Providing people with affordable housing of good quality is a global challenge. This need justifies the extensive research in this field in both developing and developed countries (Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014). In the past, this sector relied on the use of natural materials, including earthen materials (Fabbri et al., 2018; Elavarasan et al., Reference Elavarasan, Priya, Raja Gurusamy, Mohamed RiyasNaveeth and Natesh2021) which were used because of their abundance and low cost and minimal energy requirement (Gallipoli et al., Reference Gallipoli, Bruno, Perlot and Mendes2017; Hadji et al., Reference Hadji, Ihaddadene, Ihaddadene, Betga, Charick and Logerais2020). The use of earthen materials often combines various construction techniques and standards. These include rammed earth, cob, stucco, adobe, CEBs and terracotta (Dos Santos et al., Reference Dos Santos, Librelotto and Jacintho2014; Van Damme & Houben, Reference Van Damme and Houben2018). Unfortunately, these construction products are all sensitive to water and show limited strength. As a result, their durability is poor (Elavarasan et al., Reference Elavarasan, Priya, Raja Gurusamy, Mohamed RiyasNaveeth and Natesh2021; Benzerara et al., Reference Benzerara, Guihéneuf, Belouettar and Perrot2021). The poor durability combined with poor mastery of building techniques, as well as disputes over procedures and standards for assessing earth construction performances, have led to the replacement of the earthen materials by industrial materials, such as concrete, steel, wood and synthetic materials (Fabbri et al., Reference Fabbri, Morel and Gallipoli2018; Elavarasan et al., Reference Elavarasan, Priya, Raja Gurusamy, Mohamed RiyasNaveeth and Natesh2021). However, wood construction has a large environmental impact through deforestation and concrete, steel and synthetic constructions are major causes of carbon emission (Giada et al., Reference Giada, Caponetto and Nocera2019; Benzerara et al., Reference Benzerara, Guihéneuf, Belouettar and Perrot2021; Belarbi et al., Reference Belarbi, Sawadogo, Poullain, Issaadi, Hamami, Bonnet and Belarbi2022). In addition, construction using these industrial materials entails significant energy consumption (Giada et al., Reference Giada, Caponetto and Nocera2019; Hadji et al., Reference Hadji, Ihaddadene, Ihaddadene, Betga, Charick and Logerais2020; Belarbi et al., Reference Belarbi, Sawadogo, Poullain, Issaadi, Hamami, Bonnet and Belarbi2022). However, in the current context of sustainable development, energy supply is pivotal. Improvement is needed, especially in developing countries (Kaygusuz, Reference Kaygusuz2012). Buildings that are sustainable, ecological and cost-effective bring focus to issues of material selection and processing. A return to the use of earth in the building industry is becoming a topic of interest for building improvement (Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014; Fabbri et al., Reference Fabbri, Morel and Gallipoli2018; Okewale & Grobler, Reference Okewale and Grobler2022). Earthen constructions provide much better comfort for residents through thermal insulation (Zhang et al., Reference Zhang, Gustavsen, Jelle, Yang, Gao and Wang2017). The need to guarantee mechanical performance and consequently, durability, is crucial (Giada et al., Reference Giada, Caponetto and Nocera2019; Benzerara et al., Reference Benzerara, Guihéneuf, Belouettar and Perrot2021). Numerous studies have been carried out on improving the thermal and mechanical performances of earthen constructions. Earth-earth, earth-cement, earth-fly ash, earth-gypsum, earth-plant fibers and even earth-geopolymer mixtures increase the mechanical performances of the resulting bricks. Thermal performances remain similar to those of CEBs (Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014; Zhang et al., Reference Zhang, Gustavsen, Jelle, Yang, Gao and Wang2017; Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018; Van Damme & Houben, Reference Van Damme and Houben2018; Elavarasan et al., Reference Elavarasan, Priya, Raja Gurusamy, Mohamed RiyasNaveeth and Natesh2021; Hadji et al., Reference Hadji, Ihaddadene, Ihaddadene, Betga, Charick and Logerais2020; Belarbi et al., Reference Belarbi, Sawadogo, Poullain, Issaadi, Hamami, Bonnet and Belarbi2022). In addition if additives to earthen block formulation improve their mechanical performance, this is achieved through heat treatment, which also affects the thermal performance (Bourret et al., Reference Bourret, Tessier-Doyen, Guinebretiere, Joussein and Smith2015; Debnath et al., Reference Debnath, Pabbisetty, Sarkar, Singh, Majhi and Singh2022). The intrinsic characteristics of each soil affect the performance irrespective of treatment. The present study aimed to compare the mechanical and thermal performances of cement- or heat-stabilized blocks using statistical analysis. The proposed comparison may help to identify the factors that affect the insulation behaviour and/or the mechanical response of the stabilized CEB and thus justify decisions about the type of stabilized CEB to be used with respect to the performance required or the environment in which the building is to be placed and its ultimate use. The physical and thermal parameters of specimens and their mechanical responses were evaluated. Statistical tools are used for a better understanding of the performance differences and the identification of the factors affecting the performance of the materials.
