Physico-Chemical Characterization of Macusanite and Inclusions: A Volcanic Glass from Peruvian Andes

Azevedo, Murilo Candido de; Santos, Luis Fernando dos; Pereira, Luiz Augusto Stuani; Sáenz, Carlos Alberto Tello; Teixeira, Silvio Rainho; Figueroa, Pedro

doi:10.1590/1980-5373-MR-2021-0033

Abstract

Macusanite is a volcanic glass extracted from the volcanic field Macusani – Peru, formed by the fast cooling of magma. This study shows physical and chemical characterization of Macusanite samples to better understand its molecular structure, elemental composition as well as to investigate the presence of natural inclusions. The characterization of the natural glass can give valuable geological information about the magma composition, the eruption intensity and age of volcanism activity. Moreover, the use of different characterization techniques can help in mineral prospecting. Macusanite was characterized by X-Ray Diffraction/Fluorescence (XRD/XRF), Optical Microscopy, Scanning Electron Microscopy (SEM) and micro-Raman spectroscopy. The latter suggests the presence of andalusite mineral incorporated in the glass structure, while the Energy-Dispersive X-ray Spectroscopy (EDS) analysis indicates the presence of some rich calcium inclusion. Moreover, XRD shows the glass characteristic amorphous band and that the sample is in the glassy stage.

Keywords:
Volcanic Glass; Characterization; Macusanite; Mineral Inclusion

1. Introduction

Volcanic glass, also known as obsidian, is considered a mineraloid as it has no lattice effects like a crystalline structure. It is an amorphous, non-crystalline solid produced by the fast cooling of magma during a volcanic eruption. Moreover, some mineral inclusions may be trapped in the glass structure during its formation process.

Obsidian are mainly composed of silica (SiO₂). High silica magma has over 71-77% of SiO₂¹1 Friedman I, Long W. Volcanic glasses, their origins and alteration processes. J Non-Cryst Solids. 1984;67(1-3):127-33., which indicates a very viscous magma and, consequently, a violent volcanic eruption, in contrast with low silica magma which is very fluid. Magmas with more than 65% of silica are classified as felsic and are often explosive since lava easily obstructs the volcanic chimney. When these magmas solidifies outside the surface, like and extrusive rock, they get classified as a rhyolite. This type of obsidian can be found in deposits of tens of meters thick.

Silica can attract oxygen in magma producing the polymerization, which is a long chain of bonding molecules that increases the viscosity of the medium. Moreover, it can affect the formation of crystals by hindering the movement of ions that are responsible for the crystal growth and, consequently, few minerals are formed²2 Kudo AM, Jahns RH. Igneous rock. Encyclopedia Britannica; 2020. [cited 2021 Feb 28]. Available in: https://www.britannica.com/science/igneous-rock
https://www.britannica.com/science/igneo... . This behavior is more intense for felsic lavas³3 Society of Chemical Industry. It came from under the earth. Vol. 3. C&I; 2014. [cited 2021 Feb 27]. Available from: https://www.soci.org/chemistry-and-industry/cni-data/2014/3/it-came-from-under-the-earth
https://www.soci.org/chemistry-and-indus... .

Macusani is a volcanic field located in the province of Carabaya in Peru, with a longitude of 70 ° 27 'W. and latitude 14 ° 4 'S., at 4.3 km of altitude from sea level⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.. Glass pebbles found in volcanic rocks in the field are known as Macusanite, which was first found in fluvio-glacial sediments⁵5 Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305..

Macusanite was the source of some shipped stone artifacts in the archaic period, found at distances of more than 120 km from Macusani⁶6 Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76.. This obsidian has a translucent green appearance, but can occur in different colors⁶6 Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76..

Mineral characterization studies have resulted in important advances in the association between cooling magma and amorphous structure. In addition, it serves as a source of studies for improvement in radiometric dating. Some studies about its properties indicate it can be used in technological applications, such as economical adsorption of heavy metals⁷7 Steinhauser G, Bichler M. Adsorption of ions onto high silica volcanic glass. Appl Radiat Isot. 2008;66(1):1-8.^,⁸8 Ortega HL, Fernández HM, López CR, Autie MA, Infantes MA, Rodríguez CE. Cu2+ removal from aqueous solution with a Cuban volcanic glass mineral. International Journal of Plant. Animal and Environmental Sciences. 2015;6:174-83., radioactive cations and anions, and different biomolecules due to its macroporosity, which also provides application in construction, as abrasive, acoustic, filter as well as in the agriculture field⁹9 Cecilia JA, Autie-Pérez MA, Labadie-Suarez JM, Castellón ER, Molina AI. Volcanic glass and its uses as adsorbent. In: Aiello G, editor. Volcanoes - geological and geophysical setting, theoretical aspects and numerical modeling, applications to industry and their impact on the human health. London: Headquarters IntechOpen Limited; 2018.^,¹⁰10 Autie PM, Infantes MA, Cecilia J, Labadie SJ, Rodríguez CE. Separation of light liquid paraffin C5–C9 with cuban volcanic glass previously used in copper elimination from water solutions. Appl Sci (Basel). 2018;8(2):295..

The Canadian company Plateau Energy Metals found large deposits of lithium and uranium in the volcanic regions near Macusani, which may have the largest lithium reserves in the world¹¹11 Macusani Uranium Project. Plateau energy metals [cited 2020 Dec 9]. Available from: https://plateauenergymetals.com/macusani-uranium-project/
https://plateauenergymetals.com/macusani... . The discovery of high content of lithium in Macusanite¹²12 London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73. may have contributed to the exploration companies to develop projects in the region of Macusani. Moreover, this obsidian constitutes one of the greatest examples of uranium mineralization associated with pyroclastic rocks⁵5 Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305..

