Alteration, geothermometry, Raman spectroscopy and O-H stable isotopes studies on Lakehsiah 1 deposit, Yazd province, Iran

Document Type : Research Article

Authors

1 Department of Geology, Faculty of Sciences, Bu-Ali Sina University, Hamedan, Iran

2 Institute of Earth SciencesInstitute of Earth Sciences, Slovak Academy of Sciences, Bratislava, Slovakia

Abstract

Introduction
The Lakehsiah mining district is hosted in Early Cambrian volcano-sedimentary units (CVSU) of the Kashmar–Kerman zone, Central Iran. The Kashmar-Kerman belt is located between the Yazd block in the west and the Tabas block in the east and it is parallel to the Poshed badam, Tabas and Kalmard faults in the north and Koh Banan and Zarand faults in the south of the area (Ramezani and Tucker, 2003). Compositions of the volcanogenic rocks in this area vary from felsic to mafic and include rhyolitic, rhyodacitic tuff and spilitic lava and diabase. The sedimentary rocks include dolomites, dolomitic limestones and evaporites. Lakehsiah 1 deposit is one of three IOA outcrops in the Lakehsiah district which have been studied in this research.
 
Materials and Methods
The mineralogical study of alteration zones was carried out by light microscope with transmission light and X-ray diffraction (XRD) analysis, at the Mineralogical Laboratory of Bu-Ali Sina University and Iran Minerals Processing Research Center, respectively. Fluid inclusion and Raman spectroscopy studies were also performed to determine temperature, composition and evolution of the ore-forming fluid at the Institute of Earth Sciences SAS, Slovakia. Stable isotope geochemistry of quartz (O-H) was performed at the Cornell University, USA.
 
Discussion
Iron deposits hosted in the Tashk Group show hydrothermal alteration. The major minerals of the Sodic-Calcic alteration are the crystals of calcic amphiboles (tremolite-actinolite), pyroxene, calcite, magnetite and apatite. Propylitic alteration (chloritization and epidotization) is very widespread and affects volcanic and intrusive rocks. It consists of chlorite, epidote, calcite, and magnetite with minor amounts of sericite. Silicification alteration, occurs as distal alteration in both hanging wall and footwall host rocks, forming fine-grained to coarse grained quartz aggregates, veins and veinlets. Sericitic-argillic alteration occurs mainly in intrusions. Feldspar (plagioclase and K-feldspar) was altered to sericite and clay minerals. Minor quartz occurs as veinlets in this alteration zone. Na- Ca alteration in volcanic and intrusion rocks is exposed in the center of the area. Amphiboles mainly occur as replacements of plagioclase. Plagioclases were altered to chlorite, epidote, and calcite. Additionally, veinlets of quartz-epidote-chlorite, chlorite-epidote, epidote-quartz, quartz-calcite, calcite, chlorite-calcite, and epidote-calcite are observed. Quartz and carbonates (calcite) are widespread and veins of these minerals crosscut all the rocks described above.
Lakehsiah 1 deposit, hosted within high-silica rhyolitic tuffs and domes, forms a steeply dipping tabular lens and it includes massive magnetite ± apatite ± quartz ± specular hematite ± Fe-Mg silicates.
 
Fluid inclusion Petrography
Four major types of fluid inclusions are observed based on proportions of vapor, liquid, and solid phases present at room temperature in quartz mineral. They are described as follows:
1-liquid-rich inclusions (L)
2-vapor-rich inclusions (V)
3-Two-phase liquid rich fluid inclusions (L+V)
4-three phase inclusions with halite solid phase as daughter mineral (L+V+H). Study of inclusions petrography shows that most of the inclusions present within this mineral are primary in origin, although secondary or pseudosecondary types have been identified. They have different sizes (typically 5–15 μm). Fluid inclusion shapes are rounded, elliptical, irregular, negative crystal shapes and square.
 
