Ultrafine quartz flocculation: Part I. System characterization and variables selection

Silva, João Paulo Pereira da; Silva, Gilberto Rodrigues da; Martins, Afonso Henriques; Kansaon, Bruna; Peres, Antonio Eduardo Clark

doi:10.1590/0370-44672022750013

Abstract

A characterization study was performed to verify the more relevant physicochemical properties for quartz flocculation with polyacrylamide, as well as to define which variables should be further investigated regarding this flocculation system. Polyacrylamide was evaluated through molecular weight, radius of gyration, and infrared spectrometry. A natural quartz sample was investigated regarding its particle size distribution, specific surface area, mineralogical and chemical composition. The zeta potential of quartz with flocculant and surfactant was also analyzed. The results indicated that the quartz had high purity and particle sizes between 38 and 10 µm, which was within the intended particle size range; the flocculant presented a suitable molecular weight for the proposed flocculation system. Based on literature, nine variables were chosen to be investigated in Part II of this study: flocculant and surfactant concentration, flocculant and surfactant conditioning time, flocculation addition time, agitation intensity, pH of the suspension, flocculation time, and solid concentration.

keywords:
quartz; flocculation; system characterization; variables.

1. Introduction

The adsorption of flocculants and surfactants depends on the microelectrophoretic behavior of minerals which can be affected by even small variations in the type and content of impurities in the mineral lattice (Al Mahrouqi et al., 2017AL MAHROUQI, D.; VINOGRADOV, J.; JACKSON, M. D. Zeta potential of artificial and natural calcite in aqueous solution. Advances in Colloid and Interface Science, v. 240, p. 60-76, 2017.).

Contaminating crystalline species in the lattice are detected by X-ray diffraction (XRD). X-ray fluorescence (XRF) is a commonly used technique to check the purity of samples analysed by XRD, since it detects elements present at concentration below the detection limit of XRD (Carvalho et al., 2020CARVALHO, J. A. E.; BRANDÃO, P. R. G.; HENRIQUES, A. B.; OLIVEIRA, P. S.; CANÇADO, R. Z. L.; SILVA, G. R. Selective flotation of apatite from micaceous minerals using patauá palm tree oil collector. Minerals Engineering, v. 156, p. 106474, 2020.).

The degree of polymerization, measured by the molecular weight, determines the action of a polymer as flocculant, dispersant or depressant. Molecular weights above 1.000.000 Da are considered adequate for flocculating action (Attia, 1992ATTIA, Y. A. Flocculation. In: LASKOWSKI, J. S.; RALSTON, J. Colloid Chemistry in Mineral Processing. Amsterdam: Elsevier, 1992. p. 277-308. (Developments in Mineral Processing, v. 12).). Peres et al. (1994)PERES, A. E. C.; BORGES, A. A. M; GALÉRY, R. The effect of the dispersion degree on the floatability of an oxidized zinc ore. Minerals Engineering, v. 7, n. 11, p. 1435-1439, 1994. reported the use of the PAM’s SPA 15 and SPA 20, with molecular weights of 1200 Da and 2500 Da, respectively, in the successful dispersion of an oxidized zinc ore.

Different classes of flocculants are commercially available, but the most commonly used are the polyacrylamides, PAM. Based on the presence of ionic groups, PAMs are classified as non-ionic, anionic, or cationic. Most PAMs referred as non-ionic are slightly anionic containing 1-3% of anionic groups arising from the hydrolysis of amide groups (Shatat et al., 2018SHATAT, R. S.; NIAZI, S. K.; AL BATATI, F. S. Synthetic Polyelectrolytes based on polyacrylamide: non-ionic, anionic and cationic Polyacrylamides and their applications in water and wastewater treatment: literature review. Chemical Science International Journal, v. 25, n. 4, p. 1-8, 2018.). The ionic class is important regarding electrostatic interactions of PAMs.

Etheramines are surfactants which are fully dissociated in the acidic pH range. The dissociation degree decreases with the pH increase. The pH at which the concentrations of the ionized and molecular species are equal is designated as pKa. The pKa depends on the chain length and is not disclosed by the manufacturers. Fernandes (2017)FERNANDES, P. A. Efeito do tipo de éter amina na hidrofobicidade do quartzo no processo de flotação catiônica reversa de minério de ferro. 2017. 100 f. Dissertação (Mestrado em Engenharia Metalúrgica, Materiais e de Minas) - Escola de Engenharia, Universidade Federal de Minas Gerais, Belo Horizonte, 2017. reported pKa values of 9.02 for medium chain ethermonoamine, 8.87 for medium chain etherdiamine, and 8.17 for long chain etherdiamine. Rocha et al. (2021) determined the pKa of Flotigam 7100 ethermonoamine at 9.4.

Oberlerchner et al. (2015) related that for a given polymer-solvent pair, the intrinsic viscosity is a unique function of the molecular mass. The polyacrylamide viscosity is dependent on the shear rate, indicating that their solution is a non-Newtonian fluid. The viscosity decreases with increasing shear rate up to approximately 1200 rpm, after which, it becomes nearly constant (Jung et al., 2016JUNG, J.; JANG, J.; AHN, J. Characterization of a polyacrylamide solution used for remediation of petroleum contaminated soils. Materials, v. 9, n. 1, p. 16, 2016.). Another important measure of the effective size of a polymer molecule is the root-mean-square distance of the elements of the chain from its center of gravity, designated by √s², referred to as the radius of gyration of the molecule (Flory, 1953FLORY, P. J. Principles of polymer chemistry. Ithaca, N.Y.: Cornell University Press, 1953. p. 401.).