This work aims to physically and chemically characterize Macusanite samples via different methods used in material sciences (optical microscopy, scanning electron microscopy, micro-Raman spectroscopy, X-ray diffraction and X-ray fluorescence) to better understand the volcanic glass elemental composition as well as the presence of mineral inclusions which were trapped in the glass during its formation process. Moreover, the X-ray fluorescence technique may provide geological information about the magma that originated the volcanic glass.

2. Macusanite Property Investigation

Craig et al.⁶6 Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76. studied the Macusanite geological settlements as well as its use as a source material for artifacts in ancient times through comparisons of various calculated ages of this mineraloid.

Macusanite pebbles have been dated by a variety of radioisotopic techniques as fission track method, potassium-argon, argon-argon, etc., which show ages of about 4 to 10 million years⁵5 Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305.^,¹³13 Poupeau G, Labrin E, Sabil N, Bigazzi G, Arroyo G, Vatin-Pérignon N. Fission-track dating of 15 macusanite glass pebbles from the Macusani volcanic field (SE Peru). Nucl Tracks Radiat Meas. 1993;21(4):499-506.

14 Osorio AAM, Iunes PJ, Bigazzi G, Hadler N. JC, Laurenzi MA, Norelli P, Paulo SR. Fission-track dating of Macusanite glasses with plateau and size correction methods. Radiat Meas. 2003;36(1-6):407-12.^-¹⁵15 Tello SCA, Curvo E, Iunes P, Soares C, Alencar I, Guedes S, et al. Fission-track dating applied to Peruvian volcanic glasses. Revista de la Facultad de Ciencias de la UNI REVCIUNI. 2012;15:71.. Since the chemical composition varies among different pebbles, this indicates they may have come from distinct volcanic eruptions and may explain why the ages are different⁵5 Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305.^,⁶6 Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76.^,¹⁴14 Osorio AAM, Iunes PJ, Bigazzi G, Hadler N. JC, Laurenzi MA, Norelli P, Paulo SR. Fission-track dating of Macusanite glasses with plateau and size correction methods. Radiat Meas. 2003;36(1-6):407-12.. Later volcanism led to the deposition of obsidians.

Macusanite glass has been characterized through different techniques as electrical resistance¹⁶16 Rodrigues OVJ, Stuani PLA, Assunção SE, Tello SCA, Almeida OC. Electrical characterization of the Macusanite volcanic glass and influence of nuclear fission tracks on electrical conductivity. Radiat Phys Chem. 2020, micro-Raman spectroscopy¹⁷17 Zotov N. Structure of natural volcanic glasses: diffraction versus spectroscopic perspective. J Non-Cryst Solids. 2003;323:1-6. and atomic force microscopy¹⁸18 Stuani PLA, Candido AM, Nakasuga WM, Figueroa P, Tello SCA. Fission-track evolution in Macusanite volcanic glass. Radiat Phys Chem. 2020. Investigation of its elemental composition indicate it is mostly composed of high concentration (~ 70-73%) of SiO₂, ~ 15% of aluminum oxide (Al₂O₃) and some oxides like K₂O, Na₂O, CaO. Moreover, trace elements were also found in the glass molecular structure, e.g., H₂O, FeO, Fe₂O₃, MgO and others⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.^,¹²12 London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73.^,¹⁹19 Elliott CJ, Moss AA. Natural glass from Macusani, Peru. Mineral Mag J Mineral Soc. 1965;35(270):423-4.^,²⁰20 Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523..

Linck²¹21 Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74. was one of the pioneers to investigate Macusanite and found the presence of zircon, andalusite, wollastonite, scapolite, sanidine, sillimanite, aegirine-augite and oligoclase-andesine incorporated in the glass structure. At this time, Macusanite was thought to be a tektite instead of an obsidian as both are made from a natural glass⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970..

Macusanite has properties that should be similar to obsidians belonging to the rhyolite group, whose density is approximately 2.3 g/cm³²²22 Husien MS. Fracture behavior and mechanical characterization of obsidian: naturally occurring glass. [dissertation]. Oklahoma: Oklahoma State University; 2010.^,²³23 van Otterloo J, Cas AF, Scutter CR. The fracture behaviour of volcanic glass and relevance to quench fragmentation during formation of hyaloclastite and phreatomagmatism. Earth Sci Rev. 2015;151:79-116. and hardness on the Mohs scale between 5 and 6²⁴24 Geology Page. Obsidian: what is obsidian? Why obsidian is black?. 2019 [cited 2021 Feb 28]. Available from: geologypage.com/2019/08/obsidian-what-is-obsidian-why-obsidian-is-black.html
geologypage.com/2019/08/obsidian-what-is... . According to Husien²²22 Husien MS. Fracture behavior and mechanical characterization of obsidian: naturally occurring glass. [dissertation]. Oklahoma: Oklahoma State University; 2010., the obsidian hardness is greater when compared to common glass, and its structure becomes more rigid with increasing Al₂O₃ content.

Obsidian reacts to water by breaking the atomic bonds of the silicate network²³23 van Otterloo J, Cas AF, Scutter CR. The fracture behaviour of volcanic glass and relevance to quench fragmentation during formation of hyaloclastite and phreatomagmatism. Earth Sci Rev. 2015;151:79-116., which increases the rate with the temperature. This weathering process is called hydration, and it also causes an increase in the volume of the glass.