Results
Microthermometry and Raman spectroscopy
Freezing and heating experiments were performed on Types 3 and 4 fluid inclusions. Stretching of inclusions was noted during heating of large fluid inclusions in quartz from mineralized quartz veins. In such samples, homogenization temperatures range from 217–428 °C for type 3 and 384-467°C   for type 4.
Micro-thermometric data were obtained from both Types 3 and 4 inclusions. The data obtained revealed variation in salinity of the trapped fluids. The final ice melting temperature in Types 3 and 4 inclusions varies from −4° to -18 and -9 to -19 °C with a mode at around -12 °C. Final ice-melting temperatures are lowest in the mineralized quartz veins. The first melting temperatures in multiphase Types 3–4 inclusions are also in a similar range which varies from -21 to -34°C. Based on their final ice melting temperatures, it varies between 10 to 27 and 40 to 44 wt. % NaCl equivalent for type 3 and 4 inclusions. T°C vs. salinity plots of inclusions show mixing of magmatic hot fluids with cold meteoric waters. Raman spectroscopy revealed presence of 69 mol % N2 and 31 mol % CO2 and 33 mol % N2 and 67 mol % CO2 in types 3 and 4 inclusions. These gases can be derived from mantle degassing (Wang et al., 2018) and chemical
reactions during ascent of fluids.
 
H-O isotopes
Isotopic studies are among the most common methods for identifying the primary composition of ore-forming fluids in deposits (Barati and Gholipoor, 2014). In the study area, five quartz samples in quartz grains and veins were used for H-O isotope analyses, with the aim of determining the source(s) of ore-forming fluids. The δDH2O and δ18OH2O values of the ore-forming fluids in quartz samples vary from -60‰ to -80‰, and -4.71‰ to -1.42‰, respectively. The above observations reveal that the early ore-forming fluids are magmatic in origin and is characterized by high temperature and moderate to high salinity, and gradually evolve to low temperature, low salinity meteoric water. The Lakehsiah 1 Fe deposit is associated with the magmatism induced by the protracted subduction. The decrease in temperature, salinity and f(O2), as well as fluid-rock interactions, are the main factors controlling Fe deposition.
 
References
Barati, M. and Gholipoor, M., 2014. Study of REE behaviors, fluid inclusions, and O, S stable Isotopes in Zafar-abad iron skarn deposit, NW Divandarreh, Kordestan province. Journal of Economic Geology, 6(2): 235–‌275. (in Persian with English abstract) https://doi.org/10.22067/ECONG.V6I2.20257
Ramezani, J. and Tucker, R.D., 2003. The Saghand region, central Iran: U-Pb geochronology, petrogenesis and implications for Gondwana tectonics. American Journal of Science, 303(7): 622–665. https://doi.org/10.2475/ajs.303.7.622‏‏
Wang, Y., Wang, K. and Konare, Y., 2018. N2-rich fluid in the vein-type Yangjingou scheelite deposit, Yanbian, NE China. Scientific Reports, 8(1): 5662. https://doi.org/10.1038/s41598-018-22227-7

