355
Views
3
CrossRef citations to date
0
Altmetric
Original Articles

High-Temperature Oxidation of Bismuth- and Antimony-Based Sulfosalts

ORCID Icon, ORCID Icon, , ORCID Icon, ORCID Icon &

References

  • Aspiala, M., Tesfaye, F., and Taskinen, P., 2016, “Thermodynamic study in the Ag-Sb-S system by the EMF method.” The Journal of Chemical Thermodynamics, 98. pp. 361–366.
  • Assal, J., Hallstedt, B., and Gauckler, L. J., 1999, “Experimental phase diagram study and thermodynamic optimization of the Ag–Bi–O system.” Journal of American Ceramic Society, 82. pp. 711–715.
  • Aten, A. H. W., 1905, “Über phasengleichgewichte im system: wismut und schwefel.” Zeitschrift für Anorganische Chemie, 47(1). pp. 386–398.
  • Aurivillius, B., 1987, “Pyrolysis Products of Bi2(SO4)3. Crystal structures of Bi26O27(SO4)12 and Bi14O16(SO4)5.” Acta Chemica Scandinavica, A41. pp. 415–422.
  • Azad, A. M., Pankajavalli, R., and Sreedharan, O. M., 1986, “Thermodynamic stability of Sb2O3 by a solid-oxide electrolyte emf technique.” The Journal of Chemical Thermodynamics, 18(3). pp. 255–261.
  • Bailey, G. H., 1887, “Determination of atomic weight by means of the normal sulphate.” Journal of the Chemical Society, 51. pp. 676.
  • Barin, I., 1989, Thermochemical Data of Pure Substances, Part I & II, VCH Verlagsgesellschaft, New York, USA: Weinheim/VCH Publishers.
  • Bryndzia, L. T., and Kleppa, O., 1989, “Standard molar enthalpies of formation of sulfosalts in the Ag-As-S system and thermochemistry of the sulfosalts of Ag with As, Sb, and Bi.” American Mineralogist, 74. pp. 243–249.
  • Bryndzia, L. T., and Kleppa, O. J., 1988, “High-temperature reaction calorimetry of solid and liquid phases in the quasi-binary system Ag2S–Sb2S3.” Geochimica et Cosmochimica Acta, 52. pp. 167–176.
  • Charitos, A., Mattich, C., Hammerschmidt, J., Hedstrom, L., Munoz, R., Ortiz Bravo, J., Etcheverry Castro, J., Munoz Franulic, E. R., and Caballero Deramond, C. A., 2016, “Eliminating of sintering phenomenon during partial copper roasting operation – the experience of the CODELCO DMH Unit hosted by MMIJ and JMIA.” Proceedings of Copper 2016 Conference, Kyoto, Japan, Nov. 14–16, Tokyo: IMM Japan, pp. 909–920.
  • Craig, J. R., 1967, “Phase relations and mineral assemblages in the Ag-Bi-Pb-S system.” Mineralium Depozita, 1. pp. 278–305.
  • Crowley, J. A., Currier, R. H., and Szenics, T., 1997, “Mines and minerals of Peru.” The Miner Recordings, 28. pp. 1997.
  • Cubicciotti, D., 1962, “The bismuth-sulfur phase diagram.” Journal of Physical Chemistry, 66. pp. 1205–1206.
  • Dai, Z., 2016, “Development of an experimental methodology for sulphide self-heating studies and the self-heating tendency of Vale’s Voisey’s Bay Concentrator products.” Minerals Engineering, 92. pp. 125–133.
  • Damian, G., Ciobanu, C. L., Cook, N. J., and Damian, F., 2008, “Bismuthsulphosalts from the galena–matildite series in the Cremenea vein, Suior, Baia Mare district, Romania.” Neues Jahrbuch für Mineralogie - Abhandlungen: Journal of Mineralogy and Geochemistry, 185. pp. 199–213.
  • Fluidized-bed roasting, Encyclopedia Britannica, Inc., https://www.britannica.com/technology/fluidized-bed-roasting.
  • Frost, R. B., 2002, “Partial melting of sulfide ore deposites during medium and high-grade metamorphism.” The Canadian Mineralogist, 40. pp. 1–18.
  • Garavelli, A., Pinto, D., Mitolo, D., and Bindi, L., 2015, “Leguernite, Bi12.67O14(SO4)5, a new Bi oxysulfate from the fumarole deposit of La Fossa crater, Vulcano, Aeolian Islands, Italy.” Mineralogical Magazine, 78. pp. 1629–1645.
