Lithological Provenance of Multicomponent Raw Clay

The main lithological units in the study area (Fig. 1) were amphibolite (Pza) and gneiss (Pzni); however, to a lesser extent, also present were sedimentary deposits and tonalite intrusions (Kit) in the form of dikes, which were important for their contribution of kaolinite due to their greater weathering degree. Likewise, the area presented a large number of faults with the main strike directions of N10–20W and N10–20E, and dip angles greater than 55°, which indicated high brittle deformation and generated open spaces in the rock mass. This facilitated the infiltration and transport of meteoric water and fluids to deeper levels, which leached and altered the minerals of the surrounding rocks into kaolinite and goethite.

Vásquez et al. (Reference Vásquez, Carmona and Tobón2020) suggested that the low-grade kaolinitic multicomponent raw clay came from the weathering of parental rocks of metamorphic origin: (1) paragneiss composed of quartz, biotite, feldspar, muscovite, chlorite, garnet, epidote, and tourmaline, and (2) ortho-amphibolite composed of hornblende and plagioclase. They suffered argilization and sericitization, which altered their primary minerals to clay minerals types 1:1 and 2:1 (kaolinite, illite, and vermiculite), sericite, and iron (oxyhydr)oxides such as goethite and goethite enriched in aluminum. The sericite and clay contents were 50% and 20% for the ortho-amphibolite raw clay samples and 40% and 26% for the paragneiss samples, respectively.

Behavior of Chemical Variables

The chemical composition of the raw clay was related to the lithology of the parent rock (Fig. 3; Supplemental Material 1) with the acidic paragneiss contributing potassium oxide and silica to the clay composite, while the intermediate composition of ortho-amphibolite contributed alumina, iron, and titanium oxides, due to their more basic character.

Fig. 3 Behavior of the chemical variables as a function of the depth of the deposit. Bars correspond to median, and IQR to Interquartile Range

Median values were considered because they are a measure of a central tendency less affected by atypical values compared to the mean; exploratory statistical analysis of the data revealed that most cases had asymmetric distributions. Based on these analyses, large quantities of silica, alumina, iron, and titanium oxides (listed in descending proportion order) were found in both clays as a result of the weathering and alteration processes. However, when both clays were compared, the silica (60–65%) and potassium oxide (1.5–2.5%) in the paragneiss raw clay exhibited the greatest values compared to the values of these oxides in ortho-amphibolite raw clay, and, in turn, the latter obtained the highest values of alumina (20–30%), iron oxide (8–15%), and titanium (1.0–2.5%), due to its ferromagnesian composition. Furthermore, both chemical composition (Fig. 3) and loss on ignition (LOI) reported by Vásquez et al. (Reference Vásquez, Carmona and Tobón2020) confirmed that the raw clay from the first 50 m of deposit fulfilled satisfactorily the chemical requirements of pozzolanic material established in the ASTM standard C618-19 (SiO₂ + Al₂O₃ + Fe₂O₃ > 70%, SO₃ < 4%, and LOI < 10%).

On the other hand, in the first 30 m of depth, values of alumina and silica increased by the action of exogenic factors in the weathering, such as the intense rainfall (4150 mm/y) which acted on the deposit and which removed alkaline elements and enriched alumina, silica, iron, and titanium oxides. In addition, with the physicochemical samplings carried out, cations of the Mg²⁺ and Ca²⁺ type and anions of HCO^3– and SO₄ ^2– type were identified, which indicated intense leaching in the deposit and caused the decrease of the neutral to slightly acidic pH values in the sampling points of springs (5.8–7.0), piezometers (5.8–6.4), and streams (6.8–7.0), which promoted a faster ion exchange and transformed the primary minerals into alteration minerals.

