Green hematite depression for reverse selective flotation separation from quartz by locust bean gum
Scientific Reports volume 13, Article number: 8980 (2023) Cite this article
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Reverse cationic flotation is currently the main processing technique for upgrading fine hematite from silicates. Flotation is known as an efficient method of mineral enrichment that deals with possibly hazardous chemicals. Thus, using eco-friendly flotation reagents for such a process is an emerging need for sustainable development and green transition. As an innovative approach, this investigation explored the potential of locust bean gum (LBG) as a biodegradable depressant for the selective separation of fine hematite from quartz through reverse cationic flotation. Various flotation conditions (micro and batch flotation) were conducted, and the mechanisms of LBG adsorption have been examined by different analyses (contact angle measurement, surface adsorption, zeta potential measurements, and FT-IR analysis). The micro flotation outcome indicated that the LBG could selectively depress hematite particles with negligible effect on quartz floatability. Flotation of mixed minerals (hematite and quartz mixture in various ratios) indicated that LGB could enhance separation efficiency (hematite recovery > 88%). Outcomes of the surface wettability indicated that even in the presence of the collector (dodecylamine), LBG decreased the hematite work of adhesion and had a slight effect on quartz. The LBG adsorbed selectively by hydrogen bonding on the surface of hematite based on various surface analyses.
Due to the substantial iron and steel demands in various industries, low-grade finely disseminated iron oxide ores with complex mineralogy have been accounted as iron resources and processed with different upgrading techniques1. It was well-documented that reverse (cationic/anionic) flotation separation is the most comprehensive processing practice for enriching low-grade hematite ores, in which mineral liberations happen in fine fractions2,3. Silicates, the most typical gangue phases, would float by cationic/anionic collectors, and hematite should be depressed by depressants4,5,6. However, a massive volume of materials must be fed to the flotation circuits for upgrading hematite from these low-grade ores, which require a substantial quantity of reagents. These facts emerge from using selective and eco-friendly flotation chemicals throughout the process, enhancing process efficiency and reducing potential environmental issues7,8. Thus, several investigations have been conducted to explore a green approach for upgrading low-grade hematite ores by considering eco-friendly biodegradable depressants1,9,10,11,12,13,14,15,16,17.
Different depressants such as Starch18,19,20,21, Dextrin9,10,17, Carboxyl Methyl Cellulose12,13, humic acids14,15, and Tannin16 have been successfully examined for such a purpose. These studies indicated that developing environmentally friendly depressants for the reverse flotation separation of hematite would facilitate the green transition toward sustainable development and cleaner production. Thus, it is essential to examine various biodegradable depressants, such as polysaccharide-base, polyphenolic-based, and lignosulfonate-based, for hematite depression and explore their adsorption mechanisms through selective separation.
Locust bean gum (LBG) is a hydrocolloid extracted from the Ceratonia siliqua tree, also known as carob, and is widely used in the food industry22. LBG is a galactomannan polysaccharide with high molecular weight and has similar monomeric structures to the guar gum and tara gum23. LBG has been successfully used as a depressant for the flotation separation of chalcopyrite from various minerals (Table 1). It was reported that LBG could be selectively depressed by sulfide minerals (sphalerite, pyrite, and galena) and talc. LBG deactivates talc surface by physical adsorption, mainly driven by hydrogen bonding. It would stretch the shear plane of the electrical double layer on the surface of talc particles and reduce their electrical charge magnitude24. In contrast, it showed chemical adsorption on the sphalerite surface via interaction with the oxidation products25. It was also documented that LBG showed physisorption on the pyrite and galena surface, while this adsorption was weaker on the chalcopyrite particles23,26. Surprisingly, the application of LBG as a selective depressant for flotation separation of hematite-quartz has not been reported.
Therefore, as a novel approach, this study is going to examine LBG depression properties for the flotation separation of hematite from quartz during the reverse cationic flotation (by dodecylamine (DDA) as a collector). Single mineral micro-flotation experiments were initially carried out to reveal the effects of LBG on the depression of hematite. Various synthetic hematite and quartz mixtures were used further to explore process selectivity. The wettability of minerals was explored in the absence and presence of LBG and assessed by contact angle measurements at various collector concentrations. Surface characterization was conducted to identify the adsorption mechanism of LBG on both material surfaces.