  • Gather, B., and Blachnik, R., 1980, “Ternary chalcogenide systems VII: the ternary phase diagram silver-bismuth-sulphur.” Journal of the Less-Common Metals, 70. pp. 11–24.
  • Geller, S., and Wernik, J. H., 1959, “Ternary semiconducting compounds with sodium chloride-like structure: AgSbSe2, AgSbTe2, AgBiS2, AgBiSe2.” Acta Crystallographica, 12. pp. 46–54.
  • Glatz, A. C., and Pinella, A., 1968, “X-ray and neutron diffraction studies of the high-temperature 13-phase of the AgBiSe2/AgBiS2 system.” Journal of Material Science, 3. pp. 498–501.
  • Gmelin, L., 1978, Gmelins Handbuch der Anorganischen Chemie, 8th ed., Vol. 8, Germany: Springer-Verlag, Berlin Heidelberg GmbH.
  • Graham, A. R., 1951, “Matildite, aramayoite, miargyrite.” American Mineralogist, 36. pp. 436–449.
  • Happ, J. V., and Davey, T. R. A., 1971, “Solubility of sulfur in liquid bismuth.” Technical Note, Transactions, 180(778). pp. 190.
  • Hofmann, H. O., and Wanjukow, W., 1912, “The decomposition of metallic sulphates at elevated temperatures in a current of dry air.” Bulletin of the American Institute of Mining and Metallurgical Engineers, 77. pp. 889–893.
  • Johnson, V. S., White, R. J., Dann, S. E., and Hellgardt, K., 2004, “Structural investigation of the high-temperature oxidation of bismuth sulfide using TPO-MS and in situ X-ray diffraction techniques.” Industrial & Engineering Chemistry Research, 43. pp. 3127–3132.
  • Jones, W. M., 1984, “Equilibrium pressures over the systems bismuth trisulfate dibismuthmonoxydisulfate and dibismuthmonoxydisulfate dibismuthdioxymonosulfate. Slow transformation between two crystalline forms of dibismuthmonoxydisulfate.” The Journal of Chemical Physics, 80. pp. 3408–3419.
  • Keighin, C. W., and Honea, R., 1969, “The system Ag-Sb-S from 600 C to 200 C.” Mineralium Deposita, 4. pp. 153–171.
  • Kim, J.-H., Chung, D.-Y., Bilc, D., Loo, S., Short, J., Mahanti, S. D., Hogan, T., and Kanatzidis, M. G., 2005, “Crystal growth, thermoelectric properties, and electronic structure of AgBi3S5 and AgSbxBi3−xS5 (x = 0.3).” Chemistry of Materials, 17(14). pp. 3606–3614.
  • Kopp, J. C., Spieth, V., and Bernhardt, H.-J., 2012, “Precious metals and selenides mineralisation in the copper-silver deposit Spremberg-Graustein, Niederlausitz, SE-Germany.” Zeitschrift der Deutschen Gesellschaft für Geowissenschaften, 163(4). pp. 361–384.
  • Koyama, E., Nakai, I., and Nagashima, K., 1984, “Crystal Chemistry of oxide-chalcogenides. II. Synthesis and crystal structure of the first bismuthoxide-sulfide, Bi2O2S.” Acta Crystallographica, B40. pp. 105–109.
  • Landolt-Börnstein: Thermodynamic Properties of Inorganic Material, 1999, Scientific Group Thermodata Europe (SGTE), Berlin-Heidelberg: Springer-Verlag.
  • Lin, J. C., Sharma, R. C., and Chang, Y. A., 1996, “The Bi-S (bismuth-sulfur) system.” Journal of Phase Equilibrium, 17. pp. 132–139.
  • Matsuzaki, R., Sofue, A., Masumizu, H., and Saeki, Y., 1974, “Thermal decomposition process of Bi2(SO4)3.” Chemistry Letters, 3. pp. 737–740.
  • Mittova, I. Y., Soshnikov, I. M., and Terekhov, V. A., 1996, “Thermal oxidation of InP/Bi2S3 structures in oxygen.” Neorganicheskie Materialy, 32(9). pp. 1045–1048 (in Russian).
  • Morelli, D., Jovovic, V., and Heremans, J., 2008, “Intrinsically minimal thermal conductivity in cubic I− V− VI2 semiconductors.” Physical Review Letters, 101. pp. 035901.