The flocculant chain length plays a key role on the adsorption process. Its contribution on collision efficiency, bridging bond and flocs strength is significant, as well as the particle sizes, which also affect the floc formation mechanism (Otsubo, 1992OTSUBO, Y. Effect of particle size on the bridging structure and elastic properties of flocculated suspensions. Journal of Colloid and Interface Science, v. 153, n. 2, p. 584-586, 1992.). There is a relevant equivalence between the flocculant molecular weight and the particle size. The agitation of the system was also indicated among the most important in flocculation, affecting the dispersion and adsorption of the flocculant molecule and the floc formation, growing, and breakage (Bulatovic, 2007BULATOVIC, S. M. Dispersion, coagulation and flocculation. In: BULATOVIC, S. M. Handbook of flotation reagents: chemistry, theory and practice: Volume 1: flotation of sulfide ores. [S. l.]: Elsevier, 2007. cap 11, p. 215-233.). The chemical environment of the solution strongly affects the flocculant efficiency. Hulston et al. (2004)HULSTON, J.; DE KRETSER, R. G.; SCALES, P. J. Effect of temperature on the dewaterability of hematite suspensions. International Journal of Mineral Processing, v. 73, n. 2-4, p. 269-279, 2004. reported that the variables: pH, ionic strength, dosage, mixing condition, among others, affect the floc structure.

In general, a high molecular weight polymer adsorbs simultaneously on the surface of several mineral particles, yielding aggregates designated as flocs. The higher sedimentation velocity of these flocs enhances the solid liquid separation. Nevertheless, flocs of ultrafine or colloidal particles present low settling velocities, rendering necessary the use of a surfactant to cause a previous aggregation stage (Campêlo et al., 2017CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.).

Baltar & Oliveira (1998)BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643. reported adsorption of PAM on colloidal silica at pH 3 and no adsorption at pH5.5. Guévellou et al. (1995) indicated that PAM adsorption on the sand surface decreased from 387 µg/m² at pH 9.5 to 3 µg/m² at pH 11.2.

McFarlane et al. (2005) measured the stirring speed in the range between 60 and 500 rpm. Better sediment consolidation was achieved in the speed range below 200 rpm and enhanced collision and aggregate formation conditions were observed between 200 and 300 rpm. It was also observed, through parabolic curves of sedimentation rate that, in this condition, the collisions were sufficient for reaching maximum flocculant adsorption and particle aggregation, keeping floc breaking at a minimum level. Owen et al. (2002) determined the formation of large and voluminous aggregates, as well as a high sedimentation rate, at 100 rpm stirring speed.

Regarding flocculant concentration, Owen et al. (2002) and Al-Hashmi et al. 2012AL-HASHMI, A. R.; LUCKHAM, P. F.; AL-MAAMARI, R. S.; ZAITOUN, A.; AL-SHARJI, H. H. The role of hydration degree of cations and anions on the adsorption of high-molecular-weight nonionic polyacrylamide on glass surfaces. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 415, p. 91-97, 2012.) investigated the range between 30 and 100 g/t. Surfactant concentrations of 1 x 10^-5 and 5 x 10^-3 were used, respectively, by Baltar & Oliveira (1998)BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643. and (Campêlo et al. 2017). Flocculant conditioning times of 15, 120, and 180 seconds were used, respectively, by Addai-Mensah et al. (2007), Ofori et al. (2011), Campêlo et al. (2017). Surfactant conditioning times of 15, 10 and 5 minutes were selected, respectively, by Raju et al. (1991), Lu & Song, (1991)LU, S.; SONG, S. Hydrophobic interaction in flocculation and flotation 1. Hydrophobic flocculation of fine mineral particles in aqueous solution. Colloids and Surfaces, v. 57, n. 1, p. 49-60, 1991., Campêlo et al. (2017).

Solid concentrations between 10 and 45 mg/L were reported by Baltar & Oliveira (1998)BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643. and Owen et al. (2002). Flocculation times between 3 and 10 minutes were mentioned by McFarlane et al. (2005) and Campêlo et al. (2017). However, none of the references consulted addressed the effects of the variables and their interactions on the flocculation process. In this sense, the knowledge of the variable interactions in a flocculation system is of high relevance concerning the process efficiency. Therefore, the motivation of this investigation was to know the characteristics of the non-ionic polyacrylamide PAM and of the natural quartz, as well as to evaluate and define the variables that affect the destabilization of an aqueous suspension of ultrafine quartz.

The multiple variables of the mineral slurry flocculation process rendered this Part I of the study essential for the knowledge of the physicochemical properties of the flocculant non ionic polyacrylamide (PAM), the characteristics of the natural quartz sample, the electrokinetic behavior of quartz after adsorption of the flocculant (PAM) and surfactant (amine EDA). These results were used for the definition of the variables and their levels to be used in the flocculation system, Part II of the study.

2. Materials and methods

The quartz sample used in the study was collected at Corinto city in Minas Gerais, Brazil, presenting crystals of approximately 15 cm which weighed a total of 3.5 kg. The sample was subjected to comminution and classification steps, whereupon a fraction in the particle size range between 38 and 10 µm was separated. To evaluate the role of surfactants on flocculation, a sample of etheramine Flotigam EDA (Clariant, Brazil) was obtained. The non-ionic polyacrylamide (PAM) was investigated as the flocculant, derived by polymerization of acrylamides, being also provided by Clariant (Brazil). Hydrochloric acid and sodium hydroxide, manufactured by Synth, were used as pH regulators.

The reagents were methylene blue, bromophenol blue, chloroform and were used in chemical analyses for the determination of charged surfactant groups present in the flocculant chemical structure, according to the methodology described by Jiang et al. (2014).

A Mastersize Micro (Malvern Instruments, United Kingdom) was used for particle size analysis and a S2 Ranger energy dispersion X-ray fluorescence spectrometer (Bruker, Germany) was used to evaluate the purity of the sample. The sample was also analyzed using an Empyrean X-ray diffraction in a diffractometer (Panalytical, United Kingdom). The specific surface area was analyzed using the BET multipoint method, in a NOVA-1000 surface area analyzer (Quantachrome Instruments, Germany).

The PAM was analyzed using Alpha II FTIR spectrometer (Bruker, Germany) ATR mode, 32 scans, at 4 cm^-1 resolution. The PAM molecular weight was determined by its inherent viscosity, with the use of a DV-I Prime viscosimeter (Brookfield, USA). The radius of gyration of the flocculant molecule was then calculated from the values of inherent viscosity and molecular weight.

