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Low Carbon Cements

A special issue of Materials (ISSN 1996-1944). This special issue belongs to the section "Construction and Building Materials".

Deadline for manuscript submissions: closed (20 July 2022) | Viewed by 35848

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Guest Editor
1. Department of Civil Engineering, Architecture and Georesources, Instituto Superior Técnico, Universidade de Lisboa, 1049-001 Lisboa, Portugal
2. Civil Engineering Research and Innovation for Sustainability (CERIS), University of Lisbon, 1049-001 Lisbon, Portugal
Interests: new building materials; cement-based materials; low-carbon cements; special concretes; sustainability; service life
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Special Issue Information

Dear Colleagues,

Due to its versatility, low cost, and mechanical properties, reinforced concrete is still the most widely used material in the world. However, concrete production and its ever-growing demand has become a source of environmental concerns, since it involves significant depletion of raw materials, landfill disposal of construction and demolition waste, and extensive emission of greenhouse gases. Regarding this last issue, ordinary Portland cement contributes about 80%–90% of the CO2 emissions in concrete production, representing over 5% of annual anthropogenic CO2-equivalent greenhouse gas emissions.

Therefore, it is worldwide recognized that near future cement production has a carbon footprint to match. To this end, various studies have been recently conducted in order to develop more eco-efficient low carbon cements (LCC), implying a significant reduction of the global CO2 emissions.

This Special Issue aims to cover some of the latest developments in low carbon cements, such as belite cements, geopolymers, alkali-activated cements, thermos-activated waste cements, calcium aluminate cements, low-temperature or modified clinkers, blended cements with alternative supplementary cementitious materials, and emerging non-Portland cement clinker-based binders. Therefore, original papers dealing with new advances and challenges in low carbon cements are welcome, namely concerning the production, material properties, hydration, rheology, microstructure, mix design, physical, mechanical, and durability characterization of LCC-based materials, service life assessment, sustainability, testing, modeling, and future trends. Low cement concretes and new carbon capture solutions in order to reduce the CO2 footprint of the cement industry are also within the scope of this Special Issue.

Prof. Dr. José Alexandre Bogas
Guest Editor

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Keywords

  • low carbon cement
  • belite cement
  • geopolymers
  • alkali-activated cement
  • thermo-activated cement
  • calcium aluminate cement
  • sustainability
  • supplementary cementitious materials
  • blended cement
  • carbon capture

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Published Papers (12 papers)

