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Introduction
The continuous development of different research mechanisms, improved technologies, and tools in the study of various materials is carried out in different branches of science (Sharma et al., 2019a; Tao & Dongwei, 2014). The impact of molecular dynamic simulations (MDS) in different branches of study has expanded dramatically in recent years. However, in the area of minerals extraction, MDS has not yet been widely used although it represents a great opportunity to solve problems within the mining area by allowing to achieve laboratory conditions that might be economically or physically restrictive in reality.
MDS can accurately predict how each atom in a molecular system will behave over time according to a general model of physics that governs interatomic interactions (Hollingsworth & Dror, 2018a). These simulations can analyze a wide variety of molecular processes such as conformational change, positioning of all atoms, in temporal resolution, prediction of new functional materials, and research of physical phenomena on a molecular level, among others (Lindahl, 2014; Sharma et al., 2019a). MDS is a research tool which helps to understand chemical and biochemical processes, providing a dynamic dimension of structural data in addition to high precision atomic detail. There are mainly three areas of application for this type of study: 1) to build and analyze biomolecular structures, 2) to provide X-ray diffraction pattern, and 3) to explore the conformational space of biomolecules (Hollingsworth & Dror, 2018a; Lindahl, 2014; Sharma et al., 2019b).
It is of utmost importance for this paper to be able to create each of the nanostructures, since they are the precursor structures of the nanocluster; however, there is very little information available regarding the structures, so it was necessary to validate them with a study of X-ray diffraction (XRD). Hence, the objective of this research was to simulate through molecular dynamics the crystalline structures of a concentrate obtained from the mining industry to create and validate a nanocluster.
Materials and Methods
Structure Preparation
From a mineragraphic analysis (QUEMSCAN PMA) (Avino Silver & Gold Mines, 2015) of a mineral concentrate obtained in Durango, Mexico, crystalline structures were identified and used as a starting point to model through the Visualizer Module of Materials Studio software version 8.0 (Table 1).
Table 1 Crystal structures of mineral concentrate.
| Name | Crystallization system | Space group | Lattice parameters (Å) |
| Argentite (Ag2S) | Cubic | Im3m | a = 4.89 |
| Pyrargyrite (Ag3SbS3) | Trigonal | R3c | a = 11.047 c = 8.719 |
| Stromeyerite (AgCuS) | Orthorhombic | Cmcm | a = 4.06 b = 6.66 c = 7.99 |
| Chalcopyrite (CuFeS2) | Tetragonal | I-42D | a = 5.28 c = 10.41 |
| Chalcocite (Cu2S) | Monoclinic | P21/c | a = 11.881 b = 27.323 c = 13.491 |
| Covellite (CuS) | Hexagonal | P63/mmc | a = 3.792 c =16.344 |
| Sphalerite (ZnS) | Cubic | F 4 3m | a = 5.406 |
| Galena (PbS) | Cubic | Fm3m | a = 5.936 |
| Bismuthinite (Bi2S3) | Orthorhombic | Pbnm | a = 11.12 b = 11.25 c = 3.97 |
| Bismuth | Trigonal | R3*m | a = 4.537 c = 11.838 |
| Wittichenite (Cu3BiS3) | Orthorhombic | P212121 | a = 7.723 b = 10.395 c = 6.761 |
| Cd - Sulphide (CdS) | Cubic | F 4 3 m | a = 5.825 |
| Pyrite (FeS2) | Cubic | P a 3 | a = 5.417 |
| Arsenopyrite (FeAsS) | Monoclinic | P 2(1) / c | a = 5.74 b = 5.68 c = 5.79 |
| Quartz (SiO2) | Trigonal | P 3 (2) 21 | a = 4.913 b = 4.87 c = 5.405 |
| K - Feldspars (KAlSi3O8) | Monoclinic | C2/ m | a = 8.625 b = 12.996 c = 7.193 |
| Chlorite (Mg, Fe)3(Si, Al)4 O10(OH)2 (Mg, Fe)3(OH)6 | Monoclinic | C2/m | a = 5.373 b = 9.306 c = 14.222 |
| Anatase (TiO2) | Tetragonal | I4(1)/ amd | a = 3.793 c = 9.51 |
| Calcite (CaCO3) | Trigonal | R3*c | a = 4.984 b = 4.934 c = 17.062 |
| Rutile (TiO2) | Tetragonal | P4/mm | a = 4.594 c = 2.958 |
| Hematite (Fe2O3) | Hexagonal | P6/m | a = 5.427 c = 5.427 |
| Muscovite (KAl2(AlSi3O10)(OH2) | Monoclinic | C2/m | a = 5.19 b = 9.03 c = 20.05 |
| Acanth (Ag2S) | Monoclinic | P21/n | a = 4.229 b = 6.931 c = 7.862 |
| Stephanite (Ag5SbS4) | Orthorhombic | Cmc21 | a = 7.793 b = 12.295 c = 8.506 |
| Magnetite (Fe2+Fe23+O4) | Cubic | Fd3m | a = 8.391 |
| Matildite (AgBiS2) | Hexagonal | P3*m1 | a = 8.12 c = 19.02 |
Source: Authors’ own elaboration.