The zetameter ZD3-D-G 3.0+ (Zeta Meter, USA) was used for zeta potential determinations of quartz prior to and after PAM and surfactant adsorption. Mineral aqueous suspensions were prepared in the presence of: (i) supporting electrolyte (10^-3M of NaCl), PAM (300g/t) and surfactant (10^-4M).

3. Results and discussion

The result of the particle size analysis shown in Figure 1, indicates that 100% of the material is < 38 µm and 28% is < 10 µm.

Figure 1
Particle size analysis of the quartz sample.

The results of the chemical analysis and the X-ray diffractogram of the quartz sample are shown, respectively, in Table 1 and Figure 2. It is observed that Si is the major element in the sample, being directly related to the mineral composition, which only identified quartz. No other mineral phases, which could be associate to other elements, were observed.

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Table 1
Chemical analysis of the quartz sample.

Figure 2
X-ray diffractogram of quartz sample (ƛKα Cu=1,54060Å).

Figure 3 displays the result of the specific surface area of the quartz sample, obtained via BET multipoint analysis. The results show that the specific surface area is 0.496 m²/g.

Figure 3
BET multipoint curve of the quartz sample.

Figure 4 shows the result of the PAM inherent viscosity. From extrapolation of the curve, the viscosity value found was 5.35 dl/g. Using Equation 1, given by Mark-Houwink-Sakurada (Oberlerchner et al., 2015OBERLERCHNER, J. T.; ROSENAU, T.; POTTHAST, A. Overview of methods for the direct molar mass determination of cellulose. Molecules, v. 20, n. 6, p. 10313-10341, 2015.):

Figure 4
Viscosity variation with the concentration of the PAM in the presence of NaCl (1M). Viscosity determined at 25ºC at a shear rate of 100 rpm.

(1)

[η] = K^{α}

Where: M is molar mass and K and α are the polymer and system constants (Barnes, 2000BARNES, H. A handbook of elementary rheology. Aberystwyth: The University of Wales, Institute of Non-Newtonian Fluid Mechanics, 2000. v. 1.). Considering the values of 3.7 x 10^-4 and 0.66 for K and α, respectively, the molecular weight value of the flocculant was obtained:

M = {(5.35 / 3.7 \times 10^{- 4})}^{1 / 0.66} = 2.0 \times 10^{- 6} g \cdot {m o l}^{- 1} .

The calculated PAM molecular weight, 2.0 x 10^-6 g.mol^-1, is within the range considered ideal for flocculation (Baltar & Oliveira, 1998BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643.).

The radius of gyration (R_g) of the molecule was calculated using the inherent viscosity value and the molecular weight, using Equation 2 (Otsubo & Watanabe, 1990OTSUBO, Y.; WATANABE, K. Rheological studies on bridging flocculation. Colloids and Surfaces, v. 50, p. 341-352, 1990.).

(2)

[η_{iner}] M_{w} = 6^{3 / 2} Φ {(R_{g}^{2})}^{3 / 2}

Where (R_g²)3/2 is the root mean square of gyration and Φ is the Flory-Fox parameter whose adopted value of 2.2 x 1021 dl.mol^-1.cm^-3 was suggested by Newman et al. (1954)NEWMAN, S.; KRIGBAUM, W. R.; LAUGIER, C.; FLORY, P. J. Molecular dimensions in relation to intrinsic viscosities. Journal of Polymer Science, v. 14, n. 77, p. 451-462, 1954. and Otsubo & Watanabe (1990)OTSUBO, Y.; WATANABE, K. Rheological studies on bridging flocculation. Colloids and Surfaces, v. 50, p. 341-352, 1990. and used by Baltar & Oliveira (1998)BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643.. Therefore, the calculated value of the radius of gyration is 65.2 nm. The radius of gyration of the molecule is much smaller than the particles size. On flat surfaces, the thickness of the adsorbed polymer layer is roughly of the same order of magnitude as the radius of gyration of an isolated polymer chain in solution (Otsubo, 1992OTSUBO, Y. Effect of particle size on the bridging structure and elastic properties of flocculated suspensions. Journal of Colloid and Interface Science, v. 153, n. 2, p. 584-586, 1992.).

Figure 5 presents the results of the investigation on the presence of cationic, anionic and non-ionic groups in the PAM structure. After reaction with bromophenol blue, the PAM solution did not present the blue color characteristic of cationic groups (image A). After the reaction with methylene blue and chloroform, the color of the solution changed to dark blue as the only color (image C), indicating the presence of non-ionic groups. If anionic groups were present, the solution would present different shades of blue in different layers.

Figure 5
(A) PAM + bromophenol blue, (B) PAM blank (C) PAM + methylene blue + chloroform.

The result of the FTIR analysis of non-ionic PAM is shown in Figure 6.

Figure 6
FTIR spectra of the PAM at wavelength between 500cm^-1 and 4000 cm^-1.

Bands between 472 and 1040 cm^-1 are indicated as shake and twist movements of the NH₂ group. There are two important stretching vibrations C - C in 1612 and 1650 cm^-1, such vibrations were noted by Murugan et al. (1998)MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998. in 1125 and 1176 cm^-1. These vibrations can be observed, in the spectrum of figure 6, at the wavelengths of 1119 and 1181 cm^-1.

The amide group has three characteristic peaks: 1672 cm^-1, attributed to stretching vibration - C = O; 1610 cm^-1 referring to flexion vibration - NH₂ and the 1425 cm^-1 band, indicated to stretching vibration - CN by Chiem et al. (2006), who also observed a characteristic peak in 1458 cm^-1 attributed to scissor vibration - CH₂.

The two broad peaks observed at 1598 and 1647 cm^-1 are attributed to NH₂ deformation vibration and C - O vibration, respectively. The wavelengths at 2853 and 2924 cm^-1 are associated with the symmetrical stretching of CH₂. The two high intensity bands at 3326 and 3179 cm^-1 are attributed to the N - H stretching vibrations. Analysis of the normal coordinates of polyacrylamide predicts the bands at 3338 and 3171 cm^-1, noted by Murugan et al. (1998) at 3335 and 3198 cm^-1, referring to the asymmetric and symmetric stretching vibrations of NH₂, respectively.

