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Название Thermodynamic conditions for the presence of physically sorbed collectors on a mineral surface in an elementary act of flotation
DOI 10.17580/tsm.2024.07.02
Автор Kondratyev S. A.
Информация об авторе

N. A. Chinakal Institute of Mining, SB RAS, Novosibirsk, Russia

S. A. Kondratyev, Сhief Researcher, Head of the Laboratory of Mineral Processing and Technological Ecology, Doctor of Technical Sciences, e-mail: kondr@misd.ru

Реферат

Thermodynamic conditions for fixation of a physically sorbed collector on a mineral surface, its desorption from the mineral to the gas-liquid interface and spreading along it are considered. To analyze the conditions of fixation, the possibility of using an approach based on the theory of Lifshitz – Van der Waals (LW) and acid-base (AB) interaction of contacting media is shown. The limits of applicability of the Gibbs adsorption equation for determining the hydrophobization of the mineral surface in the flotation process have been established. The hydrophobicity generated by the chemisorbable reagent is achieved when the acid-base component is negative, exceeding the apolar component in absolute value. An analysis of the collecting properties of foaming agents is presented. It is shown that they are caused by surface activity in relation to the gas-liquid interface and the possibility of reducing the induction time, and not by hydrophobization of the mineral. A discussion is presented of reasons for the increase in the extraction of useful components into the concentrate with increasing length of the hydrocarbon fragment. This dependence is revealed from the position of the mechanism of action of physically sorbed collectors. It has been shown that the increase in hydrophobicity with increasing length of the hydrocarbon radical of the collector is associated with the irregular molecular packing of hydrocarbon chains on the mineral surface. The limited use of acid-base (AB) interaction in the flotation beneficiation method and especially in relation to sulfide minerals, the surface of which changes its AB parameters during ore preparation and flotation, has been noted. The disadvantages of this approach include the difficulty of establishing the exact values of the electron-acceptor and electron-donor parameters of floated minerals.

Ключевые слова Physically sorbed collector, free surface energy, adsorption, desorption, reagent film spreading, mineral surface, flotation
Библиографический список

1. Nguyen A. V., Schulze H. J. Colloidal science of flotation. New York: Marcel Dekker, 2004. 850 p.
2. Crawford R., Ralston J. The influence of particle size and contact angle in mineral flotation. International Journal of Mineral Processing. 1988. Vol. 23. pp. 1–24. DOI: 10.1016/0301-7516(88)90002-6
3. Babel B., Rudolph M. Investigating reagent-mineral interactions by colloidal probe atomic force microscopy. XXIV International Mineral Processing Congress. Moscow, 2018. pp. 1384–1391.
4. Laskowski J. S. Thermodynamic and Kinetic Flotation Criteria. Mineral Processing and Extractive Metallurgy Review. 1989. Vol. 5. pp. 25–41.
5. Abramov A. A. Principles of choice and synthesis of more selective collectors in flotation. Tsvetnye Metally. 2009. No. 4. pp. 35–40.
6. Van Oss C. J. Interfacial forces in aqueous media. London; New York: Taylor and Francis, 2006. 429 p.
7. Taguta J., McFadzean B., O'Connor C. The relationship between the flotation behaviour of a mineral and its surface energy properties using calorimetry. Minerals Engineering. 2019. Vol. 143. 105954.
8. An M., Liao Y., Cao Y., Hao X., Ma L. Improving low rank coal flotation using a mixture of oleic acid and dodecane as collector: a new perspective on synergetic effect. Processes. 2021. Vol. 9. 404. DOI: 10.3390/pr9030404
9. Cheng W., Deng Z., Tong X., Lu T. Hydrophobic agglomeration of fine pyrite particles induced by flotation reagents. Minerals. 2020. Vol. 10. 801. DOI: 10.3390/min10090801