Structure Optimization
Each structure was optimized according to an energy evaluation and conformational adjustment. Structural parameters were obtained by moving the constituent atoms to positions where the energy was minimal. This procedure was carried out using the CASTEP module by performing the Quasi-Newton BFGS method (Li & Fukushima, 2001; Pfrommer et al., 1997; Zhou, 2020). This method accumulates information about enthalpy in the inverse of the Hess matrix, once the coordinates of the configuration space are defined. The crystalline structure is delimited by the matrix of lattice vectors h={a,b,c} and the coordinates s i=1…N, relative to h of the N atoms in the unit cell, which has a volume of Ω=det(h). Conveniently, strain tensor Ɛ is chosen in exchange for the lattice vectors and is related to the reference configuration h 0 in h, as observed in equation 1.
A point in configuration space by the column vector X and its deformation components, which is the negative of the derivative of the enthalpy H for X, is given by equation 2, also known as force vector.
Moreover, from the enthalpy per unit cell (equation 3), the components of the deformation of F are derived (equation 4).
The deformation components of the force vector are multiplied by the metric tensor g =hTh , resulting in all the deformation components of F (equation 5).
So, the change in enthalpy around the minimum is given by equation 6:
The key of the method is to assume a value of A and to improve it at each step.
The dependence of the enthalpy on the strain tensor is governed by the mass, and
the deformation of H0 is multiplied by (3ΩB0)-1
for the internal coordinates. Internal coordinates are proposed to start at
H0 as a block diagonal with matrixes of the
Crystal Creation
Crystalline structures were created in the Crystal Builder Module of Materials Studio version 8.0 software. Corresponding parameters of each crystal such as the space group, crystallization system, as well as the values of the lattice parameters and the measurement of the angles were captured.
Validation of crystalline structures
Through a study of XRD (Rigaku MiniFlex) of mining concentrates, crystalline structures were characterized, obtaining parameters that allowed to compare experimental results against the simulated ones to validate each of the structures that were created. XRD data were obtained with an SC-70 detector, with voltage and current of the source at 40 kV and 15 mA, respectively, using a 2θ scan axis.
Results
Structure Preparation
The structural information of the crystals found in the mineral concentrate is presented in Table 1. All structures were created from their base structure. Representative examples are shown in Figure 1.
Structure Optimization
From the CASTEP module, the universal force field was chosen because it allows to analyze all metallic materials (BIOVIA, 2014c). Optimization of each structure was carried out using the quasi-Newton BFGS iterative method, in which, with each iteration, a value for energy is obtained. Figure 2 shows the energy optimization lines of the different crystalline structures.
Crystal Creation
Each crystal was created according to the specific lattice parameters, as well as the space group (BIOVIA, 2014a). For instance, arsenopyrite crystallizes in a monoclinic system in a space group P 2(1)/c, and it is composed of 46.01% arsenic, 34.30% iron, and 19.69% sulfur (Figure 3a). Calcite is a mineral of calcium carbonate whose crystallization system is trigonal and its space group is R3*c, which is made up of 40.04% calcium and the rest is carbonate (Figure 3b). Wittichenite is a very rare mineral that crystallizes in an orthorhombic system; its space group is P2(1)2(1)2(1); and it is composed of sulfur, copper, and bismuth in 19.40%, 38.45%, and 42.15% respectively (Figure 3c). Quartz is one of the best-known minerals on earth. It is composed of 46.74% silicon and the rest is oxygen, it crystallizes in a trigonal system and its space group is P 3 (2) 21; its structure can be seen in Figure 3d. Chalcopyrite, with a tetragonal crystallization system and an I-42D space group, is composed in equal parts of copper and sulfur (34.78%) and the rest is iron (Cambridge Crystallographic Data Center [CCDC], 2020; Crystallography Open Database, 2020; Mineralogical Society of America [Minsocam], 2017) (Figure 3e).
Validation of Crystalline Structures
The unit cell size and orientation of the crystal determine the position at which the diffraction patterns can be measured at the appropriate wavelength. The analysis of the positions of the diffraction peaks produces the unit cell size and its orientation (BIOVIA, 2014b); for this reason, to validate each one of the structures that were modeled in the simulator, lattice parameters and space groups were compared against those obtained from the XRD study (Table 2). Not all crystals that were simulated appeared in the diffraction study; therefore, only the results of those that appeared in the study are shown.