Therefore, the spectra of scissor vibration - CH₂ and stretching vibrations of NH₂ and - C = O indicate the presence of polyacrylamide main groups as alkane and carboxamide, respectively.

Table 2 presents the results of the PAM FTIR analysis.

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Table 2
PAM FTIR bands and assigned functional groups.

The proposed structure and composition for the PAM is presented in Table 3.

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Table 3
Proposed structure and composition for the PAM.

The zeta potential results of the quartz suspension in the presence of supporting electrolyte NaCl (10^-3M), PAM (300g/t), and surfactant (10^-4M) are shown in Figure 7.

Figure 7
Quartz zeta potential in the presence of (i) supporting electrolyte NaCl (10^-3M), (ii) PAM (300g/t), (iii) surfactant (10^-4M).

The zeta potential values in the presence amine in the pH range above the PIE, pH 2, are in agreement with the less negative surface charge of the mineral. This is explained by the adsorption of the cationic amine species on the quartz surface by an electrostatic attraction mechanism and immobilization by formation of hemimicelles proposed by Fuerstenau & Palmer (1976)FUERSTENAU, M. C.; PALMER, B. R. Anionic flotation of oxides and silicates. In: FUERSTENAU, M. C. (ed.). Flotation: A. M. Gaudin Memorial. New York: AIME, 1976. v. 1, p. 117-147. and still presently accepted (Baltar, 2021BALTAR, C. A. M. Flotação: em nova abordagem. Recife: Ed. UFPE, 2021. 537 p.).

The PAM adsorbs on the hydrophilic surface of quartz with excess negative charge through two mechanisms, first by electrostatic attraction and second by Van der Waals, adsorbing by hydrogen bonds with the PAM NH₂ group Baltar (2021)BALTAR, C. A. M. Flotação: em nova abordagem. Recife: Ed. UFPE, 2021. 537 p., therefore decreasing the amount of negative sites from the surface and, consequently, rendering the zeta potential value less negative.

When considering H bonding between the polyacrylamide and the adsorbent, Lee & Somasundaran (1989)LEE, L. T.; SOMASUNDARAN, P. Adsorption of polyacrylamide on oxide minerals. Langmuir, v. 5, n. 3, p. 854-860, 1989. indicated that, more likely, the electronegative C=O function of the amide acts as an H-bonding base and the oxide surface hydroxyls as an H-bonding acid. Therefore, not only the neutral undissociated SiOH group but also the positive SiOH²⁺ group can act as proton donors.

Although H-bonding is not considered as an electrostatic interaction, the fact that it is a bond between an electronegative and an electropositive group could render it charge dependent, therefore the positive SiOH²⁺ group should be at least as favorable or even more favorable than the neutral SiOH to form an H bond with the C - O (Lee & Somasundaran, 1989LEE, L. T.; SOMASUNDARAN, P. Adsorption of polyacrylamide on oxide minerals. Langmuir, v. 5, n. 3, p. 854-860, 1989.).

For both reagents, adsorption was favored near the isoelectric point and decreases with increasing pH, indicating that adsorption decreases as the oxide surface charge increases.

Knowledge of the properties of the system ensures better control of flocculation, in addition to assisting in the identification and evaluation of variables in the flocculation system under study.

The main flocculation variables and ranges found in literature are presented in Table 4. As each system is dependant on its unique physicochemical properties, the best flocculation conditions for quartz with PAM may be significantly different from those listed in Table 4, making it important to conduct an evaluation of these conditions and the variables synergistic interactions in the light of the characterization conducted in the present study.

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Table 4
Main variables and conditions found in flocculation systems.

4. Conclusions

The present work characterized a quartz flocculation system. The quartz mineral sample with a high degree of purity, in the size range is between 38 and 10 µm and specific surface area of 0.496 m²/g.

The calculated molecular weight of the non-ionic PAM, 2.0 x 10^-6 g.mol^-1, is within the range considered ideal for flocculation and the gyration radius of the molecule was determined to be 65.2 nm.

The FTIR spectrum showed the vibrations of the non-ionic PAM main constituents, carboxamide and alkane.

Electrokinetic determinations of quartz in the presence of the surfactant etheramine EDA showed strong adsorption near isoelectric points. The adsorption of the non-ionic PAM is favored near the isoelectric point and adsorbs by two adsorption mechanisms, electrostatic and Van der Waals binding.

The characterization of the system is relevant for the control of the flocculation process, since the physicochemical properties of each system plays an important role in the definition of its optimal operation conditions. The main variables identified in literature should then be investigated in detail to better understand the influence of these properties in flocculation.

Acknowledgements

This study was financed in part by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001.