Behavior of Mineralogical Variables

Because raw paragneiss clay has a more acidic composition, it contains more quartz (35–45%) and mica (muscovite) + type 2:1 clays (illite+vermiculite) (10–20%) (Fig. 4; Supplemental Material 1). Kaolinite and muscovite+illite+vermiculite increased in the first 40 and 30 m of the deposit, respectively, with kaolinite being the main mineral of the ortho-amphibolite raw clay, with a content of 28–48%, which was also related to the chemistry and genetics of the parent rock of this clay. Thus, a relationship was found with the Bowen's reaction series, where quartz, potassium feldspar (K-feldspar), and micas (muscovite) are the most thermodynamically stable minerals with the greatest abundance at the surface levels of the Earth's crust.

Fig. 4 Behavior of mineralogical variables as a function of depth of the deposit. Bars correspond to median, and IQR to Interquartile Range

Moreover, quartz tended to stable values in the weathering profile (as happened in the paragneiss raw clay), while the concentration of mica (muscovite) + type 2:1 clays and kaolinite was related directly to the weathering intensity, kaolinite being a product of an intense transformation of primary minerals (feldspars, plagioclases, and micas as biotite). This was in agreement with the results of Dapena (Reference Dapena1978) and García and Suárez (Reference García and Suárez2003).

In addition, according to Alvarado et al. (Reference Alvarado, Mata and Chinchilla2014) kaolinitic clays are the last to form, so their content increases at the most superficial levels where weathering is more intense, while illite clays are the result of less weathering, so their content decreases at the most superficial levels and a transformation of the illite into vermiculite or montmorillonite can occur. This explains why the ortho-amphibolite raw clay had the higher kaolinite and the lower mica (muscovite) + type 2:1 clay contents than the paragneiss raw clay, which meant that the ortho-amphibolite raw clay was more affected by the weathering process.

Behavior of Physical Variables

In general, the SSA of particles of <5 μm (commercial size of clay but corresponding to fine silt and clay sizes) and degree of order/disorder, P₀, calculated by FTIR, increased at surface levels of the deposit (Fig. 5; Supplemental Material 1).

Fig. 5 Behavior of the physical variables as a function of the depth of the deposit. P₀: degree of order/disorder calculated by FTIR. L* coordinate: lightness. a* coordinate: red to green. b* coordinate: blue to yellow. Bars correspond to median, and IQR to Interquartile Range

From Tironi (Reference Tironi2013), the degree order/disorder of kaolinite can be determined by utilizing P₀, considering that the structure is ordered if P₀ > 1 or disordered if P₀ < 1. In addition, the lower the P₀, the more disordered the structure is, but care must be taken because the measurement is affected by the vibration of the OH^– illitic groups around the 3625 cm^–1 band. Thus, the P₀ of the two raw clays was between 0.5 and 0.8, which indicated a slight structural disorder in the kaolinite due to the weathering suffered by the parent rocks.

So, while the formation of the raw clay occurred in the first meters of the deposit, the particle size tended to decrease, and, therefore, the SSA increased, which made the number of particles which were <5 μm greater at those points where the weathering was stronger, similar to that mentioned by Alvarado et al. (Reference Alvarado, Mata and Chinchilla2014). Thus, a direct relationship between SSA and the areas of greatest weathering was found.

Besides this, ortho-amphibolite raw clay was more weathered, which made it more susceptible to thermal activation and a better candidate for use as an SCM. This was reflected in the smaller P₀ (0.5–0.7) and larger SSA (28–30 m²/g) values found in the first 20 m of the deposit, compared to paragneiss (~0.7; 20–30 m²/g).

On the other hand, colorimetric coordinates a* and b* increased at the most superficial levels, while the opposite occurred in the L* coordinate. This meant that the raw clay in the first 30 m had more reddish hues (+a*, +b*) and was duller due to the iron (oxyhydr)oxides accumulating near the surface, especially in the ortho-amphibolite raw clay due to its greater iron content.