Table 2 Validation of crystalline structures.
| Crystal | XDR | SOFTWARE | ||
| Lattice parameters (Å) | Space group | Lattice parameters (Å) | Space group | |
| Rutile | a = 10.4748 | I213 | a = 4.594 c = 2.958 |
P4/mm |
| Arsenopyrite | a = 5.6007 b = 5.6155 c = 5.7246 |
P 2(1) / c | a = 5.74 b = 5.68 c = 5.79 |
P 2(1) / c |
| Bismuthinite | a = 11.281 b = 11.241 c = 3.935 |
Pnma | a = 11.12 b = 11.25 c = 3.97 |
Pbnm |
| Calcite | a = 5.405 b = 5.405 c =19.68 |
R3*c | a = 4.984 b = 4.934 c = 17.062 |
R3*c |
| Chalcocite | a =11.881 b = 27.323 c = 13.491 |
Fm-3m | a = 11.881 b = 27.323 c = 13.491 |
P21/c |
| Covellite | a = 3.792 c =16.344 |
P63/mmc | a = 3.792 c =16.344 |
P63/mmc |
| Sphalerite | a = 3 b =3 c =61 |
P3m1 | a = 5.406 | F 4*3m |
| Galena | a =6.970 b = 5.209 c = 7.175 |
Pma2 | a = 5.936 | Fm3m |
| Pyrargyrite | a = 8.14 b = 8.07 c = 8.64 |
P -1 | a = 11.047 c = 8.719 |
R3c |
| Pyrite | a = 5.4098 | P a 3 | a = 5.417 b = 5.424 c = 3.387 |
P a 3 |
| Stromeyerite | a = 4 b = 6 c = 8 |
Cmcm | a = 4.06 b = 6.66 c = 7.99 |
Cmcm |
| Cd - Sulphide | a = 5.4027 | F 4 3 m | a = 5.825 | F 4 3 m |
| Wittichenite | a = 7 b = 11 c = 7 |
P212121 | a = 7.723 b = 10.395 c = 6.761 |
P212121 |
| Chalcopyrite | a = 5.2739 c =10.393 |
I-42D | a = 5.28 c = 10.41 |
I-42D |
| K - Feldspars | a = 9.14 b = 9.14 c = 2 .94 |
I4/m | a = 8.625 b = 12.996 c = 7.193 |
C2/ m |
| Acanth | a = 3.88 b = 5.89 c = 8.13 |
P21/n | a = 4.229 b = 6.931 c = 7.862 |
P21/n |
| Magnetite | a = 9.17 b = 7.982 c = 2.790 |
Bbmm | a = 8.391 | Fd3m |
| Matildite | a =13.01 b = 4.488 c = 16.940 |
C12/m1 | a = 8.12 c = 19.02 |
P3*m1 |
| Chlorite | a = 5.1 b = 7.8 c = 14.29 |
C2/m | a = 5.373 b = 9.306 c = 14.222 |
C2/m |
| Quartz | a = 4.905 b = 4.905 c = 5.379 |
P 3 (2) 21 | a = 4.913 b = 4.87 c = 5.405 |
P 3 (2) 21 |
| Bismuth | a = 8.6 c = 4.2 |
I4/mcm | a = 4.537 c = 11.838 |
R3*m |
Source: Authors’ own elaboration.
Results shown in Table 2 indicate that more than 50% of the crystals that appeared in the XRD study agree with the values used for the simulation. Furthermore, the lack of concordance might occur because of the discrepancy of their chemical composition, resulting in a mismatch of space groups, in that several crystals depend on pressure and temperature to define the previously mentioned parameters, which may present variations.
X-ray Diffraction Study
Minerals are crystalline and the spatial distribution of their components is arranged as structured networks (Consejo Superior de Investigaciones Científicas [CSIC], 2020; Servicio Geólogico Mexicano [SGM], 2010); hence, XRD studies can also be used to obtain the diffraction pattern of the sample (Figure 4) quantitative analyzes.
Subsequently, the simulation of the diffraction patterns of each crystal structure that appeared in the study was performed. This procedure was carried out using the REFLEX module of the same software (BIOVIA, 2014d). The obtained results can be seen in Figure 5. However, it is a considerably different pattern from the one observed in Figure 4, this may be because in the simulation each crystal is individually analyzed, whereas in the study carried out experimentally the sample of the mining concentrate contains all its components at once.
To analyze the similarity of the XRD patterns, further research is required for each pure crystal to fully compare Figures 4 and 5.
Discussion
The nanocrystals were optimized using the CASTEP module, because it is a state-of-the-art quantum mechanics-based program, designed specifically for solid-state materials science (Clark et al., 2005). In this module, as mentioned before, the quasi-Newton method was developed with a BFGS fit, since it is the only iterative method for optimizing crystal structures.
Each structure created was validated to have the most probable structure close to reality, by making a comparative study between the x-ray diffraction pattern that could be simulated with the pattern obtained from an experimental study.
The creation, optimization, and subsequent validation of each crystal structure lead to the formation of a nanocluster with characteristics similar to a mineral sample that can be widely used for exploratory research, unlike a more orthodox experimental research which might have limiting factors such as the expense of reagents, time consumption, and some physical processing conditions that could be difficult to achieve at laboratory scale.
Conclusions
All the crystalline structures present in the mineragraphic analysis were simulated in the visualizer module, and the optimization of the geometry of 95% of the structures created using the Quasi-Newton BFGS method in the CASTEP module was achieved. On the other hand, all crystals of the optimized structures were created, each one with the corresponding parameters and angles, and 72.5% of the structures were validated by comparing the X-ray diffraction pattern against the simulated pattern. Finally, once the simulation is validated, the metal recovery process can be made more efficient by avoiding time investment in experiments and the use of reagents.