Cracks in volcanic glass propagate as multiple micro-cracks that reach pre-existing micro-fractures and not only a single fracture. Moreover, these cracks work as pathways for fluids, favoring the water-silica interaction in the inner micro-regions of the glass.

Regarding the thermal conductivity of silica glasses, it is about 1.7 W(m·K) at T = 100 ºC. The glass strength behavior displays an elastic deformation according to the classical Hooke's law followed by a fracture once the cohesive strength exceeds. The maximum cohesive strength under tension for volcanic glasses is 30 Mpa²³23 van Otterloo J, Cas AF, Scutter CR. The fracture behaviour of volcanic glass and relevance to quench fragmentation during formation of hyaloclastite and phreatomagmatism. Earth Sci Rev. 2015;151:79-116..

3. Materials and Methods

3.1. Macusanite preparation

Some Macusanite pebbles of different sizes, ranging from 1 cm to 5 cm in diameter, were selected for all characterization processes, which are shown in Figure 1a. The natural glass was pulverized using a disc mill (Marconi, model MA 360) with orbital agitation of about 5 minutes, resulting in a homogenized powder (Figure 1b). Some thin glass pieces were sanded both sides with three different granulometry sandpapers: 1200, 2400 and 4000 mesh with 70 rpm during 5 minutes for each piece in a Struers model polishing machine.

Figure 1
Macusanite pebbles (a) and their powder (b) form used in the study.

These pebbles were collected in Macusani Town, Corani district, in depostis Chilcuno Chico and Caluyo Mayo. Macusanite was found either as an inclusion in pyroclastic rocks of Quenamari formation, or as a pebble at the bottom of the ravine of the volcanic environment. A panning was carried out on the banks of the river, in which pieces of various sizes were found.

3.2. Optical microscope

Possible inclusions inside Macusanite were photomicrographed via MC170 HD microscope with transmitted light and with a 10X ocular lens and a 20X objective lens, producing a total magnification of 200X. A micro-area with two visible mineral inclusions were selected and their lengths were measured. For this procedure, a thin piece was sanded so that it was flat on both sides.

3.3. Scanning Electron Microscope (SEM)

For the SEM analyses one pebble of Macusanite was sanded both sides and another turned into powder to investigate its topology and physical characteristics with a Backscatter electron Detector (BSD). Moreover, the elemental composition of the volcanic glass was identified and quantified with an electron-dispersive spectrometer by weighting the elements in the mineraloid in the compact and powder form. The measurement instrument is an EVO LS-15 microscope Zeiss with a voltage of 20 kV. The sample was coated with carbon in an evaporation process (Q150TE, Quorum). Backscattering analysis scans the surface based on the weight of the chemical elements. Because heavy elements can backscatter electrons in greater quantities than lighter ones, they appear lighter in the image²¹21 Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74..

3.4. Micro-raman spectroscopy

Raman spectra of Macusanite were obtained by a Raman Renishaw inVia spectrometer, equipped with a Leica optical microscope and a video camera allowing a direct visualization of the sample, 50X objective lens with a spatial resolution of 1 μm². The Raman spectra were collected in the region of 200-2250 cm^-1 with a 633 nm helium-neonium laser line and 50% laser power. The measurements were performed to investigate the presence of mineral inclusions trapped in the glass.

3.5. X-Ray Fluorescence (XRF)

The X-ray fluorescence spectroscopy analysis was carried out to determine the chemical composition in weight percent (wt%) of Macusanite, using a Rh anode as the excitation source. The scans were performed in the energy range from Na to U, in qualitative and quantitative mode at room temperature in a vacuum. The measurement was carried out in a Shimadzu spectrometer (XRF-700).

3.6. X-Ray Diffractometry (XRD)

XRD analysis was carried out in a diffractometer (XRD 6000, Shimadzu) at room temperature with Cu-K_α1 (λ=1.5406 Å) radiation, 1º divergence and reception slits, in the continuous scan, 40 kV voltage, 30 mA current, 2 º/min scan speed, and 2θ angular range from 10º to 80º. For XRF and XRD analyses the powder sample was used.

4. Results and Discussion

Figure 2 shows a photomicrograph of two mineral inclusions trapped in the volcanic glass sample, which have dimensions of up to 450 µm on its major axis. Some other small inclusions are also visible throughout the glass surface.

Figure 2
Photomicrograph of Macusanite with transmitted light and a total magnification of 200x.

The SEM photomicrographs obtained using BSD are shown in Figure 3. The images were taken from the sanded surface of the sample in powder form (a) and compact form (b).

Figure 3
SEM images of Macusanite in powder (a) and compact (b) form with a total magnification of 1000x via BSD detector.

The results of the chemical composition by scanning with the EDS detector can be seen in Table 1.

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Table 1
Elemental composition of Macusanite by SEM/EDS.

Regarding the chemical composition, both samples do not present any significant difference. The results show a high prevalence of oxygen, silicon and aluminum elements, which are components of the most abundant molecules in the mineral structure (silica (SiO₂) and alumina (Al₂O₃)). Moreover, trace elements show marked depletions in F, Na, K, Ca, Fe e Cu, which is in agreement with the literature⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.^,¹²12 London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73.^,¹⁹19 Elliott CJ, Moss AA. Natural glass from Macusani, Peru. Mineral Mag J Mineral Soc. 1965;35(270):423-4.^,²⁰20 Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523..