10. Volpe C. D., Siboni S. From Van der Waals equation to acid-base theory of surfaces: a chemical-mathematical journey. Reviews of Adhesion and Adhesives. 2022. Vol. 10, No. 11. pp. 47–97. DOI: 10.47750/RAA/10.1.02
11. Docoslis A., Giese R. F., Van Oss C. J. Influence of the water–air interface on the apparent surface tension of aqueous solutions of hydrophilic solutes. Colloids and Surfaces B: Biointerfaces. 2000. Vol. 19. pp. 147–162.
12. Costanzo P. M., Giese R. F., Van Oss C. J. Determination of the acid-base characteristics of clay mineral surfaces by contact angle measurementsimplications for the adsorption of organic solutes from aqueous media. Journal of Adhesion Science and Technology. 1990. Vol. 4, Iss. 1. pp. 267–275. DOI: 10.1163/156856190X00298
13. Chaudhury M. K. Interfacial interaction between low-energy surfaces. Materials Science and Engineering: Reports. 1996. Vol. 16. pp. 97–159.
14. Van Oss C. J. Long-range and short-range mechanisms of hydrophobic attraction and hydrophilic repulsion in specific and aspecific interactions. Journal of Molecular Recognition. 2003. Vol. 16. pp. 177–190.
15. Van Oss C. J. Acid-base interfacial interactions in aqueous media. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 1993. Vol. 78. pp. 1–49.
16. Kondratyev S. A., Moshkin N. P. Selectivity of flotation separation of minerals due to a chemically fixed reagent. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2014. No. 4. pp. 150–158.
17. Konev V. A. Sulfide flotation. Moscow: Nedra, 1985. 262 p.
18. Zhivankov G. V., Ryaboy V. I. Collective properties and surface activity of higher aerofloats. Obogashchenie Rud. 1985. No. 3. pp. 13–16.
19. Kondratyev S. A., Ryaboy V. I. Dithiophosphates collecting ability estimation and its relationship to selectivity of valuable component recovery. Obogashchenie Rud. 2015. No. 3. pp. 25–30.
20. Kondratyev S. A. Collecting ability and selectivity of the flotation reagent. Fiziko-tekhnicheskie problemy razrabotki poleznykh iskopaemykh. 2021. No. 3. pp. 133–147. DOI: 10.15372/FTPRPI20210313
21. Horr T. J., Ralston J., Smart R. St. C. The use of contact angle measurements to quantify the adsorption density and thickness of organic molecules on hydrophilic surfaces. Colloids and Surfaces A: Physicochemical and Engineering Aspects. 1995. Vol. 97. pp. 183–196.
22. Laskowski J. S., Kitchener J. A. The hydrophilic-hydrophobic transition on silica. Journal of Colloid and Interface Science. 1969. Vol. 29, No. 4. pp. 670–679.
23. Bogdanov O. S., Golman A. M., Kakovsky I. A. et al. Physical and chemical foundations of the theory of flotation. Moscow: Nauka, 1983. 264 p.
24. O’Brien R. N., Feher A. I., Leja J. Interferometric and hydrodynamic flow profiles produced in water by a spreading monolayer. J. Colloid Interface Sci. 1975. Vol. 51, No. 3. pp. 366–372.
25. Ruckenstein E., Suciu D. G., Smigelschi O. Spreading on liquids: effect of surface tension sinks on the behavior of stagnant liquid layers. Modern Approaches to Wettability. Theory and Applications. ed. M. E. Schrader, G. Locb. New York: Plenum Press, 1992. pp. 397–422.
26. Osina N. Yu., Gorokhov A. V., Lakhtin S. V. Study of the influence of the group chemical composition of collector reagents on the efficiency of coal flotation. Gorny informatsionno-analiticheskiy byulleten. 2006. No. 2. pp. 393–396.
27. Zaikin A. E., Galikhanov M. F. Fundamentals of creating polymer composite materials. Kazan: Kazan State Technological University, 2001. 137 p.
28. Gonzalez-Garcia C. M., Gonzalez-Martin M. L., Gallardo-Moreno A. M., Gomez-Serrano V. et al. Free energy of interaction of sodium dodecyl sulfate in aqueous solution with carbon black surfaces. Journal of Colloid and Interface Science. 2002. Vol. 248. pp. 13–18. DOI: 10.1006/jcis.2001.8173
29. Malysa K., Barzyk W., Pomianowski A. Influence of frothers on floatability. I. Flotation of Single minerals (quartz and synthetic chalcocite). International Journal Mineral Processing. 1981. Vol. 8. pp. 329–343.
30. Heyes G. W., Trahar W. J. The natural floatability of chalcopyrite. International Journal of Mineral Processing. 1977. Vol. 4. pp. 317–344.
31. Suciu D. G., Smigelschi O., Ruckenstein E. Some experiments on the marangoni effect. American Institute of Chemical Engineers Journal. 1967. Vol. 3. pp. 1020–1024.
32. O'Brien R. N., Feher A. I., Leja J. Spreading of monolayers at the airwater interface. II. Spreading speeds for alcohols, acids, esters, sulphonates, amines, quaternary ammonium ions, and some binary mixtures. J. Colloid Interface Sci. 1976. Vol. 56, No. 3. pp. 474–482.

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