Mobile forms of metal speciation under electrochemical action upon sulfide minerals

Results of investigation of electrochemical processes using sulfide minerals with the emergence of mobile forms of metal speciation, able to migrate with gas streams are presented. Concentrations and phase composition of mobile components (including nanoparticles) have been determined. Conditions for the metals sorption when passing through rocks are shown. The estimate of the dispersion jet halo formation time for deep-seated ore is given.

1. Adamenko O. M. Mezozoy i Kaynozoy Stepnogo Altaya [Mesozoic and Cenozoic of the Stepnoy Altay]. Novosibirsk, Nauka, 1974, 165 p.

2. Alekseenko V. A. Ekologicheskaya geokhimiya [Ecological geochemistry]. Moscow, Logos, 2000, 627 p.

3. Baranov E. N. Endogennye geokhimicheskie oreoly kolchedannykh mestorozhdeniy [Endogenous geochemical halos of pyrite deposits]. Moscow, Nauka, 1987, 296 p.

4. Voroshilov N. A., Alekseev S. G., Shtokalenko M. B. Poiski rudnykh mestorozhdeniy po nalozhennym oreolam rasseyaniya [Search for ore deposits by superimposed dispersion halos]. Rossiyskiy geofizicheskiy zhurnal, 2016, no. 55–56, pp. 10–39. (In Russian).

5. Dukhanin A. S. Raspredelenie tyazhelykh metallov v gazovykh probakh mestorozhdeniy poleznykh iskopaemykh [Distribution of heavy metals in gas samples of mineral deposits]. Vtoraya Vsesoyuznaya konferentsiya po analizu neorganicheskikh gazov: Tezisy dokladov. Leningrad, 1990, pp. 255–256. (In Russian).

6. Dukhanin A. S., Alekseev S. G., Senchina N. P. Structure of jet-like dispersion halos of deeply buried mineral deposits in the Rudny Altai. Regional Geology and Metallogeny, 2019, no. 80, pp. 75–94. (In Russian).

7. Zyryanova L. A., Stroitelev A. D., Doronin A. Ya. Stroenie i sostav zony okisleniya Zakharovskogo mestorozhdeniya (Rudnyy Altay) [Structure and composition of the oxidation zone of the Zakharovskoye deposit (Rudny Altai)]. Geologicheskie formatsii Sibiri i ikh rudonosnost’. Tomsk, Izd-vo Tomskogo universiteta, 1983, pp. 47–54. (In Russian).

8. Gas’kov I. V., Distanov E. G., Mironova N. Yu., Chekalin V. M. Kolchedanno-polimetallicheskie mestorozhdeniya verkhnego devona Severo-Zapadnoy chasti Rudnogo Altaya [Pyrite-polymetallic deposits of the Upper Devonian of the North-Western part of the Rudny Altai]. Novosibirsk, Nauka, 1991. 121 p.

9. Min’ko N. I., Strokova V. V., Zhernovskiy I. V., Nartsev V. M. Metody polucheniya i svoystva nanoob”ektov [Methods of obtaining and properties of nanoobjects]. Moscow, Nauka, 2009, 168 p.

10. Molchanov V. I. Generatsiya vodoroda v litogeneze [Generation of hydrogen in lithogenesis]. Novosibirsk, Nauka, 1981, 142 p.

11. Ovchinnikova T. M. Ob elektrodnykh protsessakh na pirite i khal’kopirite [About electrode processes on pyrite and chalcopyrite]. Metodika i tekhnika razvedki. Leningrad, 1969, no. 65, pp. 17–27. (In Russian).

12. Prikhodko E. F., Morozov A. F., Volodko S. A. Evolution of nanoparticles in the lithosphere. Regional Geology and Metallogeny, 2013, no. 55, pp. 67–76. (In Russian).

13. Putikov O. F., Dukhanin A. S. O vozmozhnom mekhanizme formirovaniya «struynykh» oreolov rasseyaniya. Doklady Rossyiskoy akademii nauk Soyuza Sovetskikh Sotsialisticheskikh Respublik, 1994, vol. 338, no. 2, pp. 219–221. (In Russian).

14. Putikov O. F. Osnovy teorii nelineynykh geoelektrokhimicheskikh metodov poiskov i razvedki [Fundamentals of the theory of nonlinear geoelectrochemical methods of prospecting and exploration]. St. Petersburg, 2008, 534 p.

15. Ryss Yu. S. Geoelektrokhimicheskie metody razvedki [Geoelectrochemical methods of exploration]. Leningrad, Nedra, 1983, 255 p.

16. Ryss Yu. S., Gol’dberg I. S., Alekseev S. G., Dukhanin A. S. Struynaya migratsiya veshchestva v obrazovanii vtorichnykh oreolov rasseyaniya. Doklady Akademii nauk Soyuza Sovetskikh Sotsialisticheskikh Respublik, 1987, vol. 297, no. 4, pp. 956–958. (In Russian).

17. Saet Yu. E. Vtorichnye geokhimicheskie oreoly pri poiskakh rudnykh mestorozhdeniy [Secondary geochemical halos in the search for ore deposits]. Moscow, Nauka, 1982, 168 p.

18. Smirnov S. S. Zona okisleniya sul’fidnykh mestorozhdeniy [Zone of oxidation of sulfide deposits]. Leningrad, 1936, 292 p.

19. Sokolov S. V., Prikhod’ko E. F., Marchenko A. G., Volod’ko S. A. Conceptual formational model of imposed sorption-salt and nanochemical halos. Regional Geology and Metallogeny, 2015, no. 61, pp. 111–114. (In Russian).

20. Flerov G. N., Apel’ P. Yu., Didyk A. Yu., Kuznetsov V. I., Oganesyan R. Ts. Ispol’zovanie uskoriteley tyazhelykh ionov dlya izgotovleniya yadernykh membran [The use of

21. heavy ion accelerators for the manufacture of nuclear membranes]. Atomic Energy, 1989, vol. 67, iss. 4, pp. 274–280. (In Russian).

22. Chekalin V. M. Vklad Tomskoy shkoly geologov v sozdanie i osvoenie mineral’no-syr’evoy bazy severo-zapadnogo Altaya [Contribution of the Tomsk school of geologists to the creation and development of the mineral resource base of the northwestern Altai]. Razvitie mineral’no-syr’evoy bazy Sibiri: ot Obrucheva V. A., Usova M. A., Urvantseva N. N. do nashikh dney: sbornik trudov konferentsii. Tomsk, 2013, pp. 94–101. (In Russian).

23. Shtokalenko M. B., Voroshilov N. A., Putikov O. F. Fiziko-khimicheskie usloviya migratsii metana v obvodnennykh porodakh [Physicochemical conditions of methane migration in flooded rocks]. The Russian Geophysics Journal, 2004, no. 33–34, pp. 12–19. (In Russian).

24. Govett G. J. S. Detection of deeply buried and blind sulphide deposits by measurement of H+ and conductivity of closely spaced surface soil samples. Journal of Geochemical Exploration, 1976, vol. 6, pp. 359–382.