Figure 4 shows the dispersion of calcium through the powdered glass structure, that indicates some spot micro-areas with mineral inclusions composed of calcium. Linck²¹21 Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74. found some mineral inclusions in Macusanite with calcium composition: wollastonite (CaSiO₃), scapolite (Na₄Al₃Si₉O₂₄Cl to Ca₄Al₆Si₆O₂₄CO₃), oligoclase-andesine ((Na,Ca)[Al(Si,Al)Si₂O₈]) and aegirine-augite ((Ca,Na)(Fe³⁺,Mg,Fe²⁺)Si₂O₆). The calcium-rich inclusions found by SEM-EDS may be attributed to any of the above minerals, however, further investigation is required.

Figure 4
Calcium dispersion in Macusanite through EDS.

Zircon grains (ZrSiO₄) have also been found in other Macusanite sample characterized via SEM analysis by our research group. Therefore, this microscopic technique can assist in mineral prospecting by identifying valuable inclusions. As a common accessory mineral in igneous rocks, zircon contains a large amount of uranium and thorium in levels of about tens to thousands parts per million (ppm)²⁵25 Marsellos A, Garver J. Radiation damage and uranium concentration in zircon as assessed by Raman spectroscopy and neutron irradiation. Am Mineral. 2010;95(8-9):1192-201.. In addition, this mineral has a hardness of 7.5 on the Mohs scale and is resistant to various geological processes, which makes it routinely used in radioisotopic dating process, e.g. the fission-track method, U-Pb and U-Th/He dating. Moreover, in the industry of ceramics zircon is the main opacifier in ceramic applications²⁶26 Yildiz B, Ozturk ZB. Investigation of the usage of whitening agents as an alternative to zircon in opaque frit compositions. Acta Physica Polonica Series A. 2015;127:1180-182..

Volcanic glasses are known in micro-Raman spectroscopy by their large band spectra as they do not have a crystalline structure²⁷27 Di Genova D, Morgavi D, Hess KU, Neuville DR, Borovkov N, Perugini D, et al. Approximate chemical analysis of volcanic glasses using Raman spectroscopy. J Raman Spectrosc. 2015;46(12):1235-44.. Therefore, Macusanite spectrum collected with 633 nm laser is like other obsidian and silicate glasses collected with 415, 514 and 633 nm reported in the literature²⁸28 Carter EA, Hargreaves MD, Kononenko N, Graham I, Edwards HGM, Swarbrick B, et al. Raman spectroscopy applied to understanding Prehistoric Obsidian Trade in the Pacific Region. Vib Spectrosc. 2009;50(1):116-24.. The Raman spectrum in Figure 5 was obtained from a crystalline inclusion (Figure 6) in Macusanite. According to Linck²¹21 Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74. this spectrum is similar to the andalusite (Al₂SiO₅) mineral. The spectrum was compared with the RRUFF™ Project database of Raman Spectra²⁹29 Lafuente B, Downs RT, Yang H, Stone N. The power of databases: the RRUFF project. In: Armbruster T, Danisi RM, editors. Highlights in mineralogical crystallography. Berlin, Germany: W. De Gruyter; 2015. p. 1-30. [cited 2020 Nov 28]. Available from: https://rruff.info/Andalusite/R060212
https://rruff.info/Andalusite/R060212... for andalusite (see Table 2).

Figure 5
Raman Spectrum of Macusanite inclusion.

Figure 6
Macusanite inclusion.

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Table 2
Raman Shift of peaks in Macusanite inclusion and Andalusite.

Andalusite is an important mineral in metamorphosed aluminous rock, such as metapelitic schist and micaceous quartzite³⁰30 Zhai K, Xue W, Wang H, Wu X, Zhai S. Raman spectra of sillimanite, andalusite, and kyanite at various temperatures. Phys Chem Miner. 2020;47(5):1-11.. It has an orthorhombic structure with Pnnm space group³¹31 Taylor WH. The structure of andalusite, Al2SiO5. Z Kristallogr Cryst Mater. 1929;71:205-18.

32 Burnham CW, Buerger MJ. Refinement of the crystal structure of kyanite. Z Kristallogr Cryst Mater. 1961;115:269-90.^-³³33 Winter JK, Ghose S. Thermal expansion and high-temperature crystal chemistry of the Al2SiO5 polymorphs. Am Mineral. 1979;64:573-86.. According to the factor group theory, it has 48 predicted Raman active modes²⁸28 Carter EA, Hargreaves MD, Kononenko N, Graham I, Edwards HGM, Swarbrick B, et al. Raman spectroscopy applied to understanding Prehistoric Obsidian Trade in the Pacific Region. Vib Spectrosc. 2009;50(1):116-24.. The Raman spectrum of andalusite shows characteristics of an orthosilicate, the spectral bands above 800 cm^-1 correspond to the stretching modes of SiO₄, while the bending mode of SiO₄ occurs around 360 cm^{-1 30}. Because of the poor symmetry and poor degeneracy, there are many other Raman bands in the range from 200 to 400 cm⁻¹ corresponding to the bending mode of Al^VI–O.

Macusanite has a considerable amount of alumina, which may explain why andalusite is not an unusual inclusion, whose chemical composition is 62.9% Al₂O₃ and 37.1% SiO₂³⁴34 Danilo F, Dirk H, Florian A, Christopher P. Andalusite based raw materials for Refractory Castable: properties and application. Paris: Imerys Refractory Minerals; 2018..

In Biotite (silicate mineral) the presence of andalusite crystals identical to those in Macusanite were also found. Moreover, measurements performed in this mineral indicate the presence of uranium, thorium and lead, which makes andalusite also used in geological dating methods like zircon mineral⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.. Since andalusite has high resistance to thermal gradients and thermal shocks, it is greatly used in the industry for refractory construction and also in the foundry³⁴34 Danilo F, Dirk H, Florian A, Christopher P. Andalusite based raw materials for Refractory Castable: properties and application. Paris: Imerys Refractory Minerals; 2018..