Alteration and Weathering Degree of the Clay Deposit

In the present work, the use of electrical resistivity tomographies was highlighted as a geophysical exploration technique (green lines in Fig. 1), which, together with the perforations, allowed the establishment of the ranges and the average thicknesses of each of the horizons of the weathering profile, using the classification criteria of Dearman (Reference Dearman1974) and Little (Reference Little1969). It permitted the determination of the range of electrical resistivity, its depth, the characteristics of the medium (dry or saturated conditions), and the type of clay according to depth, for each horizon, allowing the natural conditions of the deposit to be related to the SCM development of the calcined clay as a function of depth. The results of this technique (geological interpretations and contents of clay minerals for each horizon of the weathering profile) are shown in Fig. 6 and Table 1.

Fig. 6 Electrical resistivity tomography (1–2) and typical weathering profile of the studied clay deposit. a The geological interpretation is indicated by the respective solid and dotted black arrows. b The average thickness and depth of each horizon in the weathering profile is shown according to the scale of the tomographies

Table 1 Characteristics of the typical weathering profile of the low-grade kaolinitic multicomponent raw clay deposit

E*, P*: average values of thickness and depth range for each horizon.

R: electrical resistivity. C: clay content type 1:1 and 2:1.

^a: soil and intermediate material unit under dry conditions

^b: intermediate material unit under saturated conditions

^c: intermediate material unit under saturated conditions with higher fracture and oxidation

From tomographies 1 and 2, three main zones were established (Fig. 6a): (1) bluish colors for regions whose resistivities were lower, <300 Ώ m, associated with the greater presence of water and fracturing of the medium, (2) greenish colors with intermediate resistivities between 300–1300 Ώ m, which indicated saturation, but less intense fracturing than in the previous zone, and (3) yellowish/reddish/violet colors with much higher resistivities, 1300–10000 Ώ m, associated with dry conditions (without saturation).

On the contrary, the typical weathering profile for the deposit was established from logging during the drilling campaigns (Fig. 6b), which showed three main regions: (1) a first very clayey region (horizons V–VI), with a pronounced earthy and plastic texture, and raw clays characterized by their reddish hues; (2) a second intermediate region (horizons IV–III) where rock and soil materials coexist, highlighting that the reddish hues of the soil were accompanied by whitish hues of the rock, which made the region brighter than the previous one; and (3) a very fractured third region with a grayish hue (horizon III), in which the basement rock of the deposit was observed. In this region, the ortho-amphibolite was more weathered by the greater presence of rock fragments; it had more reddish hues and had greater fracturing of the drill core, while in the paragneiss the opposite occurred; there was even discoloration in some of its fragments.

With these results, a geological interpretation of the deposit was constructed (solid and dotted arrow lines in Fig. 6a), and average thicknesses were established for the first horizons of the weathering profile (Table 1). The deposit presented soil units (horizons V–VI) of 22 m and intermediate material units (horizons III–IV) of 24 m, which indicated that ~46 m of potential material was present in situ to be used as pozzolanic material after its thermal activation. Furthermore, with increasing depth the quantity of type 1:1 clay, such as kaolinite, decreased, while the mica (muscovite) and type 2:1 clays (illite and vermiculite), increased. This was, therefore, a potential deposit of raw material from low-grade kaolinitic multicomponent clay which was highly fractured and weathered in the first 50 m of depth.

Analysis by lithology and horizons of the weathering profile (Fig. 7; Supplemental Material 1) revealed that the behaviors were similar to those of kaolinite, illite, vermiculite, and muscovite concerning depth (Fig. 4). However, when it came to relating clay minerals with their primary minerals such as K-feldspar (microcline), Na-plagioclase (albite), micas (biotite), and chlorites (clinochlore), an inverse relationship was found; i.e. in the deeper horizons (III–IV), primary minerals increased because they were closer to the parent rocks and, consequently, kaolinite decreased. In addition, the paragneiss raw clay had a larger amount of primary minerals, which indicated less intense weathering, less kaolinite (20–25%), and more muscovite + illite (10–30%), with a drastic fall of the latter to values close to zero.

