Development of a geo-environmental characterization protocol

Vermette (Reference Vermette2018) proposed a protocol to define geo-environmental domains from exploration data, which were then subdivided into geo-environmental units at the pre-feasibility and feasibility stages of the mine development, based on the Akasaba Ouest mine project (Vermette Reference Vermette2018). The proposed protocol begins at the start of the mine cycle where core log data are interpreted with an emphasis on environmental issues. It was found that core logs contained significant amount of information that can be used to estimate environmental behavior of future waste rock. The protocol provides further tests to be done at the preliminary economic assessment, pre-feasibility and feasibility steps of the mine. For the Akasaba Ouest project, the waste rocks were divided into seven geo-environmental units and three geo-environmental domains, which were included into a GOCAD model of the mine (Vermette Reference Vermette2018), as shown in Figure 2. Areas of potential AMD, copper and manganese leaching were identified, and waste management was proposed to segregate the domains and units with contamination potential.

Figure 2. Representation of waste rock characterization in the future open pit Akasaba mine; red zone is the intermediate domain, green zone is the mafic domain, yellow zone is the dacitic domain. Dots represent samples with ratios of neutralization potential RNP > 3 (green) and RNP < 1 (red). (Vermette, Reference Vermette2018).

The work on geo-environmental characterization and modeling highlighted the need for good and representative data for numerical modeling and ultimately for environmental planning decisions. In the recent years much development of analytical tools was initiated mostly for geological investigations (Lemière and Uvarova Reference Lemière and Uvarova2019) and also for environmental assessment purposes. Indeed, Cracknell et al. (Reference Cracknell, Parbhakar-Fox, Jackson and Savinova2018) used images from Corescan to obtain automated acid rock drainage index data. Since sample availability and budget are limited in the exploration and early development stages of a mine project, a project was initiated to investigate the application of existing non-destructive core analysis methods for a preliminary environmental assessment. Duvernois tested hyperspectral analysis, portable x-ray fluorescence and carbonate staining as tools to help identify acid generating minerals and neutralizing minerals to perform a preliminary environmental assessment. These tools were first validated on samples from a well-developed mine (Laronde zone 5), where the non-destructive analysis results were compared to existing geochemical data obtained using laboratory methods, such as ICP and x-ray diffraction (Duvernois et al. Reference Duvernois, Villeneuve, Demers, Cheng and Neculita2024). Then, the proposed tools were used to provide a preliminary assessment of acid generation and metal leaching potential for lithologies of a mine site under development (O’Brien). Afterwards, typical kinetic tests in columns were performed to verify the preliminary assessment. Results indicated that while the non-destructive tools were not entirely on target in terms of AMD generation, they can provide early results and help decide on which lithologies or geoenvironmental domains to focus the upcoming environmental assessment (Duvernois et al. Reference Duvernois, Villeneuve, Demers, Cheng and Neculita2024).

A challenge that was identified in using core scanning tools is the large number of data and the need for rapid interpretation. A project was recently initiated in partnership with a mining company to merge artificial intelligence with automated core scanning to predict geoenvironmental parameters of geological deposits.

Geo-environmental planning from exploration data

Several modeling approaches were investigated and adapted to environmental planning from geological data. Toubri first analyzed the geological database of a gold deposit of an operating mine in Quebec, Roberto deposit (Eleonore mine, Newmont). An environmental challenge at this mine site was the presence of arsenic in the tailings and waste rock, therefore the project involved trying to locate the sources of potentially arsenic-enriched waste rock directly in the orebody, to then propose an extraction sequence to minimize mixing of arsenic-rich and low-arsenic waste rock. Investigation of the geology database revealed that restricted arsenic grades were available, which were insufficient to obtain a good view of the arsenic distribution in the orebody. Toubri developed a stochastic approach to correlate the limited arsenic grade available to the geological logging of arsenopyrite, which enabled to fill the missing arsenic grades and populate a 3D block model of arsenic distribution (Toubri et al. Reference Toubri, Demers and Beier2021a). The superposition of the arsenic block model with the mine plan becomes an interesting tool to plan waste rock management to minimize environmental risk associated with arsenic-bearing minerals.