Hematite and quartz ores were collected from various mining in Kerman and Bandarabas provinces, respectively. A jaw crusher and dry milling were used for crushing bulk samples. The fine particles were sieved, and the particle size distribution of − 75 + 38 μm was applied for micro-flotation. The d80 of hematite and quartz were 58 and 62 m\(\upmu\), respectively. The hematite sample was not completely pure and enriched with one magnetic separation, followed by a Mozley table to improve the iron grade and remove impurities. The samples were characterized and analyzed by X-ray diffraction (XRD) using a D8 Advance AXS Bruker, and X-ray fluorescence (XRF) using a Perkin Elmer Optima 4300 XRF. The XRD spectra of the hematite and quartz samples (Fig. 1) have confirmed the purity of the minerals. The XRF analysis verified the samples' relatively high purity, the iron content of the hematite sample is 95.5%, and the silica content of the quartz sample is 97.75% (Table 2).
XRD analyses of the hematite and quartz samples.
LBG (molecular weight 226.66 g/mol, Aldrich grade, < 20 mm) as the hematite depressant was purchased from Pishgaman Company in Tehran, Iran. LBG was available as a solid white powder at room temperature (Fig. 2). Since LBG is a type of polysaccharide, it does not dissolve well in water at 20–30 °C. Therefore, it requires preliminary preparation23,25,26,27. For the preparation, LBG powder was mixed with Sodium hydroxide and distilled water in a 250 mL conical flask and placed in a hotplate, continuously stirring using a magnetic stirrer until a homogeneous opaque liquid was used obtained.
Structural formula of locust bean gum22.
Dodecylamine CH3(CH2)11NH2 was considered as the collector. Because long-chain amines are only slightly soluble in water, they were dissolved using hydrochloric acid29. It should be noted that HCl (hydrochloric acid) was used to prepare the collector and pH modifier, and NaOH is also used as a pH regulator. All solutions were prepared with specified concentrations using distilled water.
The micro-flotation tests for the single pure minerals were carried out in an 80 mL Hallimond tube. The fixed speed of the mechanical stirrer and the aeration rate were 650 rpm and 100 mL/min, respectively. In all experiments, 1.0 g of pure minerals and around 75 mL of distilled water were mixed in the tube and were conditioned for 1 min under constant agitation. The solution's pH was set at 10. After that, depressant (for 3 min) and collector solution (for 1 min) were added, respectively. Finally, flotation was carried out for 1 min. The pH level was monitored throughout the conditioning process. The flotation product was dried in an oven at 50 °C and accurately weighed before further characterization. Each condition through micro-flotation tests was repeated five times to ensure the results’ reproducibility.
The mineral mixture test was carried out in the mass ratio of 75:25 "hematite: quartz". The batch flotation test was conducted using a 1 L Denver D12 laboratory flotation cell. The solid percentage and the agitation rate were set at 30% and 1100 rpm, respectively. The airflow rate was 5 L/min. The collector and depressant concentrations were used at 150 and 300 g/t, respectively. The same conditioning and reagent addition times as the micro-flotation tests were considered, while the flotation time was 2 min. The froth products and tails were dried in an oven at 50 °C and accurately weighed before further characterization. Recovery was calculated based on the dry weight (Eq. 1) and chemical analyses. The experiments were carried out in duplicate, with the average values reported. Moreover, a real ore (Fe total 46.67%, SiO2 13.7%, P 1.7%) was provided, drily milled, and similar experiments were conducted to assess the locust bean gum depression capability.
where f, t, and c, are grade of Fe on the feed, tail and concentrate.
Contact angle measurements were conducted to characterize the surface wettability of minerals in both the absence and presence of reagents. The Sessile Drop Method (SDM) was used to determine the contact angle using the goniometer DSA25 (provided by Kruss, Germany). The minerals plate surface was pre-conditioned with flotation reagents. Subsequently, using a glass syringe and a needle with diameters of 0.510 and 0.487 mm, a water droplet was gently deposited on the mineral's surface to determine the contact angle. All measurements were taken at room temperature. The Kruss software automatically measures the system's three-phase contact points between the baseline and the fitted bubble shape to provide an accurate contact angle measurement. Because they can fit the bubble boundaries and baseline, the Young–Laplace, ellipse, and circle fitting models were used. . It was generally known that Young–Laplace is the most trustworthy model for measuring tiny angles, whereas ellipse fitting is more accurate for calculating greater contact angle, often exceeding 40°. Hematite and quartz's contact angles were measured both with and without LBG (300 mg/L). Using various concentrations of DDA (0, 5, 30, 50, and 75 mg/L). The work of adhesion and spreading coefficient values were calculated based on Eqs. (2) and (3) using the means of the measured contact angles and their standard deviations for each experimental condition.
where Wa, S, θ, and γLV represent the work of adhesion (erg/cm2), spreading coefficient (erg/cm2), contact angle (°), and the surface tension of water (mN/m) in the order.