Fig. 7 Mineralogical behavior in the weathering profile of the deposit. Upper part: Average ratio between primary and clay minerals. Lower: Variation of minerals rich in aluminum, iron, and titanium oxides. Weathering profile was classificated according to the guidelines of Little (Reference Little1969) and Dearman (Reference Dearman1974)

Likewise, aluminum minerals such as gibbsite and goethite enriched in aluminum (Fig. 7) had a direct relationship with the degree of alteration of the deposit; these minerals were accumulated in the most superficial horizons (V–VI). Intense washing and leaching of the silica and alkaline elements occurred in the deposit, similar to that found by Besoain (Reference Besoain1985). In addition, goethite and titanium minerals (rutile and anatase) behaved similarly to aluminum minerals. This will be useful for future research into the degree of alteration of other clay deposits and their suitability as pozzolanic materials.

On the contrary, the degree of alteration of the deposit obtained from the geological exploration campaign was related to that obtained through the Chemical Index of Alteration (CIA) proposed by Nesbitt and Young (Reference Nesbitt and Young1982, Reference Nesbitt and Young1984, Reference Nesbitt and Young1989) to determine the degree of alteration of feldspar from compositional measurements of oxides by the following equation (Eq. 1):

(1) $\mathrm{CIA}\left(\%\right)=\left({\mathrm{Al}}_2{O}_3/\left({\mathrm{Al}}_2{O}_3+\mathrm{CaO}+{\mathrm{Na}}_{2}O+K_{2}O\right)\right)\times 100.$

Nesbitt and Young (Reference Nesbitt and Young1982) stated that CIA ≈ 50% corresponds to Na-plagioclase (albite), Ca-plagioclase (anorthite), or K-feldspar without alteration; CIA between 30–45% corresponds to fresh basalts; and CIA between 45 and 55% to granites and granodiorites. It is from these values (>55%) that the primary minerals are altered and they are transformed into clay minerals. For illites and montmorillonites, the CIA is 75–85%, while for kaolinites and chlorites, it is close to 100%.

The average CIA of the raw clay is presented together with the weathering profile and the depth of the clay deposit in Fig. 8 (left side; Supplemental Material 1). A direct relationship was observed between the CIA and the horizons of the weathering profile, which indicated intense weathering in the first 50 m (CIA > 80%). This made the entire deposit suitable for activation as a pozzolanic material. Also, the degree of alteration increased in superficial horizons where the kaolinite content was greater, with a CIA >90%.

Fig. 8 Relationships among Chemical Index of Alteration (CIA), loss on ignition (LOI), weathering profile (horizons VI, V, IV, II), and depth of the deposit by lithological group. The vertical lines correspond to the average thickness of the horizons. Weathering profile was classified according to the guidelines of Little (Reference Little1969) and Dearman (Reference Dearman1974)

Thus, the results were consistent with each other, because the CIA in the multicomponent raw clay increased with the kaolinite content and decreased with the amount of 2:1 clays and mica (muscovite). However, an obvious lithological differentiation occurred in the CIA. This confirmed that the ortho-amphibolite raw clay was more altered and weathered than the paragneiss raw clay (by its higher CIA), which made it more susceptible to thermal activation.

A direct relationship was also observed between CIA and LOI, similar to that stated by Aristizábal et al. (Reference Aristizábal, Roser and Yokota2005) for hillslope deposits and bedrock sources in the Aburrá Valley, but differentiated by lithology (Fig. 8 right side; Supplemental Material 1). The authors stated that with these measurements, CIA can also be known, and for fresh rock, LOI is <3% with CIA being 40–50%. With this in mind, LOI increased with the degree of alteration of the deposit; i.e. CIA close to 100% in superficial horizons. Thus, all raw clay samples obtained a LOI of >7%, which indicated a significant alteration and weathering of the clay deposit, confirming once again the susceptibility of the clay deposit for use as an SCM. Furthermore, LOI values were higher and steeper in the ortho-amphibolite raw clay, which confirmed its greater alteration and weathering degree.