The chemical composition of Macusanite, as determined by XRF spectroscopy, is shown in Table 3. It consists mainly of 74.36% of silicon oxide (SiO₂), which is characteristic of the silica formation in bonding with the oxygen from the volcanic lava, and 18.25% of alumina (Al₂O₃). Both of them are the most predominant oxides in the glass, followed by K₂O e Fe₂O₃ and some traces as CaO, P₂O₅, etc. The measured silica concentration is higher than the ones found in the literature, which is about 70-73%⁴4 Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.^,¹²12 London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73.^,¹⁹19 Elliott CJ, Moss AA. Natural glass from Macusani, Peru. Mineral Mag J Mineral Soc. 1965;35(270):423-4.^,²⁰20 Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523.. XRF is a technique that can help to identify the magma type that originated the glass, which in this case it is a felsic magma that causes an explosive volcanic eruption (as the concentration of silica is about 74%)¹1 Friedman I, Long W. Volcanic glasses, their origins and alteration processes. J Non-Cryst Solids. 1984;67(1-3):127-33..

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Table 3
Chemical composition of Macusanite by XRF spectroscopy.

Regarding the XRD analysis (Figure 7), the diffractogram does not show any presence of crystalline phases, there is only a characteristic band of an amorphous material around the position of Bragg 2θ = 30º. Since magma cools quickly through the glass transition temperature there is not sufficient time for the rock crystallization.

Figure 7
X-ray Diffraction analysis of Macusanite.

Natural glasses have short lifetime in geologic time scale, as they are unstable and tend to crystallize into a spherulite, which contains silicate crystals like quartz and feldspar. However, rhyolitic glasses can have a longer lifetime, up to approximately 60 million years¹1 Friedman I, Long W. Volcanic glasses, their origins and alteration processes. J Non-Cryst Solids. 1984;67(1-3):127-33..

The process of transforming glass from a vitreous to a crystalline phase is known as devitrification. The diffusion process of water acts as a catalyst, and at low temperatures it slows down³⁵35 Marshall RR. Devitrification of natural glass. Geol Soc Am Bull. 1961;72(10):1493.. Therefore, the glass can change in events involving water and geothermal processes.

The devitrification process can reach three stages in rhyolitic glass: i) the glassy (with some spherulites as inclusions, which are spherical semicrystalline bodies that occur in glassy rocks); ii) the spherulitic (with some mineral inclusions of quartz); and iii) the granitic texture³⁶36 Lofgren G. Experimentally produced devitrification textures in natural rhyolitic glass. Geol Soc Am Bull. 1971;82(1):111..

Gimeno³⁷37 Gimeno D. Devitrification of natural rhyolitic obsidian glasses: petrographic and microstructural study (SEM+EDS) of recent (Lipari island) and ancient (Sarrabus, SE Sardinia) samples. J Non-Cryst Solids. 2003;323:84-90. showed that SEM can be useful for analyzing the devitrification process by revealing the growth of the crystal components, and discovered that phenocrysts, microphenocrysts and all kinds of previous crystalline materials act as nucleation sites for spherulites. Moreover, the most viscous lava like felsic ones show poor development of spherulites, unlike the less viscous magma rocks that present advanced stages of spherulites.

According to the XRD analysis, Macusanite shows a characteristic amorphous band and no presence of spherulites as inclusions, since this obsidian is no more than 10 million years. This result indicates that Macusanite is in the glassy stage and it is still young in comparison to the time needed to reach the last stage of devitrification. As the stages progress, the crystalline structure starts to become majority in the volcanic glass. Thus, the XRD can be a technique to inform the degree of crystallization of natural glasses.

5. Conclusions

The SEM and micro-Raman analyses are two non-destructive techniques that can be used to identify inclusions in volcanic glass, such as zircon and andalusite, which have already been dated to provide information about the thermal history of the mineral. Moreover, the lengths of these minerals are big enough to be dated through radioisotopic processes. Calcium-rich inclusions were detected by SEM/EDS, which may be wollastonite, scapolite, oligoclase-andesine and aegirine-augite. XRD is an important technique to analyze the degree of devitrification of a glass, showing that Macusanite age of less than 10 million years is quite young compared to time needed to reach the last stage of devitrification. Moreover, according to the XRF analysis Macusanite has a slightly higher amount of silica (74.35%) than others previously analyzed in the literature. The silica concentration indicates the magma produced the volcanic glass is felsic in origin.

6. Acknowledgements

This study was financed in part by the Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - Brasil (CAPES) - Finance Code 001, as well as the Brazilian foundations FAPESP (Fundação e Amparo à Pesquisa do Estado de São Paulo) [scholarship 2018/24203-1] and CNPq (Conselho Nacional de Desenvolvimento Científico e Tecnológico).