The solution depletion technique was used for adsorption studies. In this procedure, 1.0 g of each pure mineral was added to a 40 mL solution containing a certain concentration of LBG, and the pH was then adjusted to the desired level. For 2 h at room temperature, the flasks were stirred at 220 rpm. The flasks were left standing (still, not shaken) for 1 h to allow the suspended solids was settling naturally. A 25 mL pipette was used to remove the supernatant, which was then centrifuged for 15 min at 6,000 rpm in a lab-scale centrifuge. Thermo gamma metric's Helios Alpha UV–Vis Spectrophotometer was then used to measure the remaining LBG content at a wavelength of 279 nm. The difference between the original and residual concentrations was used to compute the adsorption of LBG on the mineral surfaces (Eq. 4).
where C1 and C2 represent the first and final LBG concentrations (mg/L), respectively. qe is the equilibrium adsorption capacity of the adsorbent (mg/g), V is the volume of the solution (L), and m is the weight of the minerals (g). Freundlich and Langmuir adsorption isotherms were applied to understand the LBG adsorption mechanisms on the mineral's surface (Eqs. 5 and 6, respectively). The n and KF factors for the Freundlich adsorption isotherm and the qm and KL factors for the Langmuir adsorption isotherm were determined, respectively.
The zeta potential on the mineral's surface was measured using a Zetasizer Nano ZS. Zeta potential measurements were performed at pH values of 2, 4, 7, 9, 10, and 11 in the presence of 300 mg/L LBG and its absence. 1 g of mineral sample was added to a 100 mL pre-conditioned solution. A magnetic stirring was used to condition the suspension. The pH level was monitored and maintained during conditioning. A digital pH-meter electrode was positioned within the solution during conditioning, and the pH level was continuously checked. The suspension was allowed to stand for 5 min for settling the particles. A 3 mL supernatant sample was taken out and used to determine the zeta potential. The findings of all tests, which were all conducted at room temperature, were the mean of three separate measurements.
The Fourier transform infrared (FTIR) spectrometry was applied to discover the molecular structures and the functional groups on the surface of pure single minerals before and after conditioning with LBG. In order to condition the samples, 1.0 g of each pure sample was added to an aqueous solution containing 300 mg/L of LBG, and the samples were then conditioned for 6 h (pH 10). The particles were filtered and dried for 24 h at room temperature. 1% weight of KBr (potassium bromide) was added to the mineral sample. The spectra of pure minerals (untreated) were also analyzed to make a comparison.
Hematite reverse flotation separation from quartz is commonly known to take place at pH 1030. Micro-flotation test results (Fig. 3) at a DDA concentration of 30 mg/L showed that the recovery of quartz and hematite were 94 and 75%, respectively. The recovery of quartz and hematite did not significantly change till the DDA concentration reached 75 mg/L. Micro-flotation outcomes released that without the addition of LBG, quartz, and hematite both would be floated even at the low DDA concentration (Fig. 3). However, by adding and increasing the LBG concentration, the floatability of hematite was significantly dropped (Fig. 4). While the quartz floatability and recovery showed a negligible decrease (Fig. 4). The LBG dosage was set at 300 mg/L since the hematite depression did not markedly improve above it.
Effect of DDA on the floatability of pure hematite and quartz in the absence of depressant at pH = 10.
Effect of LBG on the floatability of pure hematite and quartz (in the presence of collector; 30 mg/L of DDA) at pH = 10.
Batch flotation test with a mass ratio of 75:25 "hematite: quartz" was conducted (Fig. 5). Batch flotation outcomes highlighted that the Fe grade, Fe recovery, and Si recovery in concentrate were 56.6, 88.1, and 37.5%, respectively. These results generally agreed with the previous investigations, indicating a reasonable grade and recovery could be obtained with a single-stage flotation1,14,16. These findings showed that LBG could selectively depress hematite and enhance flotation efficiency. Experiments on the real ore samples indicated that Fe recovery through the rougher and cleaner stage would be 85.41%.
Fe grade, Iron recovery, and Si recovery of achieved iron concentrate from hematite and quartz mixtures flotation (in the presence of 150 g/t DDA, 300 g/t LBG, and pH value of 10).
The surface wettability of quartz and hematite was investigated by measuring their work of adhesion based on contact angle in the presence and absence of LBG and as a function of DDA concentration. Results (Fig. 6a–d) showed that increasing collector concentration reduced the work of adhesion for both minerals, indicating that DDA decreased their surface energy. Other studies have also reported similar findings where the Wa values for aqueous solutions decreased as the concentration of cationic collectors increased31.