Materials and analytical methods
Materials
Five alluvial clayey samples named MN11, MN14, MN22, BP1 and BM2 were collected along the Mbam River bank in Central Africa. This area is located between 10°58’30’’–11°20’30’’ East longitude and between 4°40’30’’–5°01’15’’ North latitude. Approximately 70 kg of each sample was collected in polyethylene bags for laboratory testing. Portland cement, CEM II class 42.5 R (NF EN 197-1), was used to improve the mechanical performance of raw specimens. This is a commonly used hydraulic binder in building materials and is composed of ~65% Portland clinker and ~35% other constituents.
Analytical methods
X-ray diffraction and X-ray fluorescence spectroscopy
The mineralogical and the major-element compositions of the materials studied were determined by X-ray diffraction (XRD) and X-ray fluorescence (XRF), respectively, at the University of Liège, Belgium. The XRD was performed with a Bruker D8 Advance Eco diffractometer, using Cu-Kα radiation (λ = 1.5418 Å) at 40 kV and 30 mA. The powder XRD patterns were recorded over the range 2–70°2θ with a scanning step size of 1°2θ/min. The XRF analysis was conducted on fusion beads prepared at 1100°C, after diluting in lithium tetraborate flux at a 5:1 sample:flux ratio.
Semi-quantitative analysis
The mineralogical assemblage from non-oriented powder XRD was coupled to the chemical analysis of major elements for a semi-quantitative estimation of minerals present using Equation 1 proposed by Yvon et al. (Reference Yvon, Lietard and Cases1982).
where T(x) = percentage of oxide of chemical element x; Mi = percentage of mineral i in the sample containing the chemical element x; Pi(x) = proportion of element xoxide in mineral i (calculated from the ideal mineral formula of the mineral being considered).
For the calculation, the following assumptions were adopted. The Fe2O3 was attributed to hematite or goethite; K2O was assigned to orthoclase and TiO2 to rutile; Al2O3 was distributed in orthoclase and kaolinite; and the SiO2 was distributed between orthoclase, kaolinite and quartz.
Briquette preparation, physico-mechanical and thermal characterization
Mechanical tests for flexural (σf) and compressive (σc) strengths were performed on test briquettes with dimensions of 80 mm × 40 mm × 20 mm and 40 × 40 × 40 mm. For thermal tests, 100 mm × 100 mm × 20 mm briquettes were used. To process these briquettes, the raw clays were oven-dried at 105°C for 24 h, then ground manually with a porcelain mortar, and, finally, sieved over a 1 mm sieve. All the formulations were moistened with 8–18% water on a dry basis for convenient molding before being compressed using a SPECAC laboratory hydraulic press of 10 tons at a load of 1.27 MPa. In the case of clay/cement mix, the clay/cement ratios on a dry basis were 3, 6, 9, 12 and 15wt.%. For the fired samples, the compressed blocks were dried at ambient at temperatures of ~27 ± 1°C for 7 days, then dried at 105°C before firing at 800°C, 900°C, 1000°C and 1100°C in an electric muffle furnace at a firing rate of 5°C/min. Samples were soaked for 2h at each maximum temperature before cooling to room temperature. For clay/cement mixtures, the specimens were cured at room temperature (27± 1°C) for 28 days.
The particle-size distribution of the raw clays was determined by sieving and sedimentation. Sieving was used for the coarse and fine sand fractions, over 200 μm and 80 μm sieve respectively. The Robinson's pipette method was used to assess the silt- and clay-sized fractions.
The dry (ρd) and bulk (ρ) densities of raw clays and test briquettes were determined in accordance with ASTM C373-88. The linear shrinkage (LS) was determined according to the ASTM C326-03 standard. Equation 2 was used for the LS calculation.
Where L 0 is the block length after compaction and L 1 is the length after firing or after room drying for 28 days.
The apparent porosity (n) and the water absorption (WA) were determined according to Equations 3 and 4, respectively (ASTM C373-88).
Where M 1 is the specimen dry mass (g), M 2 is the specimen mass (g) after 24 h of immersion in water and M’ is the mass of the specimen while suspended in water.
The flexural strength (σf) was measured in a three-point bending configuration (ASTM C674-77) on an Instron 5582 press in accordance with Equation 5.
where P = load (N) at the breaking strength; L = distance (mm) between the two basal supports; l = specimen width (mm); h = specimen thickness (m).