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Research

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15 pages, 1175 KiB  
Article
Life Cycle Assessment of Thermoactivated Recycled Cement Production
by Sofia Real, Vitor Sousa, Inês Meireles, José Alexandre Bogas and Ana Carriço
Materials 2022, 15(19), 6766; https://doi.org/10.3390/ma15196766 - 29 Sep 2022
Cited by 6 | Viewed by 1824
Abstract
The urgent need to tackle the effects of global warming has led to a worldwide compromise and ever-more demanding regulations. In this respect, as an important greenhouse gas emitter, the cement industry has to implement major changes in its production processes to achieve [...] Read more.
The urgent need to tackle the effects of global warming has led to a worldwide compromise and ever-more demanding regulations. In this respect, as an important greenhouse gas emitter, the cement industry has to implement major changes in its production processes to achieve future goals. In this perspective, low-carbon eco-efficient cement, such as the thermoactivated recycled cement from concrete waste (RCC), seem to be a promising alternative to current carbon-intensive binders, such as ordinary Portland cement (OPC). This study aimed to demonstrate the potential contribution of RCC to the reduction in the environmental impacts of the cement industry, by means of a comparative life cycle assessment of three production methods of this binder (wet (WM), dry (DM) and air clean (ACM) methods) and OPC. Overall, RCC WM did not turn out to be a good alternative to OPC, essentially owing to the amount of fuel and electricity required for washing and drying the particles before the magnetic separation. On the other hand, RCC DM and RCC ACM proved to be promising alternatives to RCC WM and OPC, with a relevant reduction in all impact categories. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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16 pages, 2105 KiB  
Article
Parametric Study towards Optimization of a Short Duration Carbonation Process of Recycled Cement Paste
by André Silva, Rita Nogueira, Alexandre Bogas, Dariusz Wawrzyńczak, Aleksandra Ściubidło and Izabela Majchrzak-Kucęba
Materials 2022, 15(19), 6513; https://doi.org/10.3390/ma15196513 - 20 Sep 2022
Cited by 3 | Viewed by 1355
Abstract
The recycling process of concrete originates a byproduct, cement paste powder (CPP), which is a material composed mainly of hydrated cement. This cementitious material has demonstrated promising results when applied as a binder in new concrete batches, provided it has been subjected to [...] Read more.
The recycling process of concrete originates a byproduct, cement paste powder (CPP), which is a material composed mainly of hydrated cement. This cementitious material has demonstrated promising results when applied as a binder in new concrete batches, provided it has been subjected to a previous carbonation process. One of the obstacles to the industrial application of this strategy is the long duration of the typical carbonation process, which requires from 3 to 28 days. Recently, the authors have developed a short two-hour carbonation process and thoroughly analysed it over its entire extension. In this paper, a parametric analysis of the carbonation process is performed towards CO2 uptake maximization, aiming to increase the feasibility of its short duration. CO2 uptake is evaluated using the ignition by furnace method and thermogravimetric analysis. Among the parameters considered, the initial water content and the CPP thickness present the highest impact on CO2 uptake. The investigation of different CO2 concentrations inside the carbonation chamber showed that the maximum CO2 uptake does not occur for the highest concentration value. Moreover, a minimum resident time for the forced carbonation of CPP in industrial contexts is presented, and is found to be highly dependent on the CO2 concentration. The particle size and purity degree of CPP revealed a limited influence on the CO2 uptake achieved. Additionally, this paper provides further insight into the mechanisms involved in the carbonation of mature cement paste while increasing the feasibility of our recently proposed short duration carbonation process. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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16 pages, 2465 KiB  
Article
Valorisation of Recycled Cement Paste: Feasibility of a Short-Duration Carbonation Process
by André Silva, Rita Nogueira, Alexandre Bogas, João Abrantes, Dariusz Wawrzyńczak, Aleksandra Ściubidło and Izabela Majchrzak-Kucęba
Materials 2022, 15(17), 6001; https://doi.org/10.3390/ma15176001 - 30 Aug 2022
Cited by 4 | Viewed by 1733
Abstract
Cement paste powder (CPP) is a by-product of the recycling process of concrete with an elevated carbonation capability and potential to be recycled as a binding material in new concrete batches. The application of a carbonation treatment to CPP improves this potential even [...] Read more.