Wettability parameters of pure quartz and hematite in the presence or absence of 300 mg/L LBG at pH = 10 as a function of DDA concentration.
The results of wettability were consistent with the micro-flotation outcomes, which demonstrated that increasing collector concentration improved the floatability of both quartz and hematite minerals (Fig. 3). Lelis et al. (2019, and 2022) showed that the quartz surface energy was getting significantly lower than the hematite by increasing cationic collector concentrations32,33. These data illustrated the LBG-treated quartz was more hydrophobic. The spreading coefficient products, which show how one liquid spreads over a solid phase, showed a comparable pattern for both quartz and hematite minerals. A high negative spreading coefficient value is preferred for flotation separation34. It was indicated that the hydrophobicity of the quartz was considerably greater than the treated hematite with LBG, which supported the results of the micro-flotation test. The observed phenomena in the study, where the quartz mineral exhibited higher hydrophobicity than the LBG-treated hematite mineral, may be attributed to the DDA ions having a greater electrostatic attraction to the quartz surface than the LBG-treated hematite surface. This electrostatic attraction may have been further enhanced by forming hydrogen bonds between the DDA ions and the silanol groups on the quartz surface32,35,36,37. Surface wettability outcomes (Fig. 6a) also indicated that the LBG-treated hematite had a higher work of adhesion than the untreated hematite samples. This high adhesion could be correlated to a higher affinity of the LBG-treated hematite for water. In other words, even in the presence of DDA, LBG significantly depressed the hematite surface compared to quartz. In the presence of the collector, the spreading coefficient of the LBG-treated hematite further demonstrated that its surface was turned to be fully wet. On the other hand, quartz exhibited a different response (Fig. 6d), with lower levels of its spreading and adhesion work in the presence of LBG than hematite. It was found that the addition of LBG only slightly changed the wettability of quartz in the presence of DDA. These results support the micro-flotation findings, which showed that quartz showed high floatability even when LBG was present (Fig. 4).
Based on the assessment of LBG adsorption on the surfaces of quartz and hematite, it was found that increasing the LBG concentration resulted in an increase in the amount of adsorbed LBG on both mineral surfaces (as shown in Fig. 7). However, the amount of LBG adsorbed on the hematite surface was much higher compared to that on the quartz surface, even across a wide range of LBG concentrations. Specifically, when the LBG concentration reached 150 mg/L, the adsorption quantity of LBG on the hematite surface was 2.3 mg/g, while on the quartz surface, it was only 0.57 mg/g at the same concentration. This indicates that LBG has a stronger adsorption interaction with the hematite surface than with quartz.
Adsorption amount of LBG on the hematite and quartz as a function of LBG concentration at pH = 10 (particle size: + 38–75 μm).
Additionally, the adsorption equilibrium data were analyzed using the Freundlich and Langmuir isotherm equations, and the results (as shown in Table 3) indicated that the Langmuir isotherm model was a more appropriate fit for declaring LBG adsorption on the mineral surfaces due to its higher correlation coefficients. Furthermore, the qm values of hematite and quartz were found to be 3.90 and 0.86, respectively, suggesting that the interaction of LBG with hematite is significantly stronger than that with quartz.
The zeta potential measurements (Fig. 8) indicated that bare quartz and hematite's IEP (isoelectric point) occurred at pH 2 and about 4.2, respectively. Similar values were reported in various investigations16,38,39,40,41. The zeta potentials on the surface of both hematite and quartz virtually remained more negative as the pH values increased and were negative over the flotation pH range. However, when LBG was added (300 mg/L), the zeta potentials of both treated minerals were increased compared to their untreated minerals. The variation on the hematite surface in the presence of LBG was higher than in quartz, indicating that LBG was adsorbed more on the hematite surface. These results are compatible with the outcomes of wettability and adsorption analyses. However, the magnitude of surface charge for both minerals remained unaffected. This phenomenon could be due to the non-ionic polymeric properties of LBG, a polysaccharide with many hydroxyl groups with non-ionic polymeric characteristics42. The observed variations were caused by the movement of the sliding plates of double electric layers at the mineral interfaces affected by LBG adsorbed onto the surfaces of both minerals24,43.
Zeta potentials of hematite and quartz at different pH values in the presence of 300 mg/L LBG.