The uniaxial compressive strength (σc) test was performed using an Instron servo-hydraulic press, with a capacity of 250 kN. The loading speed was 0.01 MPa/s.
The thermal and mechanical properties were determined on both cement-stabilized and fired specimens. The thermal effusivity (E in JK–1m–2s–1/2), the specific heat capacity (ρc in JK–1m–3), the diffusivity (α in m2s–1) and the conductivity (λ in Wm–1K–1) were determined using the asymmetric hot plate method (Bal et al., Reference Bal, Jannot, Quenette, Chenu and Gaye2012, Reference Bal, Jannot, Gaye and Demeurie2013). A material's thermal effusivity refers to its aptitude to exchange heat with its environment. The greater the value of E, the more the material absorbs energy from its environment (Yan & Song, Reference Yan and Song2021). α is a measure of the rate at which heat energy moves through the material, λ refers to the material's capacity to allow a heat flow to pass through it and ρc is a property that measures the ability of a material to store heat energy. These measurements were carried out in a controlled room temperature (20 ± 1°C). The measurement principle involved the determination of E and ρc, assuming a unidirectional heat transfer at the center of the sample. α and λ were deduced from E and ρc according to Equations 6 and 7.
Statistical analysis
The statistical analysis was performed based on the results obtained from raw materials and on 50 individual samples, of which there were 30 cement-stabilized CEBs and 20 fired specimens. Nineteen variables were assessed. These variables included mineralogical components (quartz– Qz, kaolinite–Kln, hematite–Hem, goethite–Gth, illite–Iltand rutile–Rt), physical parameters (clay, silt, sand, ρ, n, WA and LS), thermal parameters (E, α, λ and ρc) and mechanical parameters (σf and σc). The data was assembled in an Excel™ spreadsheet and then analyzed using the XLSTAT version 14.5.03 software. Correlation tests were carried out to assess relationships between the 19 quantitative variables considered in pairs. The summaries of these tests are represented below using correlation matrixes. Principal Component Analysis (PCA) was also carried out to assess possible relationships linking the 19 quantitative variables. Data from the 30 cement-stabilized CEBs and from the 20 fired specimens were grouped to obtain a single data set. The advantage of this statistical technique is that it synthesizes the information without truncating it. From an ‘n’-dimensional space defined by a ‘p’ number of initial variables, the PCA determines a subspace of smaller dimension by searching for new variables (principal components). These new variables are often linearly independent but explain, at best, all the observations (De Lagarde, Reference De Lagarde1983). Agglomerative Hierarchical Clustering (AHC) (Ward, Reference Ward1963) was executed to perform the PCA. The principle of this other technique is to construct natural groups such that specimens in the same group are similar and those in various groups are dissimilar (Bray & Curtis, Reference Bray and Curtis1957).
Results and discussion
Raw samples physical parameters and mineral and chemical compositions
The studied materials consisted of clay (29.38–55.88%), silt (15.67–27.27%) and sand (20.04–52.59%). In the ternary diagram soil classification (Davis & Bennett, Reference Davis and Bennett1927), the materials are classified as sandy heavy clays (MN14, MN22, BP1 and BM2) and sandy clays (MN11). Using the Winkler diagram of grain-size classification, the samples are suitable for brick manufacturing (Fadil-Djenabou et al., Reference Fadil-Djenabou, Ndjigui and Mbey2015; Ndjigui et al., Reference Ndjigui, Mbey, Fadil-Djenabou, Onana, Bayiga, Enock Embom and Ekosse2021). The dry densities (ρd) are 1.58–1.74 g/cm3 (Table 1), with an average of 1.68 g/cm3. These values are consistent with the clayey nature of the raw materials.
ε = trace.
The XRD traces of the raw clays are presented in Fig. 1. The clays consist of kaolinite, quartz and orthoclase (K-feldspar) as the main phases, associated with hematite/goethite, rutile and traces of anorthite and augite. The main chemical components are SiO2(55.12–71.79%), Al2O3(13.68–20.58%) and Fe2O3(2.8–8.68%). Minor components are TiO2(1.37–1.58%)P2O5(< 0.09%) and total fluxes (MnO, MgO, CaO, Na2O and K2O)(2.61–4. 36%, Table 1). The elemental composition is in accordance with the mineralogical composition from the XRD analysis. Coupling the chemical composition with the mineralogical assemblage, a semi-quantitative evaluation of the mineral composition was performed which led to the following mineral abundances: quartz 27.0–48.3%; kaolinite 26.9–47.8%; orthoclase 8.5–16.7%; hematite/goethite 2.8–8.6%; and rutile 1.4–1.6% (Table 1). The kaolinite contents for all the samples are of interest in terms of their use in construction and building materials. Due to the quartz contents, reduced swelling, shrinkage and cracking in wet or dry states are expected (Gallipoli et al., Reference Gallipoli, Bruno, Perlot and Mendes2017; Van Damme & Houben, Reference Van Damme and Houben2018). Orthoclase and flux contents, at suitable temperatures, favour the vitrification of the fired bodies from the clays.