7. References

¹
Friedman I, Long W. Volcanic glasses, their origins and alteration processes. J Non-Cryst Solids. 1984;67(1-3):127-33.
²
Kudo AM, Jahns RH. Igneous rock. Encyclopedia Britannica; 2020. [cited 2021 Feb 28]. Available in: https://www.britannica.com/science/igneous-rock
» https://www.britannica.com/science/igneous-rock
³
Society of Chemical Industry. It came from under the earth. Vol. 3. C&I; 2014. [cited 2021 Feb 27]. Available from: https://www.soci.org/chemistry-and-industry/cni-data/2014/3/it-came-from-under-the-earth
» https://www.soci.org/chemistry-and-industry/cni-data/2014/3/it-came-from-under-the-earth
⁴
Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.
⁵
Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305.
⁶
Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76.
⁷
Steinhauser G, Bichler M. Adsorption of ions onto high silica volcanic glass. Appl Radiat Isot. 2008;66(1):1-8.
⁸
Ortega HL, Fernández HM, López CR, Autie MA, Infantes MA, Rodríguez CE. Cu2+ removal from aqueous solution with a Cuban volcanic glass mineral. International Journal of Plant. Animal and Environmental Sciences. 2015;6:174-83.
⁹
Cecilia JA, Autie-Pérez MA, Labadie-Suarez JM, Castellón ER, Molina AI. Volcanic glass and its uses as adsorbent. In: Aiello G, editor. Volcanoes - geological and geophysical setting, theoretical aspects and numerical modeling, applications to industry and their impact on the human health. London: Headquarters IntechOpen Limited; 2018.
¹⁰
Autie PM, Infantes MA, Cecilia J, Labadie SJ, Rodríguez CE. Separation of light liquid paraffin C5–C9 with cuban volcanic glass previously used in copper elimination from water solutions. Appl Sci (Basel). 2018;8(2):295.
¹¹
Macusani Uranium Project. Plateau energy metals [cited 2020 Dec 9]. Available from: https://plateauenergymetals.com/macusani-uranium-project/
» https://plateauenergymetals.com/macusani-uranium-project/
¹²
London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73.
¹³
Poupeau G, Labrin E, Sabil N, Bigazzi G, Arroyo G, Vatin-Pérignon N. Fission-track dating of 15 macusanite glass pebbles from the Macusani volcanic field (SE Peru). Nucl Tracks Radiat Meas. 1993;21(4):499-506.
¹⁴
Osorio AAM, Iunes PJ, Bigazzi G, Hadler N. JC, Laurenzi MA, Norelli P, Paulo SR. Fission-track dating of Macusanite glasses with plateau and size correction methods. Radiat Meas. 2003;36(1-6):407-12.
¹⁵
Tello SCA, Curvo E, Iunes P, Soares C, Alencar I, Guedes S, et al. Fission-track dating applied to Peruvian volcanic glasses. Revista de la Facultad de Ciencias de la UNI REVCIUNI. 2012;15:71.
¹⁶
Rodrigues OVJ, Stuani PLA, Assunção SE, Tello SCA, Almeida OC. Electrical characterization of the Macusanite volcanic glass and influence of nuclear fission tracks on electrical conductivity. Radiat Phys Chem. 2020
¹⁷
Zotov N. Structure of natural volcanic glasses: diffraction versus spectroscopic perspective. J Non-Cryst Solids. 2003;323:1-6.
¹⁸
Stuani PLA, Candido AM, Nakasuga WM, Figueroa P, Tello SCA. Fission-track evolution in Macusanite volcanic glass. Radiat Phys Chem. 2020
¹⁹
Elliott CJ, Moss AA. Natural glass from Macusani, Peru. Mineral Mag J Mineral Soc. 1965;35(270):423-4.
²⁰
Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523.
²¹
Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74.
²²
Husien MS. Fracture behavior and mechanical characterization of obsidian: naturally occurring glass. [dissertation]. Oklahoma: Oklahoma State University; 2010.
²³
van Otterloo J, Cas AF, Scutter CR. The fracture behaviour of volcanic glass and relevance to quench fragmentation during formation of hyaloclastite and phreatomagmatism. Earth Sci Rev. 2015;151:79-116.
²⁴
Geology Page. Obsidian: what is obsidian? Why obsidian is black?. 2019 [cited 2021 Feb 28]. Available from: geologypage.com/2019/08/obsidian-what-is-obsidian-why-obsidian-is-black.html
» geologypage.com/2019/08/obsidian-what-is-obsidian-why-obsidian-is-black.html
²⁵
Marsellos A, Garver J. Radiation damage and uranium concentration in zircon as assessed by Raman spectroscopy and neutron irradiation. Am Mineral. 2010;95(8-9):1192-201.
²⁶
Yildiz B, Ozturk ZB. Investigation of the usage of whitening agents as an alternative to zircon in opaque frit compositions. Acta Physica Polonica Series A. 2015;127:1180-182.
²⁷
Di Genova D, Morgavi D, Hess KU, Neuville DR, Borovkov N, Perugini D, et al. Approximate chemical analysis of volcanic glasses using Raman spectroscopy. J Raman Spectrosc. 2015;46(12):1235-44.
²⁸
Carter EA, Hargreaves MD, Kononenko N, Graham I, Edwards HGM, Swarbrick B, et al. Raman spectroscopy applied to understanding Prehistoric Obsidian Trade in the Pacific Region. Vib Spectrosc. 2009;50(1):116-24.
²⁹
Lafuente B, Downs RT, Yang H, Stone N. The power of databases: the RRUFF project. In: Armbruster T, Danisi RM, editors. Highlights in mineralogical crystallography. Berlin, Germany: W. De Gruyter; 2015. p. 1-30. [cited 2020 Nov 28]. Available from: https://rruff.info/Andalusite/R060212
» https://rruff.info/Andalusite/R060212
³⁰
Zhai K, Xue W, Wang H, Wu X, Zhai S. Raman spectra of sillimanite, andalusite, and kyanite at various temperatures. Phys Chem Miner. 2020;47(5):1-11.
³¹
Taylor WH. The structure of andalusite, Al₂SiO₅ Z Kristallogr Cryst Mater. 1929;71:205-18.
³²
Burnham CW, Buerger MJ. Refinement of the crystal structure of kyanite. Z Kristallogr Cryst Mater. 1961;115:269-90.
³³
Winter JK, Ghose S. Thermal expansion and high-temperature crystal chemistry of the Al₂SiO₅ polymorphs. Am Mineral. 1979;64:573-86.
³⁴
Danilo F, Dirk H, Florian A, Christopher P. Andalusite based raw materials for Refractory Castable: properties and application. Paris: Imerys Refractory Minerals; 2018.
³⁵
Marshall RR. Devitrification of natural glass. Geol Soc Am Bull. 1961;72(10):1493.
³⁶
Lofgren G. Experimentally produced devitrification textures in natural rhyolitic glass. Geol Soc Am Bull. 1971;82(1):111.
³⁷
Gimeno D. Devitrification of natural rhyolitic obsidian glasses: petrographic and microstructural study (SEM+EDS) of recent (Lipari island) and ancient (Sarrabus, SE Sardinia) samples. J Non-Cryst Solids. 2003;323:84-90.