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FERNANDES, P. A. Efeito do tipo de éter amina na hidrofobicidade do quartzo no processo de flotação catiônica reversa de minério de ferro. 2017. 100 f. Dissertação (Mestrado em Engenharia Metalúrgica, Materiais e de Minas) - Escola de Engenharia, Universidade Federal de Minas Gerais, Belo Horizonte, 2017.
FLORY, P. J. Principles of polymer chemistry. Ithaca, N.Y.: Cornell University Press, 1953. p. 401.
FUERSTENAU, M. C.; PALMER, B. R. Anionic flotation of oxides and silicates. In: FUERSTENAU, M. C. (ed.). Flotation: A. M. Gaudin Memorial. New York: AIME, 1976. v. 1, p. 117-147.
GUÉVELLOU, Y.; NOÏK, C.; LECOURTIER, J.; DEFIVES, D. Polyacrylamide adsorption onto dissolving minerals at basic pH. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 100, p. 173-185, 1995.
GREGORY, J. Polymer adsorption and flocculation in sheared suspensions. Colloids and Surfaces, v. 31, p. 231-253, 1988.
JUNG, J.; JANG, J.; AHN, J. Characterization of a polyacrylamide solution used for remediation of petroleum contaminated soils. Materials, v. 9, n. 1, p. 16, 2016.
HULSTON, J.; DE KRETSER, R. G.; SCALES, P. J. Effect of temperature on the dewaterability of hematite suspensions. International Journal of Mineral Processing, v. 73, n. 2-4, p. 269-279, 2004.
LEE, L. T.; SOMASUNDARAN, P. Adsorption of polyacrylamide on oxide minerals. Langmuir, v. 5, n. 3, p. 854-860, 1989.
LECOURTIER, J.; LEE, L. T.; CHAUVETEAU, G. Adsorption of polyacrylamides on siliceous minerals. Colloids and Surfaces, v. 47, p. 219-231, 1990.
LU, S.; SONG, S. Hydrophobic interaction in flocculation and flotation 1. Hydrophobic flocculation of fine mineral particles in aqueous solution. Colloids and Surfaces, v. 57, n. 1, p. 49-60, 1991.
MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.
MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.
NEWMAN, S.; KRIGBAUM, W. R.; LAUGIER, C.; FLORY, P. J. Molecular dimensions in relation to intrinsic viscosities. Journal of Polymer Science, v. 14, n. 77, p. 451-462, 1954.
OBERLERCHNER, J. T.; ROSENAU, T.; POTTHAST, A. Overview of methods for the direct molar mass determination of cellulose. Molecules, v. 20, n. 6, p. 10313-10341, 2015.
OFORI, P.; NGUYEN, A. V.; FIRTH, B.; MCNALLY, C.; OZDEMIR, O. Shear-induced floc structure changes for enhanced dewatering of coal preparation plant tailings. Chemical Engineering Journal, v. 172, n. 2-3, p. 914-923, 2011.
OTSUBO, Y.; WATANABE, K. Rheological studies on bridging flocculation. Colloids and Surfaces, v. 50, p. 341-352, 1990.
OTSUBO, Y. Effect of particle size on the bridging structure and elastic properties of flocculated suspensions. Journal of Colloid and Interface Science, v. 153, n. 2, p. 584-586, 1992.
OWEN, A. T.; FAWELL, P. D.; SWIFT, J. D.; FARROW, J. B. The impact of polyacrylamide flocculant solution age on flocculation performance. International Journal of Mineral Processing, v. 67, n. 1-4, p. 123-144, 2002.
PAGE, M.; LECOURTIER, J.; NOǏK, C.; FOISSY, A. Adsorption of polyacrylamides and of polysaccharides on siliceous materials and kaolinite: influence of temperature. Journal of Colloid and Interface Science, v. 161, n. 2, p. 450-454, 1993.
PERES, A. E. C.; BORGES, A. A. M; GALÉRY, R. The effect of the dispersion degree on the floatability of an oxidized zinc ore. Minerals Engineering, v. 7, n. 11, p. 1435-1439, 1994.
RAJU, G. B.; SUBRAHMANYAM, T. V.; SUN, Z.; FORSLING, W. Shear-flocculation of quartz. International Journal of Mineral Processing, v. 32, n. 3-4, p. 283-294, 1991.
SCOTT, J. P.; FAWELL, P. D.; RALPH, D. E.; FARROW, J. B. The shear degradation of high molecular weight flocculant solutions. Journal of Applied Polymer Science, v. 62, n. 12, p. 2097-2106, 1996.
SHATAT, R. S.; NIAZI, S. K.; AL BATATI, F. S. Synthetic Polyelectrolytes based on polyacrylamide: non-ionic, anionic and cationic Polyacrylamides and their applications in water and wastewater treatment: literature review. Chemical Science International Journal, v. 25, n. 4, p. 1-8, 2018.

Publication Dates

Publication in this collection
19 Sept 2022
Date of issue
2022

History

Received
24 Feb 2022
Accepted
08 Apr 2022

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ADDAI-MENSAH, J.; YEAP, K. Y.; MCFARLANE, A. J. The influential role of pulp chemistry, flocculant structure type and shear rate on dewaterability of kaolinite and smectite clay dispersions under couette Taylor flow conditions. Powder Technology, v. 179, n. 1-2, p. 79-83, 2007.

[2] ALAGHA, L.; GUO, L.; GHUZI, M.; MOLATLHEGI, O.; XU, Z. Adsorption of hybrid polyacrylamides on anisotropic kaolinite surfaces: effect of polymer characteristics and solution properties. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 498, p. 285-296, 2016.

[3] AL-HASHMI, A. R.; LUCKHAM, P. F. Characterization of the adsorption of high molecular weight non-ionic and cationic polyacrylamide on glass from aqueous solutions using modified atomic force microscopy. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 358, n. 1-3, p. 142-148, 2010.

[4] AL-HASHMI, A. R.; LUCKHAM, P. F.; AL-MAAMARI, R. S.; ZAITOUN, A.; AL-SHARJI, H. H. The role of hydration degree of cations and anions on the adsorption of high-molecular-weight nonionic polyacrylamide on glass surfaces. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 415, p. 91-97, 2012.

[5] AL MAHROUQI, D.; VINOGRADOV, J.; JACKSON, M. D. Zeta potential of artificial and natural calcite in aqueous solution. Advances in Colloid and Interface Science, v. 240, p. 60-76, 2017.

[6] ATTIA, Y. A.; FUERSTENAU, D. W. The adsorption of polyacrylamide flocculants on apatites. Colloid and Polymer Science, v. 258, n. 12, p. 1343-1353, 1980.

[7] ATTIA, Y. A. Flocculation. In: LASKOWSKI, J. S.; RALSTON, J. Colloid Chemistry in Mineral Processing. Amsterdam: Elsevier, 1992. p. 277-308. (Developments in Mineral Processing, v. 12).

[8] BALTAR, C. A. M; OLIVEIRA, J. F. Interação polímero-surfatante e seus efeitos nas características dos flocos. In: ENCONTRO NACIONAL DE TRATAMENTO DE MINÉRIOS E METALURGIA EXTRATIVA, 36.; SEMINÁRIO DE QUÍMICA DE COLÓIDES APLICADA À TECNOLOGIA MINERAL, 1. 1998, Águas de São Pedro-SP. Anais [...]. Águas de São Pedro-SP: [s. n.],1998. p. 626-643.