Cement-stabilized specimens: physical, thermal and mechanical behaviours
The bulk density of cement-stabilized specimens varies with the cement contents (Table 2), ranging between 2.00 and 2.29 g/cm3, which are in the range of bulk densities for cement-stabilized CEB (1.6–2.2 g/cm3) recommended by the International Center for Earthen Architecture (Nshimiyimana et al., Reference Nshimiyimana, Fagel, Messan, Wetshondo and Courard2020). The addition of cement increases the density of all the samples. Although the clay compositions and processing are different, the density evolution observed here is similar to the behaviour of clays reported from Burkina Faso, using calcium carbide residues for stabilization (Nshimiyimana et al., Reference Nshimiyimana, Fagel, Messan, Wetshondo and Courard2020). The calcium carbide, as Portland cement in hydrate mixes, leads to the formation of calcium silicate hydrate (C-S-H) which is the main cause of the observed trend. Optimal values are achieved at 9% (dry basis) for MN14 and BM2. Slightly higher values of densities for specimens made with MN11, MN22 and BP1 are related to quartz contents, which are greater for these samples. In general, the limit value for cement addition to improve density is related to the grain-size distribution and the mineralogy. In the present study, it is assumed that the changes in size distribution after addition of 9% cement are due to the replacement of a significant amount of larger particles, mainly associated with quartz, which have high density. At lower contents (<9%), the increase in density is guided by the integration of smaller cement particles within holes in the agglomerated particles of the clayey sample (Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014).
The linear shrinkage was not measurable, indicating insignificant shrinkage for these specimens. This trend can be associated with the presence of channels through which the excess fluid is drained with almost no displacement of the structural grains. The porosity (n) and water absorption (WA) in all specimens at 0% cement and in specimens based on MN14 and BM2 materials, stabilized at 3 and 6%, were not determined due to the collapse of the specimens after immersion in water. The destruction in water is linked to weak cohesion between the particles of these specimens. This is caused by the abundant clay fraction of these samples (Walker & Stace, Reference Walker and Stace1997; Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014). In specimens in which structures were preserved, the values of n ranged between 16.97 and 23.04%, while WA ranged from 4.02 to 10.99% (Table 2). The WA slightly increased for the MN14 and BM2 samples, while it decreased for the MN11, MN22 and BP1samples with greater cement contents. The porosity reduction in these specimens is linked to the progressive filling of pores by cement, which decreases the WA. Pore filling contributes to matrix reinforcement in specimen structures and to specimen densification (Taallah et al., Reference Taallah, Guettala, Guettala and Kriker2014; Zhang et al., Reference Zhang, Gustavsen, Jelle, Yang, Gao and Wang2017; Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018). Absorbed water is generally stored in pores. As the volume of pores decreases, so does the amount of water that can be absorbed. For MN14 and BM2, n is almost stabilized as a result of addition of 9% cement. This is probably due to the increased cohesion brought on by larger cement particles that agglomerate the clay particles. However, the porosity of these samples (MN14 and BM2) remains higher in comparison to the remaining samples, due to a coarse agglomeration that develops a loose structure within the specimens. In general, a decrease in porosity is registered while an increase in density is observed, which is in line with the observation by Zhang et al. (Reference Zhang, Gustavsen, Jelle, Yang, Gao and Wang2017).
The thermal effusivity (E), diffusivity (α) and conductivity (λ) of cement-stabilized CEB range from 1.15×103 to 1.60×103 JK–1m–2s–1/2, 2.52×10–7 to 1.10×10–6 m2s–1 and 5.56×10–1 to 1.68 Wm–1K–1 respectively. The values of these parameters are minimal in specimens without added cement (0%). They increase with addition of cement (Table 2) and are consistent with the increase in density (Bouguerra et al., Reference Bouguerra, Diop, Laurent, Benmalek and Queneudec1998; Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018). These increases reduce the thermal insulation capability of cement-stabilized specimens. The latter have E values comparable to those of laterite-stabilized products (Meukam et al., Reference Meukam, Jannot, Noumowe and Kofane2004). Also, α and λ increase with decreasing porosity (Table 2). The greater the λ values, the more thermally conductive the material. The trends in the evolution of α and λ in the studied materials are similar. Indeed, the largest values of α and λ were recorded in cement-stabilized CEB, i.e. the densest, less porous CEB, where E is large. It is then obvious that cement stabilization diminished the insulation capacity of the blocks (Belarbi et al., Reference Belarbi, Sawadogo, Poullain, Issaadi, Hamami, Bonnet and Belarbi2022). This decrease is related to the difference between radiation and conduction within the block. In fact, radiation occurs in the air within the pores, and it is insulating (due to its low air conductivity, λair ≈ 0.026 Wm–1K–1b) (Debnath et al., Reference Debnath, Pabbisetty, Sarkar, Singh, Majhi and Singh2022). Conduction occurs on a solid surface, with fewer insulating effects, given that the conductivity of a solid is greater than that of air (Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018; Zhang et al., Reference Zhang, Gustavsen, Jelle, Yang, Gao and Wang2017). Given that porosity is being reduced upon cement addition, the amount of trapped air (Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018) and consequently, the radiation capability of the material are also reduced. The addition of cement favours solid surface development, which improves surface conduction.