However, the spatial distribution of an element cannot provide the entire story about potential environmental risk. Kinetic leaching assessments are usually required to evaluate environmental risks. Kinetic tests can be difficult to perform adequately at the early stage of a mine project when sample availability is restricted, or unrepresentative. Toubri calibrated a numerical model of weathering cell experiments of geoenvironmental domains identified by Vermette for the Akasaba Ouest site. Once calibrated and validated, the model was used for parametric analyses (variables tested: mineral assemblages and residence time) to determine the most significant parameters affecting metal leaching (Toubri et al. Reference Toubri, Vermette, Demers, Beier and Benzaazoua2021c). Knowing which mineral combinations and water flow patterns enhance metal leaching enable to plan the waste management to reduce environmental risks.

The final step in the numerical modeling aspect of geo-environmental planning was to combine spatial and kinetic models to promote proactive mine waste management, as proposed in Figure 3. Toubri integrated the approaches proposed in the first two steps (stochastic + kinetic modeling) in a fictious case study based on Akasaba Ouest and Roberto. For each block in the geological model, called a voxel, he assigned a mineralogical composition and proceeded in kinetic modeling to simulate the deposition of the given block in a surface waste rock pile exposed to atmospheric conditions (Toubri et al. Reference Toubri, Demers and Beier2022). The visualization of the effluent pH associated with each block was then proposed and becomes a useful tool to plan waste extraction and management.

Figure 3. Geo-environmental modelling process, from static to dynamic mine waste management. Modified from Toubri et al. (Reference Toubri, Vermette, Demers, Beier and Benzaazoua2021c).

Finally, Alvarez Zuniga worked on a methodology to predict the tailings management and reclamation costs depending on their geochemical parameters. Using different orebodies from the Raglan mine as the case study, he adapted the life cycle cost methodology proposed by Carneiro and Fourie (Reference Carneiro and Fourie2020) to introduce environmental impacts as a long-term monitoring factor in the life cycle cost equation. Tailings were divided into two categories: potentially acid generating (PAG) and non-potentially acid generating (NPAG). The net costs for four different configurations of tailings management were evaluated (i: PAG tailings + multilayer cover; ii: NPAG tailings + vegetation cover; iii: 10% PAG tailings + multilayer cover and 90% NPAG tailings + vegetation cover; iv: 10% PAG tailings + multilayer cover and 90% NPAG tailings + dry stack), resulting in a range of minimum and maximum values. Results indicated that the separation of acid-generating material from tailings have showed economic advantages. However, the significant spread between minimum and maximum values represented a major limitation of the applied methodology. The distribution of net costs per scenario and alternative was also analyzed, revealing that the share of environmental monitoring costs did not exceed 1% of the total waste management cost. Furthermore, it was observed that the proportion of reclamation costs within the total waste management costs increased as the tailings were less densified (Zuniga Alvarez Reference Zuniga Alvarez2023).

Fundamentals of environmental desulfurization

The desulfurization process for tailings with pyrite as the main sulfide mineral is now fairly well understood. The first project in this theme involved an evaluation of the effects of the orebody compositional variability on the performance of environmental desulfurization to produce non-acid-generating tailings. Working from ore samples from 18 zones within a gold ore deposit, it was found that sulfur content by itself was not a sufficient indicator for the success of desulfurization. Some zones had variable sulfate contents, as well as various levels of neutralizing minerals. The research proposed to consider not only sulfur (or sulfide) content in an ore to determine suitability for environmental desulfurization, but also neutralization potential (NP) as an important indicator (Demers et al. Reference Demers, Awoh, Villeneuve, Noirant and Turcotte2023, Reference Demers, Awoh, Villeneuve and Turcotte2024).