Keywords

References

Bakker, R.‌J. and Diamond, L.‌W., 2006. Estimation of volume fractions of liquid and vapor phases in fluid inclusions, and definition of inclusion shapes. American Mineralogist, 91(4): 635–657.‏ https://doi.org/10.2138/am.2006.1845
Barati, M. and Gholipoor, M., 2014. Study of REE behaviors, fluid inclusions, and O, S stable Isotopes in Zafar-abad iron skarn deposit, NW Divandarreh, Kordestan province. Journal of Economic Geology, 6(2): 235–‌275. (in Persian with English abstract) https://doi.org/10.22067/ECONG.V6I2.20257
Barnes, H.L., 1997. Geochemistry of hydrothermal ore deposits. John Wiley and Sons, New York, 797 pp. Retrieved April 2, 2020 from Retrieved April 2, 2020 from https://www.wiley.com/en-bo/Geochemistry+of+Hydrothermal+Ore+Deposits%2C+3rd+Edition-p-9780471571445
Barton, M.D., 2014. Iron oxide (-Cu-Au-REE-P-Ag-U-Co) systems. In: H.D. Holland and K.K. Turekian (Editors), Treatise on Geochemistry: Elsevier Science, USA, pp. 515–541. Retrieved July 10, 2020 from Retrieved July 10, 2020 from https:https://www.geo.arizona.edu/~mdbarton/MDB_papers_pdf/Barton%5B14_IOCGSystems_ToG2-Ch20.pdf
Beaufort, D., Rigault, C., Billon, S., Billault, V., Inoue, A., Inoue, S. and Patrier, P., 2015. Chlorite and chloritization processes through mixed-layer mineral series in low-temperature geological systems–a review. Clay Minerals, 50(4): 497–523. https://doi.org/10.1180/claymin.2015.050.4.06
Chiaradia, M., Banks, D., Cliff, R., Marschik, R. and De Haller, A., 2006. Origin of fluids in iron oxide–copper–gold deposits: constraints from δ37Cl, 87Sr/86Sri and Cl/Br. Mineralium Deposita, 41(6): 565–573. https://doi.org/10.1007/s00126-006-0082-6‏‏
Childress, T.M., Simon, A.C., Day, W.C., Lundstrom, C.C. and Bindeman, I.N., 2016. Iron and oxygen isotope signatures of the Pea Ridge and Pilot Knob magnetite-apatite deposits, southeast Missouri, USA. Economic Geology, 111(8): 2033–2044.‏ https://doi.org/10.2113/econgeo.111.8.2033
Clayton, R.N., O'Neil, J.R. and Mayeda, T.‌K., 1972. Oxygen isotope exchange between quartz and water. Journal of Geophysical Research, 77(17): 3057–3067. https://doi.org/10.1029/JB077i017p03057
Craig, J.‌R. and Vaughan, D.‌J., 1994. Ore microscopy and ore petrography. John Wiley and Sons Inc., New York, 434 pp. Retrieved July 15, 2020 from https://www.researchgate.net/publication/290120333
Dare, S.A., Barnes, S.J. and Beaudoin, G., 2015. Did the massive magnetite “lava flows” of El Laco (Chile) form by magmatic or hydrothermal processes? New constraints from magnetite composition by LA-ICP-MS. Mineralium Deposita, 50(5): 607–617.‏ https://doi.org/10.1007/s00126-014-0560-1
De Melo, G.H., Monteiro, L.V., Xavier, R.P., Moreto, C.P. and Santiago, E., 2019. Tracing Fluid Sources for the Salobo and Igarapé Bahia Deposits: Implications for the Genesis of the Iron Oxide Copper-Gold Deposits in the Carajás Province, Brazil. Economic Geology, 114(4): 697–718.‏ https://doi.org/10.5382/econgeo.4659
Evans, A.M., 1993. Ore geology and industrial minerals: an introduction. John Wiley and Sons, Oxford, United Kingdom, 400 pp. Retrieved July 15, 2020 from https://www.pmf.unizg.hr/_download/repository/ORE_GEOLOGY_AND_INDUSTRIAL_MINERALS.PDF
Frezzotti, M.L., Tecce, F. and Casagli, A., 2012. Raman spectroscopy for fluid inclusion analysis. Journal of Geochemical Exploration, 112: 1–20. https://doi.org/10.1016/j.gexplo.2011.09.009
Foose, M.P. and McLelland, J.M., 1995. Proterozoic low-Ti iron-oxide deposits in New York and New Jersey: Relation to Fe-oxide (Cu–U–Au–rare earth element) deposits and tectonic implications. Geology, 23(7): 665–668.‏ https://doi.org/10.1130/0091-7613(1995)023<0665:PLTIOD>2.3.CO;2
Frietsch, R., Tuisku, P., Martinsson, O. and Perdahl, J.A., 1997. Early proterozoic Cu-(Au) and Fe ore deposits associated with regional Na-Cl metasomatism in northern Fennoscandia. Ore Geology Reviews, 12(1): 1–34.‏ https://doi.org/10.1016/S0169-1368(96)00013-3