Cement paste powder (CPP) is a by-product of the recycling process of concrete with an elevated carbonation capability and potential to be recycled as a binding material in new concrete batches. The application of a carbonation treatment to CPP improves this potential even more, besides the evident gains in terms of CO2 net balance. However, the long duration usually adopted in this treatment, from 3 to 28 days, hampers the industrial viability of the process. We studied the feasibility of a short-duration carbonation process, with a duration of two hours, carrying out a comprehensive characterization of the material throughout the process. The test was performed on CPP with an average initial water content of 16.9%, exposed to a CO2 concentration of 80%. The results demonstrate two main carbonation rates: a rapid growth rate in the first 18 minutes of the process, involving all the calcium-bearing compounds in CPP, and a slow growth rate afterwards, where only C-S-H contributes to the carbonation reaction. During the 2 h carbonation process, the main CPP compounds, calcium silicate hydrate (C-S-H) and calcium hydroxide (CH), reached different carbonation degrees, 31% and 94%, with, however, close CO2 uptake values, 8% and 11%, respectively. Nevertheless, the total CO2 uptake for this process (≈19%) attained values not distant from the values usually obtained in a carbonation of 12 days or more (19–25%). Hence, these findings highlight the blocking role of C-S-H in the carbonation process, indicating that longer carbonation periods are only going to be useful if an effective carbonation of this compound is accomplished. In the present scenario, where CH is the main contributor to the reaction, the reduction in the process duration is feasible. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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16 pages, 5076 KiB  
Article
Influence of Graphene Nanoplates on Dispersion, Hydration Behavior of Sulfoaluminate Cement Composites
by Kai Cui, Jun Chang, Mohanad Muayad Sabri Sabri and Jiandong Huang
Materials 2022, 15(15), 5357; https://doi.org/10.3390/ma15155357 - 3 Aug 2022
Cited by 3 | Viewed by 1858
Abstract
Sulfoaluminate cement (SAC) is a low carbon ecological cement with good durability and is widely used in various projects. In addition, graphene nanoplates (GNPs) have excellent thermal, electrical, and mechanical properties and are excellent nano-filler. However, the hydration behavior of GNPs on SAC [...] Read more.
Sulfoaluminate cement (SAC) is a low carbon ecological cement with good durability and is widely used in various projects. In addition, graphene nanoplates (GNPs) have excellent thermal, electrical, and mechanical properties and are excellent nano-filler. However, the hydration behavior of GNPs on SAC is still unclear. In this paper, the effect of GNPs on SAC hydration was investigated by isothermal calorimetry, and the hydration kinetic model and hydration kinetic equation of SAC was established, explaining the differences in cement hydration processes with and without GNPs on SAC based on a hydration kinetic model. Results indicate that the hydration exotherm of SAC mainly includes five stages: the initial stage, the induction stage, the acceleration stage, the deceleration stage, and the stable stage. The addition of GNPs promoted the hydration exotherm of SAC and accelerated the hydration reaction. Different from the hydration reaction of Portland cement, the hydration reaction of SAC is mainly a diffusion–reaction process. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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18 pages, 7398 KiB  
Article
Analysis of the Possibility of Using Slags from the Thermal Treatment of Municipal Waste as Potential Component of Cement—Case Study
by Monika Czop, Beata Łaźniewska-Piekarczyk and Małgorzata Kajda-Szcześniak
Materials 2021, 14(21), 6491; https://doi.org/10.3390/ma14216491 - 29 Oct 2021
Cited by 4 | Viewed by 1974
Abstract
In Europe there are nearly 500 incinerators. There are over 2000 of them in the world. It is estimated that the combustion of 1 ton (Mg) of waste produces about 250–300 kg of slag. Due to the large amounts of this waste, the [...] Read more.
In Europe there are nearly 500 incinerators. There are over 2000 of them in the world. It is estimated that the combustion of 1 ton (Mg) of waste produces about 250–300 kg of slag. Due to the large amounts of this waste, the construction industry’s demand for raw materials and the reduction of CO2 emissions, research was undertaken to use slags as a cement component. The problem was complex because slags generated in the thermal treatment of municipal waste have different chemical compositions and physical properties and contain variable amounts of impurities. The choice of chemical analyses of slag was dictated by the potential influence on the properties of cement mortars. The total moisture of raw slag (4–10%), the bulk density (600–1267 kg/m3) and the specific surface after grinding (over 3000 cm2/g) were determined. The pH (11.9) and the content of sulphates (3.5% by weight), chlorides (0.3% by weight) and selected heavy metals (Cd, Cu, Fe, Mn, Zn, Pb) were measured in the aqueous extract. The obtained results of the washing test were compared with the values resulting from the currently binding legal regulations. In the next step, cement mortars with 30% addition of tested slags were designed and made. The article presents the results of compressive strength tests, which were compared with the results of samples without the addition of slag. The addition of slag to the cement mortar decreased S_MSWI 1 by 64% and S_MSWI 2 by 31%. The high loss of strength and the swelling of the S_MSWI 1 test led to the activation of the NaOH slag. In the endurance test, an increase from 16 to 32 MPa was recorded. Preliminary studies show that the addition of slag in the cement mortar allows obtaining the strength at the level of 30–32 MPa. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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26 pages, 7982 KiB  