Publication Dates

Publication in this collection
05 July 2021
Date of issue
2021

History

Received
12 Jan 2021
Reviewed
30 Mar 2021
Accepted
16 June 2021

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Friedman I, Long W. Volcanic glasses, their origins and alteration processes. J Non-Cryst Solids. 1984;67(1-3):127-33.

[2] ²
Kudo AM, Jahns RH. Igneous rock. Encyclopedia Britannica; 2020. [cited 2021 Feb 28]. Available in: https://www.britannica.com/science/igneous-rock
» https://www.britannica.com/science/igneous-rock

[3] ³
Society of Chemical Industry. It came from under the earth. Vol. 3. C&I; 2014. [cited 2021 Feb 27]. Available from: https://www.soci.org/chemistry-and-industry/cni-data/2014/3/it-came-from-under-the-earth
» https://www.soci.org/chemistry-and-industry/cni-data/2014/3/it-came-from-under-the-earth

[4] ⁴
Barnes VE, George E, Mclaughlin WA, Irving F, Oiva J. Macusanite occurrence, age, and composition, Macusani, Peru: Geological Society of America Bulletin; 1970.

[5] ⁵
Poupeau G, Sabil N, Villa IM, Bigazzi G, Vatin-Perignon N, Flores P, et al. Fission-track and K-Ar ages of “macusanite” obsidian glasses, (SE Peru): geodynamic implications. Tectonophysics. 1992;205:295-305.

[6] ⁶
Craig N, Robert JS, Rachel SPF, Mark A, Luis FB, Margaret BV, et al. Macusani obsidian from southern Peru: A characterization of its elemental composition with a demonstration of its ancient use. J Archaeol Sci. 2010;37:569-76.

[7] ⁷
Steinhauser G, Bichler M. Adsorption of ions onto high silica volcanic glass. Appl Radiat Isot. 2008;66(1):1-8.

[8] ⁸
Ortega HL, Fernández HM, López CR, Autie MA, Infantes MA, Rodríguez CE. Cu2+ removal from aqueous solution with a Cuban volcanic glass mineral. International Journal of Plant. Animal and Environmental Sciences. 2015;6:174-83.

[9] ⁹
Cecilia JA, Autie-Pérez MA, Labadie-Suarez JM, Castellón ER, Molina AI. Volcanic glass and its uses as adsorbent. In: Aiello G, editor. Volcanoes - geological and geophysical setting, theoretical aspects and numerical modeling, applications to industry and their impact on the human health. London: Headquarters IntechOpen Limited; 2018.

[10] ¹⁰
Autie PM, Infantes MA, Cecilia J, Labadie SJ, Rodríguez CE. Separation of light liquid paraffin C5–C9 with cuban volcanic glass previously used in copper elimination from water solutions. Appl Sci (Basel). 2018;8(2):295.

[11] ¹¹
Macusani Uranium Project. Plateau energy metals [cited 2020 Dec 9]. Available from: https://plateauenergymetals.com/macusani-uranium-project/
» https://plateauenergymetals.com/macusani-uranium-project/

[12] ¹²
London D, Hervig RL, Morgan GB. Melt-vapor solubilities and elemental partitioning in peraluminous granite-pegmatite systems: experimental results with Macusani glass at 200 MPa. Contrib Mineral Petrol. 1988;99(3):360-73.

[13] ¹³
Poupeau G, Labrin E, Sabil N, Bigazzi G, Arroyo G, Vatin-Pérignon N. Fission-track dating of 15 macusanite glass pebbles from the Macusani volcanic field (SE Peru). Nucl Tracks Radiat Meas. 1993;21(4):499-506.

[14] ¹⁴
Osorio AAM, Iunes PJ, Bigazzi G, Hadler N. JC, Laurenzi MA, Norelli P, Paulo SR. Fission-track dating of Macusanite glasses with plateau and size correction methods. Radiat Meas. 2003;36(1-6):407-12.

[15] ¹⁵
Tello SCA, Curvo E, Iunes P, Soares C, Alencar I, Guedes S, et al. Fission-track dating applied to Peruvian volcanic glasses. Revista de la Facultad de Ciencias de la UNI REVCIUNI. 2012;15:71.

[16] ¹⁶
Rodrigues OVJ, Stuani PLA, Assunção SE, Tello SCA, Almeida OC. Electrical characterization of the Macusanite volcanic glass and influence of nuclear fission tracks on electrical conductivity. Radiat Phys Chem. 2020

[17] ¹⁷
Zotov N. Structure of natural volcanic glasses: diffraction versus spectroscopic perspective. J Non-Cryst Solids. 2003;323:1-6.