[9] BALTAR, C. A. M. Flotação: em nova abordagem. Recife: Ed. UFPE, 2021. 537 p.

[10] BARNES, H. A handbook of elementary rheology. Aberystwyth: The University of Wales, Institute of Non-Newtonian Fluid Mechanics, 2000. v. 1.

[11] BESSAIES-BEY, H.; FUSIER, J.; HARRISSON, S.; DESTARAC, M.; JOUENNE, S.; PASSADE-BOUPAT, N.; SANSON, N. Impact of polyacrylamide adsorption on flow through porous siliceous materials: state of the art, discussion and industrial concern. Journal of Colloid and Interface Science, v. 531, p. 693-704, 2018.

[12] BULATOVIC, S. M. Dispersion, coagulation and flocculation. In: BULATOVIC, S. M. Handbook of flotation reagents: chemistry, theory and practice: Volume 1: flotation of sulfide ores. [S. l.]: Elsevier, 2007. cap 11, p. 215-233.

[13] CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.

[14] CARVALHO, J. A. E.; BRANDÃO, P. R. G.; HENRIQUES, A. B.; OLIVEIRA, P. S.; CANÇADO, R. Z. L.; SILVA, G. R. Selective flotation of apatite from micaceous minerals using patauá palm tree oil collector. Minerals Engineering, v. 156, p. 106474, 2020.

[15] CENGIZ, I.; SABAH, E.; OZGEN, S.; AKYILDIZ, H. Flocculation of fine particles in ceramic wastewater using new types of polymeric flocculants. Journal of Applied Polymer Science, v. 112, n. 3, p. 1258-1264, 2009.

[16] CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.

[17] FERNANDES, P. A. Efeito do tipo de éter amina na hidrofobicidade do quartzo no processo de flotação catiônica reversa de minério de ferro. 2017. 100 f. Dissertação (Mestrado em Engenharia Metalúrgica, Materiais e de Minas) - Escola de Engenharia, Universidade Federal de Minas Gerais, Belo Horizonte, 2017.

[18] FLORY, P. J. Principles of polymer chemistry. Ithaca, N.Y.: Cornell University Press, 1953. p. 401.

[19] FUERSTENAU, M. C.; PALMER, B. R. Anionic flotation of oxides and silicates. In: FUERSTENAU, M. C. (ed.). Flotation: A. M. Gaudin Memorial. New York: AIME, 1976. v. 1, p. 117-147.

[20] GUÉVELLOU, Y.; NOÏK, C.; LECOURTIER, J.; DEFIVES, D. Polyacrylamide adsorption onto dissolving minerals at basic pH. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 100, p. 173-185, 1995.

[21] GREGORY, J. Polymer adsorption and flocculation in sheared suspensions. Colloids and Surfaces, v. 31, p. 231-253, 1988.

[22] JUNG, J.; JANG, J.; AHN, J. Characterization of a polyacrylamide solution used for remediation of petroleum contaminated soils. Materials, v. 9, n. 1, p. 16, 2016.

[23] HULSTON, J.; DE KRETSER, R. G.; SCALES, P. J. Effect of temperature on the dewaterability of hematite suspensions. International Journal of Mineral Processing, v. 73, n. 2-4, p. 269-279, 2004.

[24] LEE, L. T.; SOMASUNDARAN, P. Adsorption of polyacrylamide on oxide minerals. Langmuir, v. 5, n. 3, p. 854-860, 1989.

[25] LECOURTIER, J.; LEE, L. T.; CHAUVETEAU, G. Adsorption of polyacrylamides on siliceous minerals. Colloids and Surfaces, v. 47, p. 219-231, 1990.

[26] LU, S.; SONG, S. Hydrophobic interaction in flocculation and flotation 1. Hydrophobic flocculation of fine mineral particles in aqueous solution. Colloids and Surfaces, v. 57, n. 1, p. 49-60, 1991.

[27] MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.

[28] MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.

[29] NEWMAN, S.; KRIGBAUM, W. R.; LAUGIER, C.; FLORY, P. J. Molecular dimensions in relation to intrinsic viscosities. Journal of Polymer Science, v. 14, n. 77, p. 451-462, 1954.

[30] OBERLERCHNER, J. T.; ROSENAU, T.; POTTHAST, A. Overview of methods for the direct molar mass determination of cellulose. Molecules, v. 20, n. 6, p. 10313-10341, 2015.

[31] OFORI, P.; NGUYEN, A. V.; FIRTH, B.; MCNALLY, C.; OZDEMIR, O. Shear-induced floc structure changes for enhanced dewatering of coal preparation plant tailings. Chemical Engineering Journal, v. 172, n. 2-3, p. 914-923, 2011.

[32] OTSUBO, Y.; WATANABE, K. Rheological studies on bridging flocculation. Colloids and Surfaces, v. 50, p. 341-352, 1990.

[33] OTSUBO, Y. Effect of particle size on the bridging structure and elastic properties of flocculated suspensions. Journal of Colloid and Interface Science, v. 153, n. 2, p. 584-586, 1992.

[34] OWEN, A. T.; FAWELL, P. D.; SWIFT, J. D.; FARROW, J. B. The impact of polyacrylamide flocculant solution age on flocculation performance. International Journal of Mineral Processing, v. 67, n. 1-4, p. 123-144, 2002.

[35] PAGE, M.; LECOURTIER, J.; NOǏK, C.; FOISSY, A. Adsorption of polyacrylamides and of polysaccharides on siliceous materials and kaolinite: influence of temperature. Journal of Colloid and Interface Science, v. 161, n. 2, p. 450-454, 1993.

[36] PERES, A. E. C.; BORGES, A. A. M; GALÉRY, R. The effect of the dispersion degree on the floatability of an oxidized zinc ore. Minerals Engineering, v. 7, n. 11, p. 1435-1439, 1994.