The ρc value ranges from 1.53×106 to 2.21×106JK–1m–3, leading to a heat mass capacity (c) range of 3440.2≤c ≤ 4418.0 JK–1kg–1, with the largest values in materials with 0% cement. Hence, cement stabilization reduces the heat-insulating capability of the blocks as ρc values decrease with increasing cement contents in all the specimens. However, these ρc values are relatively large compared to reported values of similar materials-based blocks from the literature (Meukam et al., Reference Meukam, Jannot, Noumowe and Kofane2004; Mansour et al., Reference Mansour, Jelidi, Cherif and Jabrallah2016; Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018).
The flexural (σf) and compressive (σc) strengths range from 0.77 to 5.15 MPa and from 1.53 to 28.94 MPa, respectively (Table 2). The values of these parameters increase with increasing cement contents. This trend is in line with the development of more continuous solid surfaces, as suggested by the conductivity behaviour. The σc values of cement-stabilized CEB, from 3% cement, are ≥4 MPa, which indicates that these blocks are suitable for construction of load-bearing walls in two-or three-storey buildings in dry environments (Reeves et al., Reference Reeves, Sims and Cripps2006; Murmu & Patel, Reference Murmu and Patel2018; Nshimiyimana et al., Reference Nshimiyimana, Fagel, Messan, Wetshondo and Courard2020). In specimens with 0% cement, only MN14 and BM2-based specimens exhibit σc ≥ 2 MPa, which makes them suitable for non-load-bearing structures in single-storey buildings in dry environments. The σf and σc values for MN14 and BM2 are the largest and are related to their clay contents, which are significant, compared to the remaining clayey materials. These clay mineral contents acted as a binding phase, which linked the coarse particles together in the CEB, ensuring the densification of the block (Van Damme & Houben, Reference Van Damme and Houben2018). In cement-stabilized CEB, the cohesion between coarse particles is ensured by both the clay matrix and the cement. The hydration of cement particles leads to the formation of hydrated calcium silicate (C-S-H), which binds the coarse particles of the clayey materials, leading to a continuous surface that enhances the mechanical response (Sore et al., Reference Sore, Messan, Prud'homme, Escadeillas and Tsobnang2018; John et al., Reference John, Epping and Stephan2019). Clayey materials with moderate clay mineral contents (MN11, MN22 and BP1) exhibit a marked increase in mechanical response from the addition of 6% cement. The difference between samples having greater clay mineral contents (MN14 and BM2) is due to coarse particle content that interact with C-S-H to generate a denser structure.
Heat-stabilized specimens: mineralogical, physical, thermal and mechanical behaviour
The mineralogical composition of fired samples is made up of quartz, hematite, orthoclase, rutile, anorthite and augite. A mullite diffraction peak at 3.40 Å is observed from 900°C (Fig. 2). Samples MN14 and BM2 fired at 1100°C also contain cristobalite (peaks at ~4.02 Å and ~2.48 Å). This mineralogy is consistent with that of raw materials due to the conversion of certain phases under thermal treatment. For instance, hematite forms from conversion of goethite at 250°C (Ruan et al., Reference Ruan, Frost and Kloprogge2001, Reference Ruan, Frost, Kloprogge and Duong2002; Gialanella et al., Reference Gialanella, Girardi, Ischia, Lonardelli, Mattarelli and Montagna2010). The disappearance of kaolinite is due to the conversion to metakaolinite at temperatures >600°C, which later leads to mullite crystallization and vitrification (Lee et al., Reference Lee, Souza, McConville, Tarvornpanich and Iqbal2008; Wang et al., Reference Wang, Wang and Zhang2017).