In parallel, research projects investigated the environmental desulfurization of tailings containing other types of sulfide minerals (other than pyrite). Tailings from Raglan mine, being composed mainly of pyrrhotite, were investigated by Ait-Khouia. Fundamentals of covellite flotation were examined by Botero. Experiments were also performed to use environmental desulfurization to prevent contaminated neutral drainage, especially involving sulfosalts gersdorffite, skutterudite and nickeline. In all cases, experiments were done first on pure minerals to study the interactions between mineral surfaces and collectors. It was found that the collector adsorption species varies with the sulfide mineral and influences the dosage and flotation performance (Ait-khouia et al. Reference Ait-khouia, El-bouazzaoui, Taha, Demers and Benzaazoua2023b; Botero et al. Reference Botero, Canales-Mahuzier, Serna-Guerrero, López-Valdivieso, Benzaazoua and Cisternas2022a; El-bouazzaoui et al. Reference El-bouazzaoui, Ait-khouia, Demers and Benzaazoua2022). Then, real mine tailings were desulfurized according to the parameters determined in the fundamental studies. Optimal parameters were identified for Amaruq and Raglan tailings (Ait-khouia et al. Reference Ait-khouia, Benzaazoua, Elghali, Chopard and Demers2022; El-bouazzaoui et al. Reference El-bouazzaoui, Ait-khouia, Demers and Benzaazoua2022) and a porphyry copper mine tailings (Botero et al. Reference Botero, Serna-Guerrero, López-Valdivieso, Benzaazoua and Cisternas2021), as presented in Table 1. These results suggest that environmental desulfurization can be successfully applied to tailings containing different types of sulfide minerals for the prevention of acid mine drainage and metal leaching.

Table 1. Optimal desulfurization conditions obtained in three studies

Environmental desulfurization has been considered and applied mostly on tailings from base metal and coal mines (Kotsiopoulos and Harrison Reference Kotsiopoulos and Harrison2018; Mafra et al. Reference Mafra, Bouzahzah, Stamenov and Gaydardzhiev2022). Another aspect of the research investigated its potential application to waste rock management. Since waste rocks have a wide particle size distribution, from coarse blocks to very fine particles, the desulfurization strategy has to be adapted. Using the concept of diameter of physical locking of sulfides (DPLS) (Elghali et al. Reference Elghali, Benzaazoua, Bouzahzah, Bussière and Villarraga-Gómez2018), waste rock samples from Amaruq and Centinela mines were classified by size fractions to determine the DPLS and the size fractions that require desulfurization, which were <2.5 mm for Amaruq and <2.4 mm for Centinela (between F4 and F5). Degrees of liberation per size fraction for pyrite and carbonates are presented in Figure 4. Then, depending on the size of particles to desulfurize, processes were selected and tested to reach desulfurized waste rock. Ait-Khouia tested screening, dense medium separation, gravity concentration, flotation and combinations of these processes to successfully desulfurize waste rock (Ait-khouia Reference Ait-khouia2022; Ait-khouia et al. Reference Ait-khouia, Benzaazoua, Ievgeniia and Demers2023a). Botero used flotation in a Hydrofloat unit (fluidized-bed flotation) to desulfurize particles >212 µm and Denver cell for particles <212 µm (Botero et al. Reference Botero, Demers, Cisternas and Benzaazoua2022b). These options offer new applicability for environmental desulfurization of mine waste, including waste rock.

Figure 4. Degree of liberation of pyrite and carbonates by size fraction for waste rock from Centinela and Amaruq mines.

A further objective involved flotation tests in a laboratory flotation column to investigate the influence of hydrodynamic parameters on tailings particle size distribution. Results showed that residence time had no visible impact on particle size distribution of the desulfurized tailings, but an increase in slurry density made the desulfurized tailings coarser than the feed. Using empirical relationships, saturated hydraulic conductivity in the range of 10⁻⁵ cm/s were obtained, as well as an air-entry value (AEV) of 200 and 300 cm (Guimond-Rousson et al. Reference Guimond-Rousson, Demers and Rocard2018). Air flowrate was shown to influence mainly sulfur recovery but had no effect on tailings particle size distribution.