[37] RAJU, G. B.; SUBRAHMANYAM, T. V.; SUN, Z.; FORSLING, W. Shear-flocculation of quartz. International Journal of Mineral Processing, v. 32, n. 3-4, p. 283-294, 1991.

[38] SCOTT, J. P.; FAWELL, P. D.; RALPH, D. E.; FARROW, J. B. The shear degradation of high molecular weight flocculant solutions. Journal of Applied Polymer Science, v. 62, n. 12, p. 2097-2106, 1996.

[39] SHATAT, R. S.; NIAZI, S. K.; AL BATATI, F. S. Synthetic Polyelectrolytes based on polyacrylamide: non-ionic, anionic and cationic Polyacrylamides and their applications in water and wastewater treatment: literature review. Chemical Science International Journal, v. 25, n. 4, p. 1-8, 2018.

Wave number (cm^-1)	Vibration	Functional group	References
472 - 1040	wagging and twisting vibration - NH₂	carboxamide	Jiang et al. 2014; *Murugan et al.* 1998**MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.
1119 - 1181	stretching vibration C - C	alkyl ethers	*Murugan et al.* 1998*MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Jiang et al.* 2014
1318	deformation vibration -CH	secondary aromatic amines	*Murugan et al.* 1998*MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998. Jiang et al*. 2014
1346	wagging vibration - CH₂	secondary aromatic amines	*Murugan et al.* 1998*MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998. Jiang et al.* 2014
1413	vibration - C - N	carboxamide	*Murugan et al.* 1998MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Chiem et al. 2006*CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.; Jiang et al.* 2014
1447	scissoring vibration - CH₂	alkanes	*Chiem et al.* 2006**CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.
1598	bending vibration a - NH₂	carboxamide	*Murugan et al.* 1998MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Chiem et al. 2006*CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.; Jiang et al.* 2014
1647	stretching vibration C = O	carboxamide	*Murugan et al.* 1998MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Chiem et al. 2006*CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.; Jiang et al.* 2014
2853 e 2924	asymmetric and symmetric stretching - CH₂	alkanes	*Murugan et al.* 1998MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Chiem et al. 2006**CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.
3179 e 3326	stretching vibration - NH₂	carboxamide	*Murugan et al.* 1998MURUGAN, R.; MOHAN, S.; BIGOTTO, A. FTIR and polarised Raman spectra of acrylamide and polyacrylamide. Journal of the Korean Physical Society, v. 32, n. 4, p. 505, 1998.; Chiem et al. 2006**CHIEM, L. T.; HUYNH, L.; RALSTON, J.; BEATTIE, D. A. An in situ ATR-FTIR study of polyacrylamide adsorption at the talc surface. Journal of Colloid and Interface Science, v. 297, n. 1, p. 54-61, 2006.

Structure and composition:e
where:	X = alkylethers
	Y = polyesther
	Y = aromatic secondary amine

A		B		C
PAM (g.t^-1)	References	Amine (mol. L^-1)	References	Surfactant conditioning time (min)	References
30 - 86	*Owen et al., 2002*OWEN, A. T.; FAWELL, P. D.; SWIFT, J. D.; FARROW, J. B. The impact of polyacrylamide flocculant solution age on flocculation performance. International Journal of Mineral Processing, v. 67, n. 1-4, p. 123-144, 2002.	3.86 x 10^-4	Lu & Song, 1991	10	Lu & Song, 1991
250	*McFarlane et al., 2005*MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.	2.26 - 27.07 x 10^-5	*Raju et al., 1991*RAJU, G. B.; SUBRAHMANYAM, T. V.; SUN, Z.; FORSLING, W. Shear-flocculation of quartz. International Journal of Mineral Processing, v. 32, n. 3-4, p. 283-294, 1991.	15	*Raju et al., 1991*RAJU, G. B.; SUBRAHMANYAM, T. V.; SUN, Z.; FORSLING, W. Shear-flocculation of quartz. International Journal of Mineral Processing, v. 32, n. 3-4, p. 283-294, 1991.
15 - 100	*Cengiz et al., 2009*CENGIZ, I.; SABAH, E.; OZGEN, S.; AKYILDIZ, H. Flocculation of fine particles in ceramic wastewater using new types of polymeric flocculants. Journal of Applied Polymer Science, v. 112, n. 3, p. 1258-1264, 2009.	1 - 8 x 10^-5	Baltar & Oliveira, 1998	5	Baltar & Oliveira, 1998
50 e 100	Al-Hashmi & Luckham, 2010AL-HASHMI, A. R.; LUCKHAM, P. F. Characterization of the adsorption of high molecular weight non-ionic and cationic polyacrylamide on glass from aqueous solutions using modified atomic force microscopy. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 358, n. 1-3, p. 142-148, 2010.	0,1 - 5 x 10^-3	*Campêlo et al., 2017*CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.	5	*Campêlo et al., 2017*CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.
15; 40; 80 e 100	Al-Hashmi & Luckham, 2012AL-HASHMI, A. R.; LUCKHAM, P. F.; AL-MAAMARI, R. S.; ZAITOUN, A.; AL-SHARJI, H. H. The role of hydration degree of cations and anions on the adsorption of high-molecular-weight nonionic polyacrylamide on glass surfaces. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 415, p. 91-97, 2012.
5 - 25	*Campêlo et al., 2017*CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.