Fulignati, P., 2018. Hydrothermal fluid evolution in the ‘Botro ai Marmi’quartz-monzonitic intrusion, Campiglia Marittima, Tuscany, Italy. Evidence from a fluid-inclusion investigation. Mineralogical Magazine, 82(5): 1169–1185. https://doi.org/10.1180/mgm.2018.116
Giggenbach, W.F., 1992. Magma degassing and mineral deposition in hydrothermal systems along convergent plate boundaries: SEG Distinguished lecture. Economic Geology, 87: 1927–1944. Retrieved August 1, 2020 from https://jglobal.jst.go.jp/en/detail?JGLOBAL_ID=200902004813361407
Grondijs, H.‌F. and Schouten, C., 1937. A study of the Mount Isa ores [Queensland, Australia]. Economic Geology, 32(4): 407–450.‏ https://doi.org/10.2113/gsecongeo.32.4.407
Gu, L., Wu, C., Zhang, Z., Pirajno, F., Ni, P., Chen, P. and Xiao, X., 2011. Comparative study of ore-forming fluids of hydrothermal copper–gold deposits in the lower Yangtze River Valley, China. International Geology Review, 53(5–6): 477–498.‏ https://doi.org/10.1080/00206814.2010.533873
Haghipour, A., 1977. Geological Map of the Posht-e-Badam Area, Scale 1: 100,000. Geological Survey of Iran.‏ Retrieved August 5, 2020 from https://catalogue.nla.gov.au/Record/52531
Heidarian, H., Alirezaei, S. and Lentz, D.‌R., 2017. Chadormalu Kiruna-type magnetite-apatite deposit, Bafq district, Iran: Insights into hydrothermal alteration and petrogenesis from geochemical, fluid inclusion, and sulfur isotope data. Ore Geology Reviews, 83: 43–62.‏ https://doi.org/10.1016/j.oregeorev.2016.11.031
Henriquez, F. and Martin, R.‌F., 1978. Crystal-growth textures in magnetite flows and feeder dykes, El Laco, Chile. The Canadian Mineralogist, 16(4): 581–589. Retrieved July 27, 2020 from https://www.researchgate.net/publication/237651949
Hitzman, M.W., Oreskes, N. and Einaudi, M.‌T., 1992. Geological characteristics and tectonic setting of proterozoic iron oxide (Cu- U- Au- REE) deposits. Precambrian Research, 58(1–4): 241–287.‏ https://doi.org/10.1016/0301-9268(92)90121-4
Houshmandzadeh, A. Sabzehei, M. Ghaemi, J. and Haddadan, M., 2012. Geological map of Ali Abad, scale, 1:25000, Sheet No. 7153 IV SE. Parskani Co. (in Persian)
Keyong, W., Min, Q., Fengyue, S., Duo, W., Li, W. and XiangWen, L., 2010. Study on the geochemical characteristics of ore-forming fluids and genesis of Xiaoxinancha gold-copper deposit, Jilin Province. Acta Petrologica Sinica, 26(12): 3727–3734.‏ Retrieved August 10, 2020 from https://www.researchgate.net/publication/287860941
Knipping, J.L., Bilenker, L.D., Simon, A.C., Reich, M., Barra, F., Deditius, A.P. and Munizaga, R., 2015. Trace elements in magnetite from massive iron oxide-apatite deposits indicate a combined formation by igneous and magmatic-hydrothermal processes. Geochimica et Cosmochimica Acta, 171: 15–38.‏ https://doi.org/10.1016/j.gca.2015.08.010
Lowenstern, J.‌B., 2001. Carbon dioxide in magmas and implications for hydrothermal systems. Mineralium Deposita, 36(6): 490–502.‏ https://doi.org/10.1007/s001260100185
Luo, G., Zhang, Z., Du, Y., Pang, Z., Zhang, Y. and Jiang, Y., 2015. Origin and evolution of ore-forming fluids in the Hemushan magnetite–apatite deposit, Anhui Province, Eastern China, and their metallogenic significance. Journal of Asian Earth Sciences, 113(3): 1100–1116.‏ https://doi.org/10.1016/j.jseaes.2014.08.018
Mirzababaei, G., Mehrdad Behzadi, M., Rezvanianzadeh, M.R., Yazdi, M. and Ghannadi Maragheh, M. 2019. Brecciated unit and Th-REE mineralization in the Se-Chahun ore deposit, Bafq mining district, Central Iran. Journal of Economic Geology, 11(1): 105–120. (in Persian with English abstract) https://doi.org/10.22067/econg.v11i1.65876
Morizet, Y., Paris, M., Gaillard, F. and Scaillet, B., 2009. Raman quantification factor calibration for CO–CO2 gas mixture in synthetic fluid inclusions: application to oxygen fugacity calculation in magmatic systems. Chemical Geology, 264(1–4): 58–70. https://doi.org/10.1016/j.chemgeo.2009.02.014