According to the FT-IR analyses (as shown in Fig. 9), the spectrum of LBG displayed a broad band at 3425.41 cm−1, which is associated with the stretching vibration of –OH groups. The C–H stretching vibration of alkyl –CH and –CH2 groups were observed at 2927.41 cm−1, and the C–O–H stretching vibration was present at 1022.08 cm−1 44,45. The chemical structures of LBG contain oxygen-containing functional groups, such as carboxyl and hydroxyl, which cause LBG to interact with the surfaces of metallic minerals. As seen in (Fig. 9a), the characteristic bands of hematite appeared at 476.33 cm−1, 551.54 cm−1, and 1087.45 cm−1, which were related to the Fe–O vibration (Metal-O) and –OH stretching vibration46. When LBG-treated hematite surface showed (Fig. 9a), new peaks appeared at 3426.88 and 2366.22 cm−1, related to the stretching vibration of hydroxyl groups –OH groups and the stretching vibrations of the –CH2 from the LBG spectrum, respectively. These results suggest that LBG molecules were effectively adsorbed on the hematite surface. The presence of many hydroxyl groups in LBG's structure may have facilitated hydrogen bonding, making adsorption between LGB and the hematite surface possible. On the other hand, characteristic bands for quartz particles were observed at 1083.79 cm−1, 798.38 cm−1, and 462.83 cm−1 (silanol groups and –OH bands) (Fig. 9b). When quartz was treated with LBG, no new characteristic peaks appeared in the quartz + LBG spectrum (Fig. 9b). These spectra and zeta potential measurement demonstrated that LBG interacts weakly with the quartz surface. Thus, LBG can be used as a selective depressant of hematite in flotation separation from quartz.
FT-IR spectra of (a) Hematite and (b) Quartz treated with 300 mg/L of LBG.
According to the results, LBG has the potential to act as an effective hematite depressant in reverse cationic flotation. Results obtained from micro-flotation tests indicated that LBG could significantly decrease the floatability of hematite while having a negligible impact on the recovery of quartz. Surface characterization analyses showed that the hydrophobicity of quartz was considerably higher than that of hematite when treated with LBG, which corroborated the results of the micro-flotation experiments (Fig. 3).
Based on the Wettability data (Fig. 6), the surface energy of quartz is much lower than hematite. Hematite is exposed to Fe3+ and O2− on its surface, while quartz has Si4+ and O2−. A high proportion of Si4+ cations and a low proportion of metallic cations on the quartz surface increased the adsorption of amine species and, consequently, improved floatability47. In contrast, metal sites on mineral surfaces play a significant role in the adsorption of depressants. The result showed that the quantity of LBG adsorbed on the surface of hematite was significantly greater than that on the quartz surface. Based on the zeta potential measurement (Fig. 8), LBG has fewer interactions with the quartz surface. When LBG add to the process, the hematite zeta potential becomes less positive, increasing the potential difference between hematite and quartz and improving separation. However, due to the unfavorable basicity and the constant IEP of quartz at a pH of 2, LBG generally does not interact with quartz (Fig. 8). Conversely, hematite interacts more strongly with high polysaccharide adsorption densities because it has an IEP of 4.2 pH, according to zeta potential tests. Thus, the LBG's adsorption on the hematite surface is attributed to the interaction between the metallic ions on the hematite surface and the anionic functional groups of LBG.
These findings are supported by FTIR analysis (Fig. 9). The chemical structure of LBG includes oxygen-containing functional groups, carboxyl, and hydroxyl, which were detected in the FTIR spectra. In an alkaline environment, numerous free carboxyl groups were present in the LBG solution, which has a potent complexing effect with multivalent metal ions46. Thus, LBG had a higher affinity for the hematite surface than quartz. The adsorption between LBG and the hematite surface was attributed to hydrogen bonding, specifically involving the Fe–O vibration (Metal-O) and –OH stretching vibration. The interaction between polysaccharides and hematite has been characterized as an acid/base interaction, where the polysaccharide acts as an acid, and the hematite surface serves as a base48,49. Adsorbing LBG selectively onto the hematite surface would hinder DDA adsorption; thereby, hematite would be selectively depressed. However, since LBG has weak adsorption to quartz, a large amount of DDA was adsorbed on quartz, which aided in achieving a high quartz recovery.
In this study, the depression effect of locust bean gum (LBG), as a novel and environmentally friendly depressant, for the selective separation of hematite and quartz through reverse cationic flotation was investigated through various flotation conditions. Micro-flotation results illustrated that LBG could significantly reduce the hematite floatability even at a low concentration (30 mg/L) with an insignificant effect on the quartz recovery. The batch flotation experiment revealed that LBG has a high selectivity for hematite depression, with Fe grades and Fe recovery in concentrates of 56.6 and 88.1, respectively. Various surface analyses showed that the LBG adsorption on hematite and quartz differed significantly. The wettability analysis indicated that by increasing the collector concentrations, the surface energy of quartz was significantly lower than hematite; thus, the quartz hydrophobicity was significantly higher than the LBG-treated hematite. Moreover, the difference in adhesion between LBG-treated hematite and untreated samples was very substantial. Adding LBG only slightly changed the wettability of quartz in the presence of DDA. Surface adsorption analysis depicted that LBG interacted with the hematite surface more strongly than quartz, while at the concentration of 300 mg/L LBG, the adsorption quantities of hematite and quartz were 3.3 and 1.7 (mg/g), respectively. The FT-IR outcomes revealed that LBG molecules were adsorbed via hydrogen bonding on the hematite surface and interacted weakly with the quartz surface.