Linear shrinkage (LS) values are relatively low (1.11–7.22%) and increase with firing temperature (Table 3). Samples with large clay contents exhibit the largest values of LS. The small LS values are consistent with the mineralogical assemblage of the raw materials, which are poor in fluxing agents, leading to limited formation of a vitreous phase. Hence, the main cause of LS in these materials is capillary diffusion, which releases water molecules out of the structure during firing. The dehydration of oxy-hydroxide minerals such as goethite and clay minerals are the main sources of LS (He et al., Reference He, Yue, Su, Gao, Gao, Wang and Yu2012). Hence, the largest values of LSin samples with large clay contents are explained. The ρ values also increase with firing temperature, from 1.88 to 2.12 g/cm3 (Table 3), due to densification, associated with the formation of denser phases such as mullite as from 900°C. These ρ values are in line with the densities of kaolinite-based products reported in previous studies (Njeumen et al., Reference NjeumenNkayem, Mbey, Kenne Diffo and Njopwouo2016; Pountouenchi et al., Reference Pountouenchi, Njoya, Mbey, Mache, Njoya, Yongue, Njopwouo, Fagel, Pilate and Van Parys2023).
Porosity (n) and water adsorption (WA) decrease with increasing temperature. This trend is in accord with the fact that WAis linked to n. The n decrease is associated with the enclosure of pores during sintering, resulting from vitreous phase formation. The values of WA are small and they range from 4.12 to 7.21%. These low values indicate that all the materials are suitable for building materials and construction, according to Brazilian standard recommendations for WA of <20% (Souza et al., Reference Souza, Sanchez and De Hollanda2002; Onana et al., Reference Onana, Ntouala, Mbey, Ngo'oZe, Kabeyene and Ekodeck2019). Porosity ranges from 17.24 to 23.75% and is of interest for thermal isolation (Bories et al., Reference Bories, Borredon, Verdrenne and Vilarem2014). However, the firing temperature should not exceed1000°C in order to benefit from the pores in thermal insulation.
The thermal parameters of the fired bricks are reported in Table 3. All of the parameters decreased in the fired specimen at 800°C in comparison to the unfired blocks (sample dried under ambient conditions at ~28°C). The observed decrease of the parameters is related to kaolinite conversion into metakaolin upon dehydroxylation, which is a less conductive phase (Bourret et al., Reference Bourret, Tessier-Doyen, Guinebretiere, Joussein and Smith2015). Above 800°C, an increase in E, α andλ is observed, resulting in a decrease inρc. The trend change after 800°C is associated with the crystallization and formation of phases such as mullite (Michot et al., Reference Michot, Smith, Degot and Gault2008) and the increase in structural organization of quartz, which is a highly conductive mineral in comparison to clay minerals (Yoon et al., Reference Yoon, Car, Srolovitz and Scandolo2004). Hence, at low mullitization (<900°C), the most conductive blocks are made of samples rich in sand (quartz) fraction, namely MN11 and MN22. At temperatures >900°C, the degree of mullitization affects conductivity, with the clay-rich samples (MN14 and BM2) showing greater conductivity. The intermediate behaviour of sample BP1 is driven by its clay fraction (38.06%), which is in the same range as its sand fraction (35.11%). In addition, pore reduction upon firing contributes to increased conductivity due to increased surface conduction.
The ranges for E, α and λ are 8.67×102 to 1.14×103JK–1m–2s–1/2, 2.22×10–7 to 5.27×10–7 m2s–1and 4.09×10–1 to 8.24×10–1 Wm–1K–1, while ρc values are in the range 1.55×106–1.84×106 JK–1m–3 (Table 3). These values indicate that fired bricks are more heat insulating than cement-stabilized specimens.
The values of the flexural (σf) and compression (σc) strengths are listed in Table 3. They range from 1.63 MPa to 6.10 MPa and 5.71 MPa to 27.83 MPa, respectively. Both strengths increase with firing temperatures as reported in previous studies (Roudouane et al., Reference Roudouane, Mbey, Bayiga and Ndjigui2020; Onana et al., Reference Onana, Ntouala, Mbey, Ngo'oZe, Kabeyene and Ekodeck2019). These increases are obviously associated with increased densification during sintering. The firing promotes vitrification and the formation of denser phases such as mullite (Buchner et al., Reference Buchner, Kiefer, Königsberger, Jäger and Füssl2021; Debnath et al., Reference Debnath, Pabbisetty, Sarkar, Singh, Majhi and Singh2022). The role of mullite on densification is further confirmed by the highest strengths registered for clay-rich samples, MN14 and BM2. According to the Brazilian standard reported by Souza et al. (Reference Souza, Sanchez and De Hollanda2002), values of σf ≥ 2 MPa and σf ≥ 5.5 MPa are recommended for structural brick making. Among the studied samples, MN14 and BM2 are suitable after firing at 800°C, while temperatures of at least 1000°C may be necessary for the other samples unless an amendment is made to reduce the firing temperatures.