Naranjo, J.A., Henríquez, F. and Nyström, J.O., 2010. Subvolcanic contact metasomatism at El Laco volcanic complex, central Andes. Andean Geology, 37(1):110–120.‏ Retrieved August 10, 2020 from https://www.redalyc.org/pdf/1739/173914377005.pdf
Pirajno, F., 2009. Hydrothermal processes and mineral systems. Springer Science and Business Media, Australia, 1273 pp.‏ https://doi.org/10.4067/s0718-71062010000100005
Rajabi, A., Canet, C., Rastad, E. and Alfonso, P., 2015. Basin evolution and stratigraphic correlation of sedimentary-exhalative Zn–Pb deposits of the Early Cambrian Zarigan–Chahmir Basin, Central Iran. Ore Geology Reviews, 64: 328–353.‏ https://doi.org/10.1016/j.oregeorev.2014.07.013
Rajabi, A., Rastad, E., Alfonso, P. and Canet, C., 2012. Geology, ore facies and sulfur isotopes of the Koushk vent-proximal sedimentary-exhalative deposit, Posht-e-Badam block, Central Iran. International Geology Review, 54(14): 1635–1648. https://doi.org/10.1080/00206814.2012.659106
Rajabzadeh, M.A., Hoseini, K. and Moosavinasab, Z., 2015. Mineralogical and geochemical studies on apatites and phosphate host rocks of Esfordi deposit, Yazd province, to determine the origin and geological setting of the apatite. Journal of Economic Geology, 6(2): 331–353. (in Persian with English abstract) https://doi.org/10.22067/econg.v6i2.20956
Ramdohr, P., 1980. The ore minerals and their intergrowths. Elsevier, Oxford, New York, 1205 pp. Retrieved August 20, 2020 from https://www.researchgate.net/publication/284413752
Ramezani, J. and Tucker, R.D., 2003. The Saghand region, central Iran: U-Pb geochronology, petrogenesis and implications for Gondwana tectonics. American Journal of Science, 303(7): 622–665. https://doi.org/10.2475/ajs.303.7.622‏‏
Robb, L., 2005. Introduction to ore-forming processes. Blackwell publishing, Malden, 373 pp. Retrieved August 20, 2020 from https://kursatozcan.com/ders_notlari/Introduction_to_Ore_Forming_Processes.pdf
Samani, B., 1993. Saghand formation, a riftogenic unit of upper Precambrian in central Iran. Geosciences: Scientific Quarterly Journal of the Geological Survey of Iran, 2(6): 32–45. (in Persian with English abstract) Retrieved August 20, 2020 from https://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&lang=en&idt=6501166
Samani, B.A. 1988. Metallogeny of the Precambrian in Iran. Precambrian Research, 39(1–2): 85–106.‏ ‏https://doi.org/10.1016/0301-9268(88)90053-8
Sepahi, A.‌A. and Miri, M., 2015. Textures of Igneous and metamorphic rocks. Bu-Ali sina University press, Hamedan, 171 pp. (in Persian) Retrieved August 22, 2020 from https://www.researchgate.net/publication/285393053
Shelley, D., 1993. Igneous and metamorphic rocks under the microscope: classification, textures, microstructures and mineral preferred-orientations. Chapman and Hall, London, 445 pp. https://doi.org/10.1017/S0016756800020744
Sheppard, S.M. and Harris, C., 1985. Hydrogen and oxygen isotope geochemistry of Ascension Island lavas and granites: variation with crystal fractionation and interaction with sea water. Contributions to Mineralogy and Petrology, 91(1): 74–81. https://doi.org/10.1007/BF00429429
Shepherd, T.J., Rankin, A.H. and Alderton, D.H., 1985. A practical guide to fluid inclusion studies. Chapman and Hall Blackie, New York, 224 pp. Retrieved August 27, 2020 from https://www.amazon.com/Practical-Guide-Fluid-Inclusion-Studies/dp/0216916461
Taghipour, S., Kananian, A., Harlov, D. and Oberhänsli, R., 2015. Kiruna-type iron oxide-apatite deposits, Bafq district, central Iran: Fluid-aided genesis of fluorapatite-monazite-xenotime assemblages. The Canadian Mineralogist, 53(3): 479–496. https://doi.org/10.3749/canmin.4344‏‏