Deposition of desulfurized tailings

Deposition of desulfurized tailings as a cover layer in a tailings storage facility is generally done by hydraulic transportation and disposal at the end of a pipe, or multiple pipes (spigots). Hydraulic slurry deposition can cause rapid settling of coarse particles and a further travel distance before settling for fine particles. This settling induced variations in saturated hydraulic conductivity (k_sat) of one order of magnitude from near the deposition point to the farther edge of the pond (Demers et al. Reference Demers, Huo-Kang and Mbonimpa2017a). Considering that hydrogeological properties are associated with particle size distribution, size segregation following tailings disposal may affect the performance of the desulfurized tailings cover to maintain a high degree of saturation. Projects were initiated to evaluate the impact of segregation on the spatial heterogeneity of hydrogeotechnical and hydrogeological properties of tailings. Using core samples extracted from a tailings pond in Abitibi, characterization was performed in layers selected from visual observations. In general, the tailings were fine-grained (P₈₀ was greater than 72%), except the tailings located deeper (100–125 cm) that were mostly coarse-grained with 29% ≤ P₈₀ ≤ 56%. Particles tended to be finer and specific gravity lower along the beach. Furthermore, the percentage of sulfide minerals, particularly pyrite, decreased along the beach from the discharge point to the pond (Temgoua Reference Temgoua2021). Oxygen consumption tests revealed that the K_r values decreased along the beach from the discharge point to the pond (Driouky Reference Driouky2020).

Geochemical performance of desulfurized tailings as cover material

The geochemical performance of covers made of desulfurized tailings was investigated, to make sure that desulfurized tailings remained non-acid generating when used in covers exposed to the atmosphere and climatic conditions. Four desulfurized tailings from gold mines in Abitibi with sulfur content between 0.11% S and 0.26% S were tested in laboratory columns as covers to prevent acid mine drainage. Although the four desulfurized tailings yielded neutral effluents with very low metal concentrations when tested individually, when used as a cover in non-optimal hydrogeological conditions (i.e., degree of saturation allowed some oxygen flux), some materials were unable to maintain neutral conditions (see Figure 5). Results indicated that the type of neutralizing and residual sulfide minerals have an effect of cover geochemical performance (Demers et al. Reference Demers, Berrouch, Plante and Pabst2020).

Figure 5. pH of column test effluents where desulfurized tailings were placed as cover over sulfidic tailings. T: uncovered tailings 12% S, LC: desulfurized tailings 0.26% S, CMC: desulfurized tailings 0.14% S, GC: desulfurized tailings 0.12% S, WC: desulfurized tailings 0.15% S (modified from Demers et al. Reference Demers, Berrouch, Plante and Pabst2020).

The geochemical evolution of desulfurized tailings is strongly related to the conditions in which they are placed. Projects investigated the impact of reducing conditions, such as in a water saturated cover, or under a cover, as well as the role of microorganisms naturally present on the mine sites (Pakostova et al. Reference Pakostova, McAlary, Marshall, McGarry, Ptacek and Blowes2022; Pinto et al. Reference Pinto, Al-Abed, Holder and Reisman2014). Results from samples collected on an inactive and uncovered mine site showed that metals and metalloids associated with various secondary phases, particularly Fe(III) oxyhydroxide phases, can be remobilized via biotic and abiotic reductive dissolution reactions if these conditions were to occur (Agau Reference Agau2023). More specific experimental work is ongoing where desulfurized tailings are placed in oxic and anoxic conditions for kinetic tests, either as individual materials (weathering cells), or as cover layer over oxidized tailings.