[18] ¹⁸
Stuani PLA, Candido AM, Nakasuga WM, Figueroa P, Tello SCA. Fission-track evolution in Macusanite volcanic glass. Radiat Phys Chem. 2020

[19] ¹⁹
Elliott CJ, Moss AA. Natural glass from Macusani, Peru. Mineral Mag J Mineral Soc. 1965;35(270):423-4.

[20] ²⁰
Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523.

[21] ²¹
Linck G. Ein neuer knstallfiihrender Tektit von Paucartambo in Peru. Chem Erde. 1926;2:157-74.

[22] ²²
Husien MS. Fracture behavior and mechanical characterization of obsidian: naturally occurring glass. [dissertation]. Oklahoma: Oklahoma State University; 2010.

[23] ²³
van Otterloo J, Cas AF, Scutter CR. The fracture behaviour of volcanic glass and relevance to quench fragmentation during formation of hyaloclastite and phreatomagmatism. Earth Sci Rev. 2015;151:79-116.

[24] ²⁴
Geology Page. Obsidian: what is obsidian? Why obsidian is black?. 2019 [cited 2021 Feb 28]. Available from: geologypage.com/2019/08/obsidian-what-is-obsidian-why-obsidian-is-black.html
» geologypage.com/2019/08/obsidian-what-is-obsidian-why-obsidian-is-black.html

[25] ²⁵
Marsellos A, Garver J. Radiation damage and uranium concentration in zircon as assessed by Raman spectroscopy and neutron irradiation. Am Mineral. 2010;95(8-9):1192-201.

[26] ²⁶
Yildiz B, Ozturk ZB. Investigation of the usage of whitening agents as an alternative to zircon in opaque frit compositions. Acta Physica Polonica Series A. 2015;127:1180-182.

[27] ²⁷
Di Genova D, Morgavi D, Hess KU, Neuville DR, Borovkov N, Perugini D, et al. Approximate chemical analysis of volcanic glasses using Raman spectroscopy. J Raman Spectrosc. 2015;46(12):1235-44.

[28] ²⁸
Carter EA, Hargreaves MD, Kononenko N, Graham I, Edwards HGM, Swarbrick B, et al. Raman spectroscopy applied to understanding Prehistoric Obsidian Trade in the Pacific Region. Vib Spectrosc. 2009;50(1):116-24.

[29] ²⁹
Lafuente B, Downs RT, Yang H, Stone N. The power of databases: the RRUFF project. In: Armbruster T, Danisi RM, editors. Highlights in mineralogical crystallography. Berlin, Germany: W. De Gruyter; 2015. p. 1-30. [cited 2020 Nov 28]. Available from: https://rruff.info/Andalusite/R060212
» https://rruff.info/Andalusite/R060212

[30] ³⁰
Zhai K, Xue W, Wang H, Wu X, Zhai S. Raman spectra of sillimanite, andalusite, and kyanite at various temperatures. Phys Chem Miner. 2020;47(5):1-11.

[31] ³¹
Taylor WH. The structure of andalusite, Al₂SiO₅ Z Kristallogr Cryst Mater. 1929;71:205-18.

[32] ³²
Burnham CW, Buerger MJ. Refinement of the crystal structure of kyanite. Z Kristallogr Cryst Mater. 1961;115:269-90.

[33] ³³
Winter JK, Ghose S. Thermal expansion and high-temperature crystal chemistry of the Al₂SiO₅ polymorphs. Am Mineral. 1979;64:573-86.

[34] ³⁴
Danilo F, Dirk H, Florian A, Christopher P. Andalusite based raw materials for Refractory Castable: properties and application. Paris: Imerys Refractory Minerals; 2018.

[35] ³⁵
Marshall RR. Devitrification of natural glass. Geol Soc Am Bull. 1961;72(10):1493.

[36] ³⁶
Lofgren G. Experimentally produced devitrification textures in natural rhyolitic glass. Geol Soc Am Bull. 1971;82(1):111.

[37] ³⁷
Gimeno D. Devitrification of natural rhyolitic obsidian glasses: petrographic and microstructural study (SEM+EDS) of recent (Lipari island) and ancient (Sarrabus, SE Sardinia) samples. J Non-Cryst Solids. 2003;323:84-90.

Element	Compact (wt%)	Powder (wt%)
O	53.94	59.66
F	2.31	2.58
Na	2.98	2.76
Al	7.08	6.20
Si	30.55	25.36
K	2.56	2.26
Ca	0.21	0.34
Fe	0.36	0.46
Cu	-	0.36
Total	100.00

Peak	Macusanite Inclusion (cm^-1)	Andalusite (cm^-1)²⁰20 Macdonald R, Smith RL, Thomas JE. Chemistry of the subalkalic silicic obsidians. USA: U.S. Geological Survey. 214 p. Professional Paper 1523.
1	146.15	--
2	291.67	~290
3	321.46	~320
4	357.89	~355
5	919.06	~920
6	951.56	~950
7	~1010	~1020
8	1062.08	~1065
9	2129.01	--

Identified Oxides	(wt%)
SiO₂	74.351
Al₂O₃	18.248
K₂O	4.310
Fe₂O₃	1.077
P₂O₅	0.545
CaO	0.511
SO₃	0.364
Rb₂O	0.180
MnO	0.124
TiO₂	0.078
Cs₂O	0.026
As₂O₃	0.049
SnO₂	0.032
ZnO	0.018
Ir₂O₃	0.017
CuO	0.011
WO₃	0.010
Others	0.018