Cement and heat-stabilized specimens: performance comparison using statistical analysis
Comparison of average values of physical parameters shows that ρ is greater in cement-stabilized CEB than in fired bricks (Table 4), whereas n is greater in fired bricks than in cement-stabilized CEB. These two parameters affected both the thermal and mechanical behaviours of the specimens. Indeed, E, α and λ are smaller in fired bricks than in cement-stabilized CEB, indicating a greater thermal insulation capacity for fired bricks. In addition, the mechanical parameters σf and σc are greater in cement-stabilized CEB than in fired bricks. The comparison of standard deviation (SD) values (Table 4) shows that the thermal properties (E, α, λ and ρc) and the compressive strength (σc) of the studied materials are more dispersed when stabilized with cement, while the flexural strength (σf) dispersion is greater for fired products. These differences in dispersion indicate that the changes in properties are more marked for cement stabilization than for heat stabilization; there is an optimal temperature beyond which the changes are less sensitive.
SD = standard deviation.
Tables 5 and 6 highlight the levels of correlation between physical, mineralogical, thermal and mechanical parameters. ρ is moderately negatively correlated with n in both cement-stabilized and heat-stabilized materials. These negative correlations agree with the n reduction upon either firing temperature increase or cement percent increase, confirming the results from the measured n (see previous sections). However, the level of correlation between ρ and n is greater (absolute value) in fired materials (R = –0.783) compared to cement-stabilized materials (R = –0.612), suggesting a possible additional factor on vitrification that is taking place in the firing process. As LS correlates positively with ρ (R = 0.592) and negatively with n (R = –0.731) in fired specimens, the LS should be considered to be the additional factor. The latter affects not only the total volume of the specimen, but also the volume of voids in the specimen, resulting in the improvement of the density along with vitrification.
Values in bold are different from 0 with a level of significance, alpha = 0.05.
Values shown in bold are different from 0 with a level of significance, alpha = 0.05.
ρ is strongly positively correlated with E, α and λ (R ≥ 0.840) and negatively correlated with ρc (R ≤ –0.717). These trends indicate reduced insulation capacities of specimens with increasing densities and this is further confirmed by the fact that n, in contrast to ρ in the same specimens, is negatively correlated with E, α and λ (R ≤ –0.591) and positively with ρc (R ≥ 0.434). Most of these correlations are high and linear (supplementary data Fig. S1a to S1i). Some of the correlations are average in cement-stabilized specimens when compared to heat-stabilized specimens, resulting in the fact that specimens are more insulating when heat-stabilized than when cement-stabilized. The correlation of these properties to the mineralogy of cement-stabilized specimens shows that quartz and kaolinite contents are the main sources of densification. Because quartz is denser than kaolinite, it is positively correlated with ρ(R = 0.456), whereas kaolinite is negatively correlated (R = –0.492). The negative correlation with kaolinite is probably associated with the poor interaction between the clay and the fine cement particles, which may not favour densification. In contrast, interactions with coarser quartz particles increase the densification. Correlations of the density with raw-sample mineralogy in fired specimens are not meaningful, as the changes in mineral forms of clays to mullite or of quartz to its polymorphs (such as cristobalite) should be considered. The same applies to the thermal parameters (Table 6). It is then postulated that the less insulating behaviour of the cement-stabilized CEB is due to pore organization defaults that favor surface conduction, in contrast to heat-stabilized specimens, in which the mineralogical conversion of the clay minerals and vitrification generate control of the pore structures, in which radiation in the trapped air is developed. However, the mechanical responses of the fired specimens are favorably correlated to kaolinite contents (R ≥ 0.695), as a result of their conversion during sintering in more dense phases such as mullite. The LS and the clay fraction, in heat stabilization, are positively linearly correlated with mechanical strength (supplementary data Fig. S1k to S1n). This is not the case in cement-stabilized CEB as there is almost no shrinkage.
Correlations between thermal (E, α and λ) and mechanical parameters (σf and σc) are positive and significant (R ≥ 0.702) in cement-stabilized materials (Table 5), whereas for heat-stabilized materials, correlations are positive but less significant (R ≤ 0.526) (Table 6). The structure of the specimens is probably the main cause of the differences. In cement-stabilized materials, the formation of calcium silicate hydrate (C-S-H) favours the formation of continuous surface which improve mechanical responses but reduce insulation capacity as the surface conduction improves. In fired products, the sintering process implies the formation of a vitreous phase in which unmodified mineral grains are embedded together with the partial mineral conversion of some phases. This leads to less continuous surfaces that contribute to enhancement of insulation due to the reduction of surface conduction.