Thermal Activation of the Low-Grade Kaolinitic Multicomponent Raw Clay

The XRD patterns and FTIR spectra of the raw and calcined clay samples from the horizons of the weathering profile of the clay deposit (Figs. 9, 10, 11; Supplemental Material 2) revealed, in general, that the degree of alteration decreased with depth, as did the reflection of the kaolinite, gibbsite, goethite, hematite, and anatase, especially in the patterns for the ortho-amphibolite raw clay, which contains more of these minerals. However, the opposite occurred in muscovite, illite, and vermiculite, which were more prevalent in the paragneiss raw clay as reflected by more intense XRD peaks from these minerals in the XRD patterns.

Fig. 9 XRD patterns of the calcined clay at temperatures of 650, 750, and 850°C for the various horizons in the weathering profile (see Supplemental Material 2 for the tabulated raw data). RT: room temperature. Q: quartz, K: kaolinite, M: muscovite, I: illite, V: vermiculite, Gh: goethite, Gi: gibbsite, H: hematite, A: anatase

Fig. 10 FTIR spectra of the paragneiss clay calcined at temperatures of 650, 750, and 850°C for the various horizons in the weathering profile. RT: room temperature

Fig. 11 FTIR spectra of ortho-amphibolite clay calcined at temperatures of 650, 750, and 850°C for the various horizons in the weathering profile. RT: room temperature

The following observations were made about the effect of calcination. (1) A significant increase was observed in the intensity and widths of the 8.88 and 34.88°2θ muscovite reflections, and the 20.03, 35.02, and 24.30°2θ illite reflections with temperature, particularly at 850°C and in horizons IV–III, indicating a structural order (no total dehydroxylation under the studied temperatures) similar to that recorded by Alujas et al. (Reference Alujas, Fernández, Quintana, Scrivener and Martirena2015), where total dehydroxylation occurs around 900°C. (2) At all temperatures, the 12.30 and 24.85°2θ reflections of kaolinite, the 21.24 and 35.00°2θ reflections of goethite, and the 17.80°2θ reflection of gibbsite collapsed completely, indicating that total dehydroxylation of these minerals occurred at temperatures below 650°C, similar to that found by Alujas et al. (Reference Alujas, Fernández, Quintana, Scrivener and Martirena2015), where the total dehydroxylation of kaolinite occurred at 600°C and of goethite and gibbsite at 350°C. (3) The intensity and width of the 33.28 and 35.74°2θ hematite reflections and of the 25.35°2θ anatase reflection increased with temperature, which was associated with the crystallization phenomena of minerals such as hematite (iron oxide) above 650°C and the total dehydroxylation of goethite (iron oxyhydroxide) around 350°C.

On the other hand, FTIR spectra showed bands of six functional groups (Figs. 10 and 11): a vibration band at 528 cm^–1 from Si–O–Al (VI) of kaolinite (where VI indicates Al in octahedral coordination), vibration bands at 747 and 789 cm^–1 of Si–O–Al (IV) of kaolinite (where IV indicates Al in tetrahedral coordination), a deformation vibration band at 910 cm^–1 of Al–OH of kaolinite, elongation vibration bands at 1000 and 1026 cm^–1 of Si–O of kaolinite, a bending vibration band at 1640 cm^–1 of H–O–H of water molecules adsorbed by 2:1 clays such as montmorillonite (Madejová, Reference Madejová2003), and stretching bands at 3621, 3655, 3669, and 3695 cm^–1 of the hydroxyl groups.

The transmittances of the raw clay samples (at room temperature – RT) for the functional group Si–O–Al (VI) were between 20 and 60% (absorbance between 1.6 and 0.5), which indicated greater structural order in the multicomponent raw clay due to the octahedral coordination of aluminum in the kaolinite; hence the need to thermally activate the raw clay to ensure pozzolanic reactivity. However, the small amount of Si–O–Al (IV) (transmittance between 75 and 90%, absorbance between 0.3 and 0.1) in both lithologies reflected a certain degree of structural disorder in the kaolinite of the raw clay, produced by the weathering suffered in the clay deposit, which made it suitable for thermal activation.