Valorization of desulfurization concentrates

Gold recovery from desulfurization concentrates was investigated from three desulfurization concentrates, using cyanidation and gravity recovery processes. The three concentrates behaved very differently, highlighting the need to have a detailed characterization of the gold and associated particles. Concentrate A had 1.85 g/t Au, concentrate B had 1.75 g/t Au, and concentrate C had 0.72 g/t Au. Recoveries obtained by cyanidation and gravity processes (Knelson concentrator and Mozley table) are presented in Figure 6. There was no relationship between initial gold content and recovery. Indeed, gravity separation was limited by the fine particle size, while cyanidation was limited by gold liberation. Proposed flowsheets can include the recirculation of the desulfurization concentrate into the existing cyanidation circuit, where applicable, or can include a dedicated gravity concentration circuit (Allard et al. Reference Allard, Lopez, Demers and Coudert2022).

Figure 6. Gold recovery by cyanidation and gravity processes performed on three desulfurization concentrates.

Valorization of other mine wastes

Desulfurized tailings and low-sulfide waste rock were tested as components of a cover with capillary barrier effects, both in the laboratory and field. Hydrogeotechnical monitoring of the laboratory columns and the intermediate field scale cells revealed that the contrast between the waste rock and desulfurized tailings is adequate to create a capillary barrier, to maintain the desulfurized tailings at a high degree of saturation and to reduce significantly the oxygen flux towards the reactive tailings (Kalonji-Kabambi et al. Reference Kalonji-Kabambi, Bussière and Demers2020a; Reference Kalonji-Kabambi, Bussière and Demers2020b). However, the oxygen flux reduction was not sufficient to prevent acid mine drainage, due to the highly reactive nature of the tested tailings (Kalonji-Kabambi et al. Reference Kalonji-Kabambi, Demers and Bussière2020c). The combination of desulfurized tailings and waste rock was also evaluated on an inclined surface to prevent AMD from dikes formerly built with acid generating materials and was found successful in deviating rain from infiltration into the dyke (Kalonji-Kabambi et al. Reference Kalonji-Kabambi, Bussiere and Demers2021).

Another project investigated the use of reactive waste rock as cover material, more specifically for a monolayer cover with elevated water table. Removal of fine particles was tested both as a method to reduce the contamination potential of the waste rock and to favor a capillary break between tailings and waste rock layer to prevent evaporation of the tailings pore water. Waste rock from three mine sites were separated into size fractions and tested in leaching columns to obtain the evolution of leachate quality. For two out of the three waste rocks, a significant decrease in sulfate release rate was observed when the particle size is above 1 mm, as shown in Table 2. The third waste rock is already oxidized and was found to be unsuitable for re-use as cover material, especially when exposed to the atmosphere (Sylvain et al. Reference Sylvain, Pabst and Demers2023; Reference Sylvain, Pabst and Demers2024).

Table 2. Cumulative sulfate release rates per size fraction for three waste rocks (adapted from Sylvain et al. Reference Sylvain, Pabst and Demers2023)

Treatment sludge produced by the lime neutralization process applied to acidic effluents was investigated as reclamation material. AMD treatment sludge being very fine and at low solid density, it was mixed with either waste rock, tailings or soil, as part of a cover system to prevent AMD from reactive tailings (Demers et al. Reference Demers, Benzaazoua, Mbonimpa, Bouda, Bois and Gagnon2015a, 2015b; Demers et al. Reference Demers, Mbonimpa, Benzaazoua, Bouda, Awoh, Lortie and Gagnon2017b; Mbonimpa et al. Reference Mbonimpa, Bouda, Demers, Benzaazoua, Bois and Gagnon2016). Results confirmed that AMD treatment sludge mixed with soil makes a good water retention material, with hydrogeotechnical properties required for a monolayer or part of a multilayer cover scenario. The tendency of sludge to facilitate vegetation growth began to be investigated in this project through bioaccumulation studies, which showed no bioaccumulation in roots, stems and leaves (Smirnova et al. Reference Smirnova, Demers, Bouda, Benzaazoua, Mbonimpa and Bois2013).