In the PCA, the cumulated percentage of variance (56.79) presented by the two axes F1 and F2 is not sufficient. To avoid misinterpretation of the graphic, the F1–F3 factorial plan has been added, for a cumulated percentage of variance of 71.09 (supplementary data, Table S1). Results relative to the contribution of variables for the construction of these axes show that thirteen parameters are well expressed. This contribution is supported by the square cosine method (supplementary data Table S2). According to this method, clay, sand, Qz, Kln, ρ, n, α and λ on the F1 axis, σf and σc on the F2 axis, and silt, Hem, and Rt on the F3 axis are well represented. An interpretation based on WA, E, Gth and Or is to be considered secondary.
In the F1–F2 correlation circle (Fig. 3a), Kln and clay are positively correlated. These two variables are negatively correlated with Qz and sand. E, α, λ, ρ, σf and σc are close, i.e. positively correlated. These correlations corroborate observations made previously, i.e. the greater the value of ρ, the greater is E, α, λ, σf and σc. In the F1–F3 factorial plan (Fig. 3b), sand and Qz are close to ρ, α and λ. This group of parameters is significantly negatively correlated with clay, Kln and n. These correlations reaffirm the impact of the mineralogical variation on the density and, consequently, on the thermal performance. The resulting clouds of individuals (Fig. 3c,d) show that the F1 axis almost separates cement-stabilized CEB from heat-stabilized specimens. This highlights the effect of the two stabilization techniques on the initial materials. The two groups can, however, be redistributed into three classes. Indeed, AHC organizes the cement and heat-stabilized materials studied into classes 1, 2 and 3 (Fig. 4). Class 1 groups both cement- (10 samples) and heat- (17 samples) stabilized CEB. This class is governed by moderate to large clay, sand, quartz and kaolinite contents (clay = 38.16%, sand = 41.97%, Qz = 40.71% and Kln = 35.75%) (supplementary data Table S3). Specimens in this class show good mechanical performances when cement-stabilized. In addition, they show good insulation capabilities and moderate to good mechanical performances when heat-stabilized. Class 2 (7 samples) consists only of cement-stabilized CEB and the controlling factors here are large clay and kaolinite, and moderate sand and quartz contents (clay = 49.42%, Kln = 44.92%, sand = 25.27% and Qz = 28.88%). Specimens in this class are marked by large insulation capacities and poor mechanical performances. Similar to class 1, class 3 also consists of both cement- (13 samples) and heat- (3 samples) stabilized CEB. Here the governing factors are large clay and kaolinite, and moderate sand and quartz contents (clay = 48.56%, Kln = 44.26%, sand = 28.15% and Qz = 30.51%). Specimens in this class show moderate to high insulation capacities and moderate mechanical performances regardless of the stabilization type.
Summary and conclusions
Clayey materials from the Mbam River banks were characterized and used in the manufacture of earthen building blocks. The aim was to evaluate their thermal and mechanical performances after cement- and heat-stabilization. These materials consist mainly of kaolinite, orthoclase and quartz with minor hematite, goethite, rutile, anorthite and augite. Their densities are consistent with their nature as soil materials, with variations associated with differences in mineral-phase contents, mainly kaolinite and quartz. Overall, the thermal insulation of the materials studied is satisfactory, with better performances for heat-stabilized specimens, especially those fired at temperatures of <1000°C. The insulation capacity of heat-stabilized specimens decreases with temperature increase as a result of pore reduction. However, the poor development of continuous surfaces allows the thermal insulation to remain greater when compared to cement-stabilized specimens. The cement-stabilizedspecimens show greater mechanical responses than heat-stabilized specimens. Addition of ~9% cement is the ideal level for cement-stabilized specimens, particularly for those rich in kaolinite. Regarding the firing temperature, a minimum of 900°C should be recommended to obtain suitable fired bricks. It was established using statistics that the mineralogy of raw samples determines the insulation behaviour of the stabilized CEB. For fired samples, large clay contents favour insulation behaviour through the transformation of clay minerals during firing. Discontinuities arising from conversion of clay minerals and the formation of a vitreous phase cause reduced conduction surfaces, which enhance the thermal insulating performance. LS is an additional factor for porosity changes in heat stabilization. For cement-stabilized materials, the role of C-S-H in continuous surface development was proposed as a main cause of thermal insulation reduction. A large clay content does not favour the mechanical response in cement stabilization, due to poor clay–cement interaction. Coarse particles, such as sand, are needed to ensure good cohesion and interaction between the C-S-H and the fine fraction due to clay.
Overall, although the mineralogy of the starting material should be considered in relation to the performance needed, the mechanical responses are of more interest with cement stabilization, while thermal insulation is better using firing.
Supplementary material
To view supplementary material for this article, please visit https://doi.org/10.1180/clm.2024.9.
Acknowledgements
The Cameroonian Ministry of Higher Education is acknowledged for providing a research allowance for the modernization of university research to the teachers-researchers of state universities.
Financial support
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Conflicts of interest
The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.