational parameters (pressure, dispersed phase flux, temperature, shear rate) were established for the specific phase characteristics (viscosity, density, interfacial tension) to achieve control of emulsion droplets and maintain a high encapsulation of core content (high payload). Microcapsules with sodium silicate core and an average diameter of ∼130 μm were produced. Microcapsules were shown to achieve high payload (∼89%). Moreover their thermal stability was characterised and their release performance in the cementitious matrix established. The results demonstrated the capability of membrane emulsification to produce microcapsules with an aqueous core for use in self-healing of cementitious materials.

Published

2021

5. Addressing the need for standardization of test methods for self-healing concrete: an inter-laboratory study on concrete with macrocapsules

Author

Van Mullem, Tim, Anglani, Giovanni, Dudek, Marta, Vanoutrive, Hanne, Bumanis, Girts, Litina, Chrysoula, Kwiecień, Arkadiusz, Al-Tabbaa, Abir, Bajare, Diana, Stryszewska, Teresa, Caspeele, Robby, Van Tittelboom, Kim, Jean-Marc, Tulliani, Gruyaert, Elke, Antonaci, Paola, De Belie, Nele, Van Mullem, Tim [0000-0003-0657-8893], Anglani, Giovanni [0000-0003-1656-6319], Dudek, Marta [0000-0003-0658-6922], Vanoutrive, Hanne [0000-0003-0356-8307], Bumanis, Girts [0000-0002-6617-0120], Litina, Chrysoula [0000-0002-8020-7524], Kwiecień, Arkadiusz [0000-0002-6169-5585], Al-Tabbaa, Abir [0000-0002-5746-6886], Bajare, Diana [0000-0002-3250-5594], Stryszewska, Teresa [0000-0003-1984-4425], Caspeele, Robby [0000-0003-4074-7478], Van Tittelboom, Kim [0000-0002-7718-3189], Jean-Marc, Tulliani [0000-0003-2419-4383], Gruyaert, Elke [0000-0003-0117-2544], Antonaci, Paola [0000-0002-3146-9106], De Belie, Nele [0000-0002-0851-6242], and Apollo - University of Cambridge Repository

Subjects

Waterproofing, Absorption (acoustics), Technology and Engineering, Materials science, Round robin test, 02 engineering and technology, Bending, CRACKS, 010402 general chemistry, 01 natural sciences, water permeability, self-healing concrete, Focus on Self-Healing Materials, mental disorders, ABSORPTION, WATER, General Materials Science, Composite material, SUPERABSORBENT POLYMERS, Materials of engineering and construction. Mechanics of materials, REPAIR, standardization, CEMENT-BASED MATERIALS, Round robin test, self-healing concrete, standardization, macrocapsules, polyurethane, capillary water absorption, water permeability, active crack width control technique, machine learning, capillary water absorption, 600 Others Self-healing concrete, PERFORMANCE, 021001 nanoscience & nanotechnology, Durability, macrocapsules, 0104 chemical sciences, Permeability (earth sciences), machine learning, polyurethane, Self-healing, TA401-492, VISUALIZATION, active crack width control technique, Mortar, 0210 nano-technology, TP248.13-248.65, Research Article, Biotechnology

Abstract

Development and commercialization of self-healing concrete is hampered due to a lack of standardized test methods. Six inter-laboratory testing programs are being executed by the EU COST action SARCOS, each focusing on test methods for a specific self-healing technique. This paper reports on the comparison of tests for mortar and concrete specimens with polyurethane encapsulated in glass macrocapsules. First, the pre-cracking method was analysed: mortar specimens were cracked in a three-point bending test followed by an active crack width control technique to restrain the crack width up to a predefined value, while the concrete specimens were cracked in a three-point bending setup with a displacement-controlled loading system. Microscopic measurements showed that with the application of the active control technique almost all crack widths were within a narrow predefined range. Conversely, for the concrete specimens the variation on the crack width was higher. After pre-cracking, the self-healing effect was characterized via durability tests: the mortar specimens were tested in a water permeability test and the spread of the healing agent on the crack surfaces was determined, while the concrete specimens were subjected to two capillary water absorption tests, executed with a different type of waterproofing applied on the zone around the crack. The quality of the waterproofing was found to be important, as different results were obtained in each absorption test. For the permeability test, 4 out of 6 labs obtained a comparable flow rate for the reference specimens, yet all 6 labs obtained comparable sealing efficiencies, highlighting the potential for further standardization. ispartof: Science And Technology Of Advanced Materials vol:21 issue:1 pages:661-682 ispartof: location:United States status: Published online

Published

2020