  • MTDATA – Phase Diagram Software from the National Physical Laboratory, 2010, SGTE pure element transition data, http://resource.npl.co.uk/mtdata/unarytable.html.
  • Oudich, F., David, N., Mathieu, S., and Vilasi, M., 2015, “Phase equilibria investigations and thermodynamic modeling of the system Bi2O3–Al2O3.” Journal of Nuclear Materials, 457. pp. 72–79.
  • Outotec (Finland) Oy, 2016, Outotec roasting solutions, Sustainable use of Earth’s natural resources, 8. www.outotec.com.
  • Padilla, R., Aracena, A., and Ruiz, M. C., 2014, “Kinetics of stibnite (Sb2S3) oxidation at roasting temperatures.” Journal of Mining and Metallurgy, Section B: Metallurgy, 50(2). pp. 127–132.
  • Padilla, R., Ramírez, G., and Ruiz, M. C., 2010, “High-temperature volatilization mechanism of stibnite in nitrogen-oxygen atmospheres.” Metallurgical and Materials Transactions B, 41. pp. 1284–1292.
  • Padilla, R., Ricardo, V., Ruiz, M. C., and Reddy, R. G., 2011, “Kinetics of the oxidation of bismuthinite in Oxygen–Nitrogen atmospheres.” Metallurgical and Materials Transactions B, 42. pp. 1017–1022.
  • Roine, A., 2010, HSC Chemistry 6, Finland: Outotec Oy Research Centre.
  • Schönau, K. A., and Redfern, S. A. T., 2002, “High-temperature phase transitions, dielectric relaxation, and ionic mobility of proustite, Ag3AsS3, and pyrargyrite, Ag3SbS3.” Journal of Applied Physics, 92. pp. 7415–7424.
  • Sharma, R. C., and Chang, Y. A., 1990, Bi–S (bismuth–sulfur), In Binary Alloy Phase Diagrams, Vol. 3, (T. B. Massalski, Ed.), Materials Park, Ohio: ASM International.
  • Singh, K., Joat, R. V., and Bhoga, S. S., 2002, “Investigation of the Ag2SO4-BaSO4 binary system from an SOx sensor point of view.” Ionics, 8. pp. 470–478.
  • Staude, S., Dorn, A., Pfaff, K., and Markl, G., 2010, “Assemblages of Ag–Bi sulfosalts and conditions of their formation: the type locality of schapbachite (Ag0.4Pb0.2Bi0.4S) and neighboring mines in the Schwarzwald ore district, Southern Germany.” Canadian Mineralogist, 48. pp. 441–466.
  • Subban, C. V., Rousse, G., Courty, M., Barboux, P., and Tarascon, J.-M., 2014, “Polymorphism in Bi2(SO4)3.” Solid State Science, 38. pp. 25–29.
  • Tesfaye, F., and Lindberg, D., 2016, “Thermochemical properties of selected ternary phases in the Ag-Bi-S system.” Journal of Materials Science, 51. pp. 5750–5759.
  • Tesfaye, F., and Taskinen, P., 2013, “Experimental thermodynamic study of the equilibrium phase AgBi3S5 by an improved EMF method.” Thermochimica Acta, 562. pp. 75–83.
  • Tesfaye, F., and Taskinen, P., 2014, “Experimentally determined thermodynamic properties of schapbachite (α-AgBiS2) below T = 700 K.” The Journal of Chemical Thermodynamics, 70. pp. 219–226.
  • Van Hook, H. F., 1960, “The ternary system Ag2S-Bi2S3-PbS.” Economic Geology, 55. pp. 759–788.
  • Wu, D., 1989, “The stability of matildite (AgBiS2) and Ag2Bi4S7 and phase relations in the system Ag2S-Bi2S3.” Acta Mineralogica Sinica, 9. pp. 126–132.
  • Živković, D., Sokić, M., Živković, Ž., Manasijević, D., Balanović, L., Štrbac, N., Ćosović, V., and Boyanov, B., 2013, “Thermal study and mechanism of Ag2S oxidation in air.” Journal of Thermal Analysis and Calorimetry, 111. pp. 1173–1176.
  • Živkovic, Z., Štrbac, N., Živkovic, D., Grujicic, D., and Boyanov, B., 2002, “Kinetics and mechanism of Sb2S3 oxidation process.” Thermochimica Acta, 383. pp. 137–143.

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.