The datasets used and/or analysed during the current study available from the corresponding author on reasonable request.
Tohry, A. & Dehghani, A. Effect of sodium silicate on the reverse anionic flotation of a siliceous–phosphorus iron ore. Sep. Purif. Technol. 164, 28–33 (2016).
Article CAS Google Scholar
Rocha, L., Cançado, R. Z. L. & Peres, A. E. C. Iron ore slimes flotation. Miner. Eng. 23, 842–845 (2010).
Article CAS Google Scholar
Quast, K. Literature review on the use of natural products in the flotation of iron oxide ores. Miner. Eng. 108, 12–24 (2017).
Article CAS Google Scholar
Arantes, R. S. & Lima, R. M. F. Influence of sodium silicate modulus on iron ore flotation with sodium oleate. Int. J. Miner. Process. 125, 157–160 (2013).
Article CAS Google Scholar
Araujo, A. C., Viana, P. R. M. & Peres, A. E. C. Reagents in iron ores flotation. Miner. Eng. 18, 219–224 (2005).
Article CAS Google Scholar
Ma, X., Marques, M. & Gontijo, C. Comparative studies of reverse cationic/anionic flotation of Vale iron ore. Int. J. Miner. Process. 100, 179–183 (2011).
Article CAS Google Scholar
Yang, B. et al. Selective collection performance of an efficient quartz collector and its response to flotation separation of malachite from quartz. Miner. Eng. 172, 107174 (2021).
Article CAS Google Scholar
Wang, L. et al. Selective separation of hematite from quartz with sodium oleate collector and calcium lignosulphonate depressant. J. Mol. Liq. 322, 114502 (2021).
Article CAS Google Scholar
Zhang, M., Xu, Z. & Wang, L. Ultrasonic treatment improves the performance of starch as depressant for hematite flotation. Ultrason. Sonochem. 82, 105877 (2022).
Article CAS PubMed Google Scholar
Wang, D. & Liu, Q. Influence of aggregation/dispersion state of hydrophilic particles on their entrainment in fine mineral particle flotation. Miner. Eng. 166, 106835 (2021).
Article CAS Google Scholar
Qi, G. W., Klauber, C. & Warren, L. J. Mechanism of action of sodium silicate in the flotation of apatite from hematite. Int. J. Miner. Process. 39, 251–273 (1993).
Article CAS Google Scholar
Shrimali, K. & Miller, J. D. Polysaccharide depressants for the reverse flotation of iron ore. Trans. Indian Inst. Met. 69, 83–95 (2016).
Article CAS Google Scholar
Poperechnikova, O. Y., Filippov, L. O., Shumskaya, E. N. & Filippova, I. V. Intensification of the reverse cationic flotation of hematite ores with optimization of process and hydrodynamic parameters of flotation cell. J. Phys. Conf. Ser. 879, 012016 (2017).
Article Google Scholar
Tohry, A., Dehghan, R., Zarei, M. & Chelgani, S. C. Mechanism of humic acid adsorption as a flotation separation depressant on the complex silicates and hematite. Miner. Eng. 162, 106736 (2021).
Article CAS Google Scholar
dos Santos, I. D. & Oliveira, J. F. Utilization of humic acid as a depressant for hematite in the reverse flotation of iron ore. Miner. Eng. 20, 1003–1007 (2007).
Article Google Scholar
Tohry, A., Dehghan, R., de Salles Leal Filho, L. & Chehreh Chelgani, S. Tannin: An eco-friendly depressant for the green flotation separation of hematite from quartz. Miner. Eng. 168, 106917 (2021).
Article CAS Google Scholar
Mineralurgii, F. P. Dextrins As Selective Flotation. 36, 273–278 (2002).
Google Scholar
Veloso, C. H., Filippov, L. O., Filippova, I. V., Ouvrard, S. & Araujo, A. C. Investigation of the interaction mechanism of depressants in the reverse cationic flotation of complex iron ores. Miner. Eng. 125, 133–139 (2018).