D		E		F
Addition time (s)	References	Flocculant conditioning time (s)	References	Agitation intensity (rpm)	References
180	Attia & Fuerstnau, 1980ATTIA, Y. A.; FUERSTENAU, D. W. The adsorption of polyacrylamide flocculants on apatites. Colloid and Polymer Science, v. 258, n. 12, p. 1343-1353, 1980.	180	Attia & Fuerstnau, 1980ATTIA, Y. A.; FUERSTENAU, D. W. The adsorption of polyacrylamide flocculants on apatites. Colloid and Polymer Science, v. 258, n. 12, p. 1343-1353, 1980..	200	Gregory, 1988GREGORY, J. Polymer adsorption and flocculation in sheared suspensions. Colloids and Surfaces, v. 31, p. 231-253, 1988.
60	*Scott et al., 1996*SCOTT, J. P.; FAWELL, P. D.; RALPH, D. E.; FARROW, J. B. The shear degradation of high molecular weight flocculant solutions. Journal of Applied Polymer Science, v. 62, n. 12, p. 2097-2106, 1996.	15	*McFarlane et al., 2005*MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.	250 - 1.500	*Scott et al., 1996*SCOTT, J. P.; FAWELL, P. D.; RALPH, D. E.; FARROW, J. B. The shear degradation of high molecular weight flocculant solutions. Journal of Applied Polymer Science, v. 62, n. 12, p. 2097-2106, 1996.
5	*McFarlane et al., 2005*MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.	15	*Addai-Mensah et al., 2007*ADDAI-MENSAH, J.; YEAP, K. Y.; MCFARLANE, A. J. The influential role of pulp chemistry, flocculant structure type and shear rate on dewaterability of kaolinite and smectite clay dispersions under couette Taylor flow conditions. Powder Technology, v. 179, n. 1-2, p. 79-83, 2007.	100	Baltar & Oliveira, 1998
15	*Cengiz et al., 2009*CENGIZ, I.; SABAH, E.; OZGEN, S.; AKYILDIZ, H. Flocculation of fine particles in ceramic wastewater using new types of polymeric flocculants. Journal of Applied Polymer Science, v. 112, n. 3, p. 1258-1264, 2009.	120	*Cengiz et al., 2009*CENGIZ, I.; SABAH, E.; OZGEN, S.; AKYILDIZ, H. Flocculation of fine particles in ceramic wastewater using new types of polymeric flocculants. Journal of Applied Polymer Science, v. 112, n. 3, p. 1258-1264, 2009.	75 - 400	*Owen et al., 2002*OWEN, A. T.; FAWELL, P. D.; SWIFT, J. D.; FARROW, J. B. The impact of polyacrylamide flocculant solution age on flocculation performance. International Journal of Mineral Processing, v. 67, n. 1-4, p. 123-144, 2002.
180	*Campêlo et al., 2017*CAMPÊLO, L. D.; BALTAR, C. A. M.; FRANÇA, S. C. A. The importance of an initial aggregation step for the destabilization of an anatase colloidal suspension. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 531, p. 67-72, 2017.	120	*Ofori et al., 2011*OFORI, P.; NGUYEN, A. V.; FIRTH, B.; MCNALLY, C.; OZDEMIR, O. Shear-induced floc structure changes for enhanced dewatering of coal preparation plant tailings. Chemical Engineering Journal, v. 172, n. 2-3, p. 914-923, 2011.	60 - 500	*McFarlane et al., 2005*MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.
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G		H		I
pH	References	Flocculation time (min)	References	Solids (g/L)	References
3 - 12	Lee e Somasundaran, 1989LEE, L. T.; SOMASUNDARAN, P. Adsorption of polyacrylamide on oxide minerals. Langmuir, v. 5, n. 3, p. 854-860, 1989.	4	Attia e Fuerstnau, 1980ATTIA, Y. A.; FUERSTENAU, D. W. The adsorption of polyacrylamide flocculants on apatites. Colloid and Polymer Science, v. 258, n. 12, p. 1343-1353, 1980..	30	Lee & Somasundaran 1989
4 - 8	*Lecourtier et al., 1990*LECOURTIER, J.; LEE, L. T.; CHAUVETEAU, G. Adsorption of polyacrylamides on siliceous minerals. Colloids and Surfaces, v. 47, p. 219-231, 1990.	5	*Scott et al., 1996*SCOTT, J. P.; FAWELL, P. D.; RALPH, D. E.; FARROW, J. B. The shear degradation of high molecular weight flocculant solutions. Journal of Applied Polymer Science, v. 62, n. 12, p. 2097-2106, 1996.	20	*Page et al., 1993*PAGE, M.; LECOURTIER, J.; NOǏK, C.; FOISSY, A. Adsorption of polyacrylamides and of polysaccharides on siliceous materials and kaolinite: influence of temperature. Journal of Colloid and Interface Science, v. 161, n. 2, p. 450-454, 1993.
7 - 11,3	*Guévellou et al., 1995*GUÉVELLOU, Y.; NOÏK, C.; LECOURTIER, J.; DEFIVES, D. Polyacrylamide adsorption onto dissolving minerals at basic pH. Colloids and Surfaces A: Physicochemical and Engineering Aspects, v. 100, p. 173-185, 1995.	10	*McFarlane et al., 2005*MCFARLANE, A. J.; BREMMELL, K. E.; ADDAI-MENSAH, J. Optimising the dewatering behaviour of clay tailings through interfacial chemistry, orthokinetic flocculation and controlled shear. Powder Technology, v. 160, n. 1, p. 27-34, 2005.	10	Baltar & Oliveira, 1998
3,5 - 5,5	Baltar & Oliveira 1998	2	*Cengiz et al., 2009*CENGIZ, I.; SABAH, E.; OZGEN, S.; AKYILDIZ, H. Flocculation of fine particles in ceramic wastewater using new types of polymeric flocculants. Journal of Applied Polymer Science, v. 112, n. 3, p. 1258-1264, 2009.	45	*Owen et al., 2002*OWEN, A. T.; FAWELL, P. D.; SWIFT, J. D.; FARROW, J. B. The impact of polyacrylamide flocculant solution age on flocculation performance. International Journal of Mineral Processing, v. 67, n. 1-4, p. 123-144, 2002.
2	*Bessaies-Bey et al., 2018*BESSAIES-BEY, H.; FUSIER, J.; HARRISSON, S.; DESTARAC, M.; JOUENNE, S.; PASSADE-BOUPAT, N.; SANSON, N. Impact of polyacrylamide adsorption on flow through porous siliceous materials: state of the art, discussion and industrial concern. Journal of Colloid and Interface Science, v. 531, p. 693-704, 2018.	3	Câmpelo et al., 2017	24	Câmpelo et al., 2017