Article
Investigation of the Effect of Mixing Time on the Mechanical Properties of Alkali-Activated Cement Mixed with Fly Ash and Slag
by Taewan Kim and Choonghyun Kang
Materials 2021, 14(9), 2301; https://doi.org/10.3390/ma14092301 - 29 Apr 2021
Cited by 3 | Viewed by 1963
Abstract
This is an experiment on the effect of mixing time for alkali-activated cement (AAC) using a binder mixed with ground granulated blast furnace slag (slag) and fly ash (FA) in a ratio of 1:1 on the mechanical properties. The mixing method of ASTM [...] Read more.
This is an experiment on the effect of mixing time for alkali-activated cement (AAC) using a binder mixed with ground granulated blast furnace slag (slag) and fly ash (FA) in a ratio of 1:1 on the mechanical properties. The mixing method of ASTM C305 was used as the basic mixing method, and the following mixing method was changed. Simply adding the same mixing time and procedure, the difference in the order of mixing slag and FA, and controlling the amount of activator and mixed water were considered. As a result of the experiment, the addition of the same mixing time and procedure, pre-injection of slag, and high-alkali mixed water in which half of the activator and mixing water were mixed showed the highest mechanical properties and a dense pore structure. As a result, the design of a blending method that can promote the activation action of slag rather than FA at room temperature was effective in improving the mechanical properties of AAC. In addition, these blending factors showed a clearer effect as the concentration of the activator increased. Through the results of this experiment, it was shown that high-temperature curing, high fineness of the binder, or even changing the setting of the mixing method without the use of excessive activators can lead to an improvement of mechanical properties. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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18 pages, 7406 KiB  
Article
Influence of Particle Morphology of Ground Fly Ash on the Fluidity and Strength of Cement Paste
by Juntao Ma, Daguang Wang, Shunbo Zhao, Ping Duan and Shangtong Yang
Materials 2021, 14(2), 283; https://doi.org/10.3390/ma14020283 - 7 Jan 2021
Cited by 40 | Viewed by 2958
Abstract
The grinding process has become widely used to improve the fineness and performance of fly ash. However, most studies focus on the particle size distribution of ground fly ash, while the particle morphology is also an important factor to affect the performance of [...] Read more.
The grinding process has become widely used to improve the fineness and performance of fly ash. However, most studies focus on the particle size distribution of ground fly ash, while the particle morphology is also an important factor to affect the performance of cement paste. This article aims at three different kinds of ground fly ash from the ball mill and vertical mill, and the particle morphology is observed by scanning electron microscopy (SEM) to calculate the spherical destruction (the ratio of spherical particles broken into irregular particles in the grinding process of fly ash), which provides a quantification of the morphology change in the grinding process. The fluidity of cement paste and the strength of cement mortar are tested to study the relation of spherical destruction and fluidity and strength. The results show that the spherical destruction of ground fly ash in a ball mill is more than 80% and that in a vertical mill with a separation system is only 11.9%. Spherical destruction shows a significant relation with the fluidity. To different addition of ground fly ash, the fluidity of cement paste decreases with the increase of spherical destruction. To the strength of cement paste, particle size distribution and spherical destruction are both the key factors. Therefore, spherical destruction is an important measurement index to evaluate the grinding effect of the fly ash mill. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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15 pages, 2607 KiB  
Article
Portland Cements with High Content of Calcined Clay: Mechanical Strength Behaviour and Sulfate Durability
by Carlos H. Aramburo, César Pedrajas and Rafael Talero
Materials 2020, 13(18), 4206; https://doi.org/10.3390/ma13184206 - 22 Sep 2020
Cited by 14 | Viewed by 3297
Abstract
Calcined clay has become the supplementary cementitious materials with the greatest potential to reduce the clinker/cement. In this research, the mechanical strengths and sulphate resistance of blended cements with a high content of calcined clay as a pozzolanic addition were evaluated to demonstrate [...] Read more.
