Experimental study of the formation of chalcopyrite and bornite via the sulfidation of hematite: Mineral replacements with a large volume increase

Abstract: Chalcopyrite (CuFeS 2 ) and bornite (Cu 5 FeS 4 ) are the most abundant Cu-bearing minerals in hydrothermal Cu deposits, forming under a wide range of conditions from moderate-temperature sedimentary exhalative deposits to high-temperature porphyry Cu and skarn deposits. We report the hydrothermal synthesis of both chalcopyrite and bornite at 200-300 °C under hydrothermal conditions. Both minerals formed via the sulfidation of hematite in solutions containing Cu(I) (as a chloride complex) and hydrosulfide, at … Show more

“…In U-free experiments, chalcopyrite replaced hematite directly (Zhao et al 2014a). In contrast, the presence of U…”

“…7c). Li et al (2015) and Zhao et al (2014a) observed that the replacement of hematite (Fe 2 O 3 ) by chalcopyrite (CuFeS 2 ; V m ~ +196%; Table 1) results in both a porous chalcopyrite that replaces the hematite in a pseudomorphic manner, and a chalcopyrite overgrowth that grows from solution. Hence, it is clear that such a large volume increase is accommodated through the transport of species away from the replacement interface rather than via reaction-induced fracturing as has been observed in other systems exhibiting a volume increase (Jamtveit et al 2009;Plümper et al 2012;Putnis et al 2007b).…”

“…78% pseudomorphic pentlandite + 3H + + 1.875O 2(aq) ⟶ violarite + 1.5Ni2+ + 0.75Fe 2 O 3 + 1.5H 2 O S -16.63% pseudomorphic (Xia et al 2009a) cryptoperthite ⟶ 0.54Ab 96 Or 04 + 0.46Or 87 Ab 17 (patch perthite) K-Na-Si-O -0.58% pseudomorphic (Norberg et al 2013) aragonite ⟶ calcite Ca-C-O 8.12% pseudomorphic with minor overgrowth (Perdikouri et al 2013) 54% ICDR with significant overgrowth (Zhao et al 2014b) 2pyrrhotite + 14H 2 S (aq) + 7O 2(aq) ⟶ 16pyrite + 14H 2 O Fe 15.70% pseudomorphic with minor overgrowth (Qian et al 2011) 2zoisite + rutile + quartz ⟶ 3anorthite + titanite + H 2 O Ti 18.78% pseudomorphic (Cruz-Uribe et al 2014; Kapp et al 2009) 2forsterite + 3H 2 O ⟶ lizardite + brucite Si 47.83% replacement with fracture generation (Kelemen and Hirth 2012; Plümper et al 2012) magnetite + 6H 2 S (aq) + O 2(aq) ⟶ 3pyrite + 6H 2 O Fe 59.80% replacement and overgrowth(Qian et al 2010) 3% ICDR with significant overgrowth(Zhao et al 2014a) …”

Textural and compositional complexities resulting from coupled dissolution–reprecipitation reactions in geomaterials

“…In U-free experiments, chalcopyrite replaced hematite directly (Zhao et al 2014a). In contrast, the presence of U…”

“…7c). Li et al (2015) and Zhao et al (2014a) observed that the replacement of hematite (Fe 2 O 3 ) by chalcopyrite (CuFeS 2 ; V m ~ +196%; Table 1) results in both a porous chalcopyrite that replaces the hematite in a pseudomorphic manner, and a chalcopyrite overgrowth that grows from solution. Hence, it is clear that such a large volume increase is accommodated through the transport of species away from the replacement interface rather than via reaction-induced fracturing as has been observed in other systems exhibiting a volume increase (Jamtveit et al 2009;Plümper et al 2012;Putnis et al 2007b).…”

“…78% pseudomorphic pentlandite + 3H + + 1.875O 2(aq) ⟶ violarite + 1.5Ni2+ + 0.75Fe 2 O 3 + 1.5H 2 O S -16.63% pseudomorphic (Xia et al 2009a) cryptoperthite ⟶ 0.54Ab 96 Or 04 + 0.46Or 87 Ab 17 (patch perthite) K-Na-Si-O -0.58% pseudomorphic (Norberg et al 2013) aragonite ⟶ calcite Ca-C-O 8.12% pseudomorphic with minor overgrowth (Perdikouri et al 2013) 54% ICDR with significant overgrowth (Zhao et al 2014b) 2pyrrhotite + 14H 2 S (aq) + 7O 2(aq) ⟶ 16pyrite + 14H 2 O Fe 15.70% pseudomorphic with minor overgrowth (Qian et al 2011) 2zoisite + rutile + quartz ⟶ 3anorthite + titanite + H 2 O Ti 18.78% pseudomorphic (Cruz-Uribe et al 2014; Kapp et al 2009) 2forsterite + 3H 2 O ⟶ lizardite + brucite Si 47.83% replacement with fracture generation (Kelemen and Hirth 2012; Plümper et al 2012) magnetite + 6H 2 S (aq) + O 2(aq) ⟶ 3pyrite + 6H 2 O Fe 59.80% replacement and overgrowth(Qian et al 2010) 3% ICDR with significant overgrowth(Zhao et al 2014a) …”

Textural and compositional complexities resulting from coupled dissolution–reprecipitation reactions in geomaterials

“…It is likely that the Cu-Fe sulfide minerals at Olympic Dam originally formed by the replacement of hematite, and have subsequently been remobilized (Haynes et al 1995). Recently Zhao et al (2014a) was able to form chalcopyrite and bornite by the replacement of hematite under hydrothermal conditions. Again it is a surprising feature that these nominally massive sulfide ore minerals have such a relatively high porosity.…”

“…In all cases the product mineral showed evidence of reaction generated porosity. The ore-forming reactions that have been studied include the replacement of pentlandite by violarite (Tenailleau et al 2006;Xia et al 2009Xia et al , 2008Xia et al , 2007, pyrrhotite by marcasite and pyrite (Qian et al 2011;Xia et al 2010Xia et al , 2007, hematite by chalcopyrite (Zhao et al 2014b), chalcopyrite by bornite (Zhao et al 2014a), magnetite by pyrite (Qian et al 2010) and by arsenian-pyrite (Qian et al 2013), calaverite by gold (Zhao et al 2009, and sylvanite and krennerite by gold-silver alloy (Xu et al 2013;Zhao et al 2013). In all these replacement reactions, porosity was generated in the daughter minerals regardless whether the reaction involves volume contraction or expansion.…”

Characterization of porosity in sulfide ore minerals: A USANS/SANS study

Exsolution of chalcopyrite from bornite-digenite solid solution: an example of a fluid-driven back-replacement reaction