The stirred-tank reactors appear to be usually used in the continuous flow mode of operation and often reserved for high-value metals with substantial leaching rate more than that of heap bioleaching [32] and [33]. The information of the crystal structures on some common minerals can be easily gotten through an database platform, named
Crystallography Open Database (COD), which is an open-access collection of crystal structures of organic, selleck inorganic, metal-organic compounds and minerals [34]. The information of the crystal structures on chalcopyrite and pyrite are listed as followed (Table 1 and Table 2): Chalcopyrite pertains to one of the I-III-VI2 type semiconductors with tetrahedral coordination and S atoms are displaced slightly toward the Fe atoms with a certain direction deviation. Cu is located at the fractional coordinates of (0,0,0) and (0,0.5,0.25), S is at (0.2575,0.25,0.125) and Fe is at (0,0,0.5) Belnacasan molecular weight and (0,0.5,0.75), that the former location of Fe has spin α compared with the latter has spin β, which gives the character of antiferromagnetic structure to chalcopyrite at room/indoor temperature., and some variation in these values has listed as, dFe–S = 2.26 Å, dCu–S = 2.30 Å and dCu–Fe = dCu–Cu = dFe–Fe = 3.71 Å [35], [36], [37] and [38]. Pyrite is one of two polymorphic forms. FeS2 has a face-centered crystal,
which is more stable and steady than marcasite. The unit cell of pyrite is totally determined by cell parameter a, and coefficient of S, u. The crystal structure of pyrite was published in 1914 by Bragg, and the parameters that now commonly accepted are listed as a = 5.416 Å Fludarabine ic50 and u = 0.385 Å. S atoms are connected by covalent bond, and share Fe2+ with the same five S in a slightly deformed octahedral cell. The cubic pyrite morphology which is most common in the nature, possesses the surface 1 0 0 while pyritohedral and octahedral morphologies is with
surfaces 2 1 0 and 1 1 1, respectively and surface 1 1 0 are also can be found. All of these surfaces are of lower coordination as compared to the bulk structure as bonds are fractured during cleavage [39] and [40]. Usually, the cell of crystal structure of pyrite is a cube, while the structure cell of a dodecahedron with pentagonal faces or octahedral crystals with triangular faces also can be detected under a certain and specific geological tectonic environment. Specific elements can be found in the pyrite lattice as substitutions or occluded as inclusions, and the natural pyrite shows p-type or n-type conductivity in terms of the characters of semiconducting mineral [27], [41] and [42]. The valence band structure of chalcopyrite has been studied from different aspects for many years.