Taylor, B.E., 1992. Degassing of H2O from rhyolitic magma during eruption and shallow intrusion, and the isotopic composition of magmatic water in hydrothermal systems. In: J.W. Hedenquist (Editors), Magmatic Contributions to Geothermal Systems. Geological Survey of Japan, Tsukuba, Report 279, 190–194. Retrieved May 5, 2020 from https://www.researchgate.net/publication/285082036
Taylor, Jr., H.P., 1974. The application of oxygen and hydrogen isotope studies to problems of hydrothermal alteration and ore deposition. Economic Geology, 69(6): 843–883. https://doi.org/10.2113/gsecongeo.69.6.843
Taylor, Jr., 1997. Oxygen and hydrogen isotope relationships in hydrothermal mineral deposits. In: H.L. Barnes (Editors), Geochemistry of Hydrothermal Ore Deposits. John Wiley and Sons, New York, pp. 229–302. Retrieved April 22, 2020 from https://www.researchgate.net/publication/288948012
Thompson, A.J.B., Thompson, J.F.H. and Dunne, K.P.E., 1996. Atlas of alteration: a field and petrographic guide to hydrothermal alteration minerals. Geological Association of Canada, Canada, 120 pp. Retrieved August 18, 2020 from https://searchworks.stanford.edu/view/3877120
Touret, J.‌L., 1992. CO2 transfer between the upper mantle and the atmosphere: temporary storage in the lower continental crust. Terra Nova, 4(1): 87–98.‏ https://doi.org/10.1111/j.1365-3121.1992.tb00453.x
Torab, F.M., 2008. Geochemistry and metallogeny of magnetite apatite deposits of the Bafq Mining District, Central Iran. Ph.D. Thesis, Technical University of Claustal, Clausthal, Germany, 131 pp. Retrieved July 27, 2020 from https://core.ac.uk/download/pdf/45268823.pdf
Tornos, F., Velasco, F. and Hanchar, J.M., 2016. Iron-rich melts, magmatic magnetite, and superheated hydrothermal systems: The El Laco deposit, Chile. Geology, 44(6): 427–430.‏ https://doi.org/10.1130/G37705.1
Wang, Y., Wang, K. and Konare, Y., 2018. N2-rich fluid in the vein-type Yangjingou scheelite deposit, Yanbian, NE China. Scientific Reports, 8(1): 5662. https://doi.org/10.1038/s41598-018-22227-7
Westhues, A., Hanchar, J.M., LeMessurier, M.J. and Whitehouse, M.J., 2017. Evidence for hydrothermal alteration and source regions for the Kiruna iron oxide–apatite ore (northern Sweden) from zircon Hf and O isotopes. Geology, 45(6): 571–574.‏ https://doi.org/10.1130/G38894.1
Wilkinson, J.J., 2001. Fluid inclusions in hydrothermal ore deposits. Lithos, 55(1–4): 229–272. https://doi.org/10.1016/S0024-4937(00)00047-5
Williams, P.J., Barton, M.D., Johnson, D.A., Fontboté, L., De Haller, A., Mark, G. and Marschik, R., 2005. Iron oxide copper-gold deposits: Geology, space-time distribution, and possible modes of origin. In: J.W. Hedenquist, J.F.H. Thompson, R.J. Goldfarb and J.P. Richards (Editors), Economic Geology, One Hundredth Anniversary Volume. Society of Economic Geologists, Littelton, USA, pp. 371–405.‏ Retrieved June 27, 2020 from https://www.researchgate.net/publication/308527615
Williams, P.‌J. and Blake, K.‌L., 1993. Alteration in the Cloncurry district; Roles of recognition and interpretation in exploration for Cu-Au and Pb-Zn-Ag deposits. Contributions of the Economic Geology Research Unit, Townsville, Queensland, Australia, 72 pp. Retrieved August 26, 2020 from https://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=6384265
Whitney, D.‌L. and Evans, B.‌W., 2010. Abbreviations for names of rock-forming minerals. American mineralogist, 95(1): 185–187.‏ https://doi.org/10.2138/am.2010.3371
Zhaohua, L., Xinxiang, L., Shaofeng, G., Jing, S., Bihe, C., Fan, H. and Zongfeng, Y., 2008. Metallogenic systems on the transmagmatic fluid theory. Acta Petrologica Sinica, 24(12): 2669–2678.‏ Retrieved August 27, 2020 from https://www.researchgate.net/publication/286482625
Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 10 November 2019
  • Revise Date: 01 September 2020
  • Accept Date: 07 September 2020

Share

How to cite

Statistics