Article CAS Google Scholar
Li, K., Zhang, H., Peng, T., Liu, C. & Yang, S. Influences of starch depressant with the various molecular structure on the interactions between hematite particles and flotation bubbles. Colloids Surfaces A Physicochem. Eng. Asp. 652, 129814 (2022).
Article CAS Google Scholar
Yang, S., Li, C. & Wang, L. Dissolution of starch and its role in the flotation separation of quartz from hematite. Powder Technol. 320, 346–357 (2017).
Article CAS Google Scholar
Zhang, J., Yang, C., Niu, F. & Gao, S. Molecular dynamics study on selective flotation of hematite with sodium oleate collector and starch-acrylamide flocculant. Appl. Surf. Sci. 592, 153208 (2022).
Article CAS Google Scholar
Prajapati, V. D. et al. Galactomannan: A versatile biodegradable seed polysaccharide. Int. J. Biol. Macromol. 60, 83–92 (2013).
Article CAS PubMed Google Scholar
Shen, Z. et al. Selective depression mechanism of locust bean gum in the flotation separation of chalcopyrite from pyrite in a low-alkalinity media. Miner. Eng. 170, 107044 (2021).
Article CAS Google Scholar
Feng, B. et al. Use of locust bean gum in flotation separation of chalcopyrite and talc. Miner. Eng. 122, 79–83 (2018).
Article CAS Google Scholar
Feng, B. et al. Effect of surface oxidation on the depression of sphalerite by locust bean gum. Miner. Eng. 146, 106142 (2020).
Article CAS Google Scholar
Miao, Y., Wen, S., Shen, Z., Feng, Q. & Zhang, Q. Flotation separation of chalcopyrite from galena using locust bean gum as a selective and eco-friendly depressant. Sep. Purif. Technol. 283, 120173 (2022).
Article CAS Google Scholar
Feng, B. et al. Flotation separation behavior of chalcopyrite and sphalerite in the presence of locust bean gum. Miner. Eng. 143, 105940 (2019).
Article CAS Google Scholar
Feng, B. et al. Synergistic effect of acidified water glass and locust bean gum in the flotation of a refractory copper sulfide ore. J. Clean. Prod. 202, 1077–1084 (2018).
Article CAS Google Scholar
Partridge, A. C. & Smith, G. W. Flotation and adsorption characteristics of the hematite-dodecylamine-starch system. Can. Metall. Q. 10, 229–234 (1971).
Article CAS Google Scholar
Houot, R. Beneficiation of iron ore by flotation—Review of industrial and potential applications. Int. J. Miner. Process. 10, 183–204 (1983).
Article CAS Google Scholar
Zhang, L. et al. Wettability of a Quartz surface in the presence of four cationic surfactants. Langmuir 26, 18834–18840 (2010).
Article CAS PubMed Google Scholar
Lelis, D. F., da Cruz, D. G. & Fernandes Lima, R. M. Effects of calcium and chloride ions in iron ore reverse cationic flotation: fundamental studies. Miner. Process. Extr. Metall. Rev. 40, 402–409 (2019).
Article CAS Google Scholar
Lelis, D. F., Fernandes Lima, R. M., Rocha, G. M. & Leão, V. A. Effect of magnesium species on cationic flotation of quartz from hematite. Miner. Process. Extr. Metall. Rev. 43, 339–345 (2022).
Article CAS Google Scholar
Leja, J. Surface Chemistry of Froth Flotation (Springer, 1982).
Google Scholar
Smith, R. W. & Scott, J. L. Mechanisms of dodecylamine flotation of quartz mechanisms of dodecylamine flotation of quartz. Miner. Process. Extr. Metall. Rev. https://doi.org/10.1080/08827509008952667 (2007).
Article Google Scholar
Vidyadhar, A., Rao, K. H., Chernyshova, I. V. & Pradip & Forssberg, K. S. E.,. Mechanisms of amine-quartz interaction in the absence and presence of alcohols studied by spectroscopic methods. J. Colloid Interface Sci. 256, 59–72 (2002).
Article ADS CAS Google Scholar
Churaev, N. V., Sergeeva, I. P., Sobolev, V. D. & Jacobasch, H. Modification of quartz surfaces using cationic surfactant solutions. 164, 121–129 (2000).
CAS Google Scholar
Rao, S. R. Surface Chemistry of Froth Flotation. Springer, New York (2004). doi:https://doi.org/10.1007/978-1-4757-4302-9.
Carlson, J. J. & Kawatra, S. K. Factors affecting zeta potential of iron oxides. Miner. Process. Extr. Metall. Rev. 34, 269–303 (2013).