Likewise, FTIR spectra of calcined clay samples confirmed what was discussed from the XRD patterns: total dehydroxylation in kaolinite at temperatures ≥650°C, given that OH and Al–OH bands of kaolinite disappeared. Furthermore, above 650°C, the transmittance of the Si–O–Al (VI) band decreased dramatically, indicating lower coordination of aluminum and, consequently, more structural disorder in the calcined clay. Therefore, clays of the deposit showed structural disorder by thermal treatment, due to total dehydroxylation of kaolinite at 650°C and partially of illite at 850°C (confirmed by XRD); so, these calcined clays were candidates for evaluation as SCMs by means of pozzolanic activity measurements such as SAI and Frattini.

Evaluation of the Pozzolanic Activity of Multicomponent Calcined Clay

The Strength Activity Index (SAI) at 28 curing days for the first 50 m of the clay deposit is shown in Fig. 12 (left side; Supplemental Material 1). Pozzolanic activity decreased with depth at the three calcination temperatures, due mainly to the degree of weathering, which was greater at superficial levels. This corroborated the suggestion that the greater the degree of weathering, the greater the SAI, as asserted by Dapena (Reference Dapena1978) and García and Suárez (Reference García and Suárez2003).

Fig. 12 SAI results at 28 curing days as a function of calcination temperature and depth (left), and behavior of the kaolinite/(muscovite+illite+vermiculite) ratio of the raw clay derived from ortho-amphibolite with the depth of the deposit (right). Bars correspond to median, and IQR to Interquartile Range

Regardless of the lithology of the parent rock and the temperature of calcination, the calcined clay of the first 50 m of the deposit fulfilled satisfactorily the requirements for pozzolanic material, because SAI was between 85 and 110%, which was higher than the threshold value of 75% established by ASTM C 311-18.

Considering the mineralogy in the ortho-amphibolite raw clay (Fig. 4), a relationship was found among SAI, kaolinite and mica (muscovite) + type 2:1 clay minerals (illite + vermiculite) (Fig. 12 right side; Supplemental Material 1). At shallower levels, where weathering was more intense, the development of calcined clay as an SCM increased to values close to 100% SAI and even exceeded this value at 650 and 750°C, which reflected a net gain in mechanical strength at these temperatures. This was due to the higher kaolinite and aluminum oxide content at this depth, which, when thermally activated, caused the clay structure to disorder, resulting in more metakaolin and more pozzolanic clay. This may also be due to greater SSA of particles and structural disorder degree of kaolinite in these superficial levels in the raw state, which can decrease activation energy, facilitate destruction of OH bonds in kaolinite, and make it more reactive. Conversely, with increasing depth, mechanical development decreased because mica (muscovite) + type 2:1 clay minerals (illite + vermiculite) content increased and SSA decreased, which meant the kaolinite/(muscovite+illite+vermiculite) ratio fell to values close to 2. Thus, SAI was affected by the kaolinite/(muscovite+illite+vermiculite) ratio, P₀ index, and SSA of particles, especially at surface levels.

On the contrary, SAI increased with temperatures up to 750°C, with better mechanical development at the higher end. Then, at 850°C, mechanical development dropped sharply, which was even lower than the value obtained at 650°C. According to Tironi et al. (Reference Tironi, Trezza, Scian and Irassar2012), Fernández et al. (Reference Fernández, Alba and Torres2013), and Danner et al. (Reference Danner, Norden and Justnes2018), structural break-down and dehydroxylation cause structural disorder in clay minerals, increasing their pozzolanic reactivity and development as SCMs. Kaolinitic or 1:1 type clays are completely dehydroxylated between 500 and 600°C, while in 2:1 type clays, such as illite, vermiculite, or montmorillonite, dehydroxylation occurs at higher temperatures (800–1000°C). Thus, the calcined clay had the greatest pozzolanic activity at 750°C, which was a value within the range found in the literature (600–1000°C) (Alujas et al., Reference Alujas, Fernández, Quintana, Scrivener and Martirena2015; Yanguatin et al., Reference Yanguatin, Ramírez, Tironi and Tobón2019; Córdoba et al., Reference Córdoba, Zito, Sposito, Rahhal, Tironi and Thienel2020a, Reference Córdoba, Zito, Tironi, Rahhal, Irassar and Bishnoi2020b; Rakhimova et al., Reference Rakhimova, Rakhimov, Bikmukhametov, Morozov, Eskin and Lygina2020; Rodríguez & Tobón, Reference Rodríguez and Tobón2020; Rodríguez et al., Reference Rodríguez, Frías and Tobón2021; Sposito et al., Reference Sposito, Maier, Beuntner and Thienel2022) and was a product of its mineralogical multicomponents (the optimum temperature of activation was higher than 1:1 type clay and lower than 2:1 type).