Calcined clay has become the supplementary cementitious materials with the greatest potential to reduce the clinker/cement. In this research, the mechanical strengths and sulphate resistance of blended cements with a high content of calcined clay as a pozzolanic addition were evaluated to demonstrate that these cements could be designed as CEM (cement) type IV/A-SR and IV/B-SR cements by the current European standard UNE-EN 197-1: 2011. The blended cements were prepared by two Portland cements (P1 and PY6) with different mineralogical compositions and a calcined clay. The level of replacement was greater than 40% by weight. The results obtained confirm the decrease in the mechanical strengths and the increase in the sulfate resistance of the two Portland cements when they are replaced by calcined clay at a level of replacement greater than 40%. These results are a consequence of the chemical effect from the pozzolanic activity of the calcined clay. Therefore, there is an important decrease in portlandite levels of paste liquid phase that causes the increase in sulfate resistance and the decrease of the mechanical strengths. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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33 pages, 11506 KiB  
Article
Influence of the Treatment Temperature on the Microstructure and Hydration Behavior of Thermoactivated Recycled Cement
by Sofia Real, Ana Carriço, José Alexandre Bogas and Mafalda Guedes
Materials 2020, 13(18), 3937; https://doi.org/10.3390/ma13183937 - 5 Sep 2020
Cited by 51 | Viewed by 3624
Abstract
This paper intends to contribute to a better knowledge of the production and rehydration of thermoactivated recycled cement and its incorporation in cement-based materials. To this end, the influence of the treatment temperature on the properties of recycled cements and recycled cement pastes [...] Read more.
This paper intends to contribute to a better knowledge of the production and rehydration of thermoactivated recycled cement and its incorporation in cement-based materials. To this end, the influence of the treatment temperature on the properties of recycled cements and recycled cement pastes was assessed by means of a wide array of tests. Anhydrous recycled cement as well as the resulting pastes were characterized through density and particle size, water demand and setting time, thermogravimetry, X-ray diffraction, field emission gun scanning electron microscopy, isothermal calorimetry, 29Si nuclear magnetic resonance spectroscopy, flowability, mechanical strength, mercury intrusion porosimetry and scanning electron microscopy. The treatment temperature had a significant influence on the dehydration and hydration of recycled cement, essentially resulting in the formation of C2S polymorphs of varying reactivity, which led to pastes of different fresh and hardened behaviors. The high water demand and the pre-hydration of recycled cement resulted in high setting times and low compressive strengths. The highest mechanical strength was obtained for a treatment temperature of 650 °C. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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29 pages, 10048 KiB  
Article
Durability and Time-Dependent Properties of Low-Cement Concrete
by Keila Robalo, Eliana Soldado, Hugo Costa, Luís Carvalho, Ricardo do Carmo and Eduardo Júlio
Materials 2020, 13(16), 3583; https://doi.org/10.3390/ma13163583 - 13 Aug 2020
Cited by 20 | Viewed by 3249
Abstract
The sustainability concerns of concrete construction are focused both on the materials’ eco-efficiency and on the structures’ durability. The present work focuses on the characterization of low cement concrete (LCC), regarding time-dependent and durability properties. LCC studies which explore the influence of the [...] Read more.
The sustainability concerns of concrete construction are focused both on the materials’ eco-efficiency and on the structures’ durability. The present work focuses on the characterization of low cement concrete (LCC), regarding time-dependent and durability properties. LCC studies which explore the influence of the formulation parameters, such as the W/C (water/cement ratio), W/Ceq, (which represents the mass ratio between water and equivalent cement), W/B (water/binder) ratio, and the reference curves, on the aforementioned properties are limited. Thus, several LCC mixtures were formulated considering two dosages of binder powder, 350 and 250 kg/m3, the former with very plastic consistency and the latter with dry consistency, which were combined with a large spectrum of cement replacement rates (up to 70%), through adding fly ash and limestone filler, and with different compactness levels. The main objectives were to study the influence of the formulation parameters on the properties: shrinkage and creep, accelerated carbonation and water absorption, by capillarity, and by immersion. The lifetime of structures produced with the studied LCC was estimated, considering the durability performance, regarding the carbonation effect on the possible corrosion of the steel reinforcement. LCC mixtures with reduced cement dosage and high compactness, despite the high W/C ratios, have low shrinkage and those with higher strength have reduced creep, however depending on W/Ceq ratio. Those mixtures can be formulated and produced presenting good performance regarding carbonation resistance and, consequently, a long lifetime, which is mandatory for a sustainable construction. LCC with 175 kg/m3 of cement dosage is an example with higher lifetime than current concrete with 250 kg/m3 of cement; depending on the XC exposure classes (corrosion induced by carbonation), the amount of cement can be reduced between 37.5% and 42%, since the LCC with 175 kg/m3 of cement allows reducing the concrete cover below the minimum recommended, ensuring simultaneously the required lifetime for current and special structures. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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Review