Article CAS Google Scholar
Rohem Peçanha, E., da Fonseca de Albuquerque, M. D., Antoun Simão, R., de Salles Leal Filho, L. & de MelloMonte, M. B. Interaction forces between colloidal starch and quartz and hematite particles in mineral flotation. Colloids Surfaces A Physicochem. Eng. Asp. 562, 79–85 (2019).
Fan, G., Wang, L., Cao, Y. & Li, C. Collecting agent–mineral interactions in the reverse flotation of iron ore: A brief review. Minerals 10, 1–22 (2020).
Article Google Scholar
Tang, M., Lei, Y., Wang, Y., Li, D. & Wang, L. Rheological and structural properties of sodium caseinate as influenced by locust bean gum and κ-carrageenan. Food Hydrocoll. 112, 106251 (2021).
Article CAS Google Scholar
Huang, P., Wang, L. & Liu, Q. Depressant function of high molecular weight polyacrylamide in the xanthate flotation of chalcopyrite and galena. Int. J. Miner. Process. 128, 6–15 (2014).
Article CAS Google Scholar
Kaity, S., Isaac, J. & Ghosh, A. Interpenetrating polymer network of locust bean gum-poly (vinyl alcohol) for controlled release drug delivery. Carbohydr. Polym. 94, 456–467 (2013).
Article CAS PubMed Google Scholar
Jana, S. & Sen, K. K. Chitosan — Locust bean gum interpenetrating polymeric network nanocomposites for delivery of aceclofenac. Int. J. Biol. Macromol. 102, 878–884 (2017).
Article CAS PubMed Google Scholar
Pavlovic, S. & Brandao, P. R. Adsorption of starch, amylose, amylopectin and glucose monomer and their effect on the flotation of hematite and quartz. Miner. Eng. 16, 1117–1122 (2003).
Article CAS Google Scholar
Severov, V. V., Filippov, L. O. & Filippova, I. V. Relationship between cation distribution with electrochemical and flotation properties of calcic amphiboles. Int. J. Miner. Process. 147, 18–27 (2016).
Article CAS Google Scholar
Liu, Q., Zhang, Y. & Laskowski, J. S. The adsorption of polysaccharides onto mineral surfaces: an acid/base interaction. Int. J. Miner. Process. 60, 229–245 (2000).
Article CAS Google Scholar
Laskowski, J. S., Liu, Q. & O’Connor, C. T. Current understanding of the mechanism of polysaccharide adsorption at the mineral/aqueous solution interface. Int. J. Miner. Process. 84, 59–68 (2007).
Article CAS Google Scholar
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The authors acknowledge the Staff of the Mineral Processing Laboratory of the University of Tehran for their technical support. This manuscript resulted from a project supported by CAMM3, the Center of Advanced Mining and Metallurgy, as a center of excellence at the Luleå University of Technology.
Open access funding provided by Lulea University of Technology. Open access funding provided by Centre of Advanced Mining and Metallurgy (CAMM3).
School of Mining Engineering, College of Engineering, University of Tehran, Tehran, Iran
Mehrdad Kordloo, Gholamreza Khodadadmahmoudi, Ehsan Ebrahimi & Ali Rezaei
Mining and Metallurgical Engineering Department, Yazd University, Yazd, 89195-741, Iran
Arash Tohry
Minerals and Metallurgical Engineering, Swedish School of Mines, Department of Civil, Environmental and Natural Resources Engineering, Luleå University of Technology, 971 87, Luleå, Sweden
Saeed Chehreh Chelgani
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M.K.: Conceptualization, Investigation, Data Curation, Funding acquisition, Resources, Experiment conduction, Writing—review & editing, Gh.Kh:. Investigation, Data Curation, Formal analysis, Software, Funding acquisition, Resources, Writing—original draft, E.E.: Investigation, Data Curation, Formal analysis, Software, Writing—original draft, A.R.: Equipment, Resources, Funding acquisition, A.T.: Project administration, Methodology, Validation, Visualization, Writing—review & editing, S.C.Ch.: Conceptualization, Supervision, Validation, Funding acquisition, Writing—review & editing.
Correspondence to Arash Tohry or Saeed Chehreh Chelgani.
The authors declare no competing interests.
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Kordloo, M., Khodadadmahmoudi, G., Ebrahimi, E. et al. Green hematite depression for reverse selective flotation separation from quartz by locust bean gum. Sci Rep 13, 8980 (2023). https://doi.org/10.1038/s41598-023-36104-5
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Received: 01 March 2023
Accepted: 30 May 2023
Published: 02 June 2023
DOI: https://doi.org/10.1038/s41598-023-36104-5
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