The reduction in the SAI at 850°C may be caused by particle agglomeration or early crystallization of non-reactive phases such as spinel, due to the large amount of iron and titanium oxides. However, studies at higher temperatures are necessary for effective confirmation, as are complementary studies such as SEM and PSD.

The physical test of pozzolanicity (SAI) was contrasted with the chemical test of pozzolanicity and the Frattini test (Fig. 13; Supplemental Material 1), which discriminated by lithology and by the horizon of the weathering profile for a better understanding of the pozzolanic activity.

Fig. 13 Frattini test at 28 curing days of the clay mortars from the paragneiss (left) and ortho-amphibolite (right) weathering profiles calcined at temperatures of 650, 750, and 850°C. RT: room temperature

Chemical test results (Fig. 13) revealed a similar trend between Frattini and SAI results; in other words, multicomponent clays only had pozzolanic activity when they were calcined, with better results in the first horizons of the weathering profile (VI and V) and at 650 and 750°C, this latter temperature being better because of its greater distance in height with respect to the lime saturation curve. Likewise, the trend of a decrease in pozzolanic activity at 850°C was maintained (displacement vector with a tendency to the region above the lime saturation curve), as happened in SAI. For these reasons, Frattini was also affected by mineralogy (kaolinite/(muscovite+illite+vermiculite) ratio), chemical composition (aluminium oxide), weathering (CIA and horizons), crystallinity (P₀), and physical variables (SSA).

On the other hand, Frattini results showed no pozzolanicity in samples of horizons IV–III/ortho-amphibolite and horizon V/paragneiss calcined at 650 and 750°C, which were contrary to what was determinated by SAI. This was possibly due to the muscovite + illite content in the raw clays of these horizons (28 and 23%, respectively), which was higher than other horizons (Fig. 7). The illite content of the clay must be optimal because its presence can cause an effect similar to that of the filling system (no chemical interaction between cement and this calcined clay). According to Fernández et al. (Reference Fernández, Martirena and Scrivener2011), the layered structure of illite is largely preserved during dehydroxylation so the octahedral Al and tetrahedral Si do not react easily with Ca²⁺ ions released during cement hydration, resulting in less C-S-H gel formation and lower mechanical strength. SAI is very sensitive to this type of physical interaction. When the type 2:1 clay minerals are treated at low temperatures, they are not fully activated. Consequently, they do not have their full chemical interaction with the cement. This is evidenced in Fig. 13 when, upon reaching the maximum temperature (850°C), the points of each of these materials were located on the saturation curve or slightly below it. The interaction of these materials with the cement, then, was probably more physical than chemical, which is why their pozzolanic effect was seen in SAI but not in Frattini.

For the reasons stated above, regardless of lithology, weathering horizon profile, or calcination temperature (650, 750, or 850°C), the mica (muscovite) + type 2:1 clay minerals (illite + vermiculite) content of multicomponent calcined clay must not exceed 9% in order to be used as an SCM; or its calcination temperature must be >850°C when it exceeds this value, taking lithology and weathering horizon profile into account (the greater content of type 2:1 clay minerals raised the activation temperature of the sample and decreased its pozzolanic activity).