Jump to: Research

29 pages, 4600 KiB  
Review
Palm Oil Fuel Ash-Based Eco-Friendly Concrete Composite: A Critical Review of the Long-Term Properties
by Mugahed Amran, Yeong Huei Lee, Roman Fediuk, Gunasekaran Murali, Mohammad Ali Mosaberpanah, Togay Ozbakkaloglu, Yee Yong Lee, Nikolai Vatin, Sergey Klyuev and Maria Karelia
Materials 2021, 14(22), 7074; https://doi.org/10.3390/ma14227074 - 22 Nov 2021
Cited by 26 | Viewed by 5176
Abstract
Rapid global infrastructural developments and advanced material science, amongst other factors, have escalated the demand for concrete. Cement, which is an integral part of concrete, binds the various individual solid materials to form a cohesive mass. Its production to a large extent emits [...] Read more.
Rapid global infrastructural developments and advanced material science, amongst other factors, have escalated the demand for concrete. Cement, which is an integral part of concrete, binds the various individual solid materials to form a cohesive mass. Its production to a large extent emits many tons of greenhouse gases, with nearly 10% of global carbon (IV) oxide (CO2) emanating from cement production. This, coupled with an increase in the advocacy for environmental sustainability, has led to the development of various innovative solutions and supplementary cementitious materials. These aims to substantially reduce the overall volume of cement required in concrete and to meet the consistently increasing demand for concrete, which is projected to increase as a result of rapid construction and infrastructural development trends. Palm oil fuel ash (POFA), an industrial byproduct that is a result of the incineration of palm oil wastes due to electrical generation in power plants has unique properties, as it is a very reactive materials with robust pozzolanic tendencies, and which exhibits adequate micro-filling capabilities. In this study, a review on the material sources, affecting factors, and durability characteristics of POFA are carefully appraised. Moreover, in this study, a review of correlated literature with a broad spectrum of insights into the likely utilization of POFA-based eco-friendly concrete composites as a green material for the present construction of modern buildings is presented. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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24 pages, 2593 KiB  
Review
Incorporation of Alkali-Activated Municipal Solid Waste Incinerator Bottom Ash in Mortar and Concrete: A Critical Review
by Rawaz Kurda, Rui Vasco Silva and Jorge de Brito
Materials 2020, 13(15), 3428; https://doi.org/10.3390/ma13153428 - 3 Aug 2020
Cited by 29 | Viewed by 4676
Abstract
In the light of one of the most common waste management issues in urban areas, namely the elimination of municipal solid waste (MSW; about 486 kg of the waste per capita were generated in the EU in 2017), this study discusses one technique [...] Read more.
In the light of one of the most common waste management issues in urban areas, namely the elimination of municipal solid waste (MSW; about 486 kg of the waste per capita were generated in the EU in 2017), this study discusses one technique as an outlet in the construction industry for the by-product of the waste’s incineration in energy recovery facilities (i.e., MSW incinerator bottom ash—MIBA). There have been some investigations on the use of MIBA as partial replacement of cement to be used in cementitious composites, such as concrete and mortars. However, the waste’s incorporation ratio is limited since further products of hydration may not be produced after a given replacement level and can lead to an unsustainable decline in performance. In order to maximize the incorporation of MIBA, some research studies have been conducted on the alkali activation of the waste as precursor. Thus, this study presents an extensive literature review of the most relevant investigations on the matter to understand the material’s applicability in construction. It analyses the performance of the alkali-activated MIBA as paste, mortar, and concrete from different perspectives. This literature review was made using search engines of several databases. In each database, the same search options were repeated using combinations of various representative keywords. Furthermore, several boundaries were made to find the most relevant studies for further inspection. The main findings of this review have shown that the chemical composition and reactivity of MIBA vary considerably, which may compromise performance comparison, standardization and commercialization. There are several factors that affect the performance of the material that need to be considered, e.g., type and content of precursor, alkaline activator, curing temperature and time, liquid to solid ratio, among others. MIBA-based alkali-activated materials (AAM) can be produced with a very wide range of compressive strength (0.3–160 MPa). The main factor affecting the performance of this precursor is the existence of metallic aluminum (Al), which leads to damaging expansive reactions and an increase in porosity due to hydrogen gas generation stemming from the reaction with the alkaline activator. Several approaches have been proposed to eliminate this issue. The most effective solution was found to be the removal of Al by means of eddy current electromagnetic separation. Full article
(This article belongs to the Special Issue Low Carbon Cements)
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