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Augite

Augite is a common rock-forming belonging to the group, specifically classified as a clinopyroxene, and serves as an intermediate member in the series between and hedenbergite. It has a complex chemical composition represented by the formula (Ca,Na)(Mg,Fe,Al)(Si,Al)₂O₆, which allows for significant variations due to substitutions of calcium, sodium, magnesium, iron, and aluminum. Augite typically forms short, thick prismatic crystals in the , exhibiting a vitreous luster and colors ranging from dark green and brown to black. With a Mohs of 5.5 to 6 and distinct in two directions nearly at right angles, it is a key component in and ultramafic igneous rocks, as well as certain high-grade metamorphic rocks. A common rock-forming , particularly in and ultramafic rocks, augite is primarily encountered in formations such as , , , , and ultramafics, where it contributes to the dark coloration and character of these lithologies. It also appears in granulites and other high-grade metamorphic rocks, and has been identified in lunar basalts and stony meteorites, underscoring its role in understanding extraterrestrial . The mineral's compositional variability reflects processes and metamorphic conditions, making it valuable for analysis to infer temperature and pressure histories of rock formation. Despite its prevalence, augite lacks significant commercial applications and is mainly studied for its geological and significance.

Etymology and History

Naming Origin

The name "augite" derives from the ancient Greek word augitēs (αὐγίτης), meaning "" or "luster," a term Werner applied to highlight the reflective sheen on the cleavage surfaces of exceptional specimens. German mineralogist coined the name in 1792 during his systematic classification efforts at the Mining Academy. In the late , mineralogical naming conventions emphasized descriptive terms rooted in classical and Latin to capture physical traits, reflecting the era's shift toward empirical taxonomy amid debates like Werner's , which posited aqueous origins for rocks and advocated orderly for minerals. Werner's approach, influential in establishing modern , prioritized observable characteristics such as luster over chemical analysis, which was then rudimentary. The term's evolution traces from ancient Greek references to bright, lustrous stones—evident in classical texts describing similar vitreous materials—to its formal adoption in 20th-century standards. The International Mineralogical Association (IMA), through its Commission on New Minerals and Mineral Names, has retained "augite" as the approved name for the monoclinic clinopyroxene with compositions generally intermediate in the diopside-hedenbergite series and the (Ca,Na)(Mg,Fe,Al,Ti)(Si,Al)₂O₆ since the 1978 nomenclature report, ensuring consistency in global mineral classification. This standardization underscores augite's role as a key rock-forming while preserving Werner's etymological intent tied to its occasional pearly luster.

Discovery and Early Studies

Augite was identified and named in 1792 by , a prominent German and mineralogist at the Bergakademie Freiberg in , during his examinations of basaltic rocks in the region. Werner's work focused on the constituents of these rocks, recognizing augite as a distinct based on its physical characteristics, particularly the luster of its cleavage surfaces. This discovery occurred amid broader investigations into the origins of formations in , where Werner documented augite's presence in columnar and layered structures. In the early 19th century, further analyses by leading mineralogists solidified augite's position within the group. René Just Haüy, the founder of modern crystallography, incorporated augite into his classification of pyroxenes in 1796, emphasizing its prismatic cleavage and monoclinic crystal form as key diagnostic features. These observations built on Werner's initial description, using geometric and to distinguish augite from related silicates. British mineralogist Henry James Brooke contributed to these efforts through detailed crystallographic studies in the , confirming the mineral's structural consistency via measurements of cleavage angles and crystal habits. Augite played a significant role in Werner's Neptunist theory, which posited that all rocks, including basalts, formed through precipitation from a primordial ocean rather than volcanic processes. Werner interpreted the presence of augite in basaltic rocks as supporting evidence for their aqueous deposition, viewing the mineral's crystalline forms as products of slow crystallization in water. This perspective contrasted sharply with the Plutonist arguments advanced by contemporaries like and the Scottish school, who emphasized igneous origins for such rocks based on field evidence of lava flows and intrusions. The debate over augite-bearing basalts highlighted early tensions in geological interpretation, influencing subsequent stratigraphic and petrologic studies.

Chemical Composition

Ideal Formula

The ideal formula of augite, a calcium-rich clinopyroxene mineral in the group, is (\ce{(Ca,Na)(Mg,Fe,Al,Ti)(Si,Al)2O6}). This representation captures the essential of the mineral as a single-chain , where the consists of two tetrahedral sites, one octahedral M1 site, one larger M2 site, and six oxygen atoms forming the characteristic pyroxene chain structure. In this formula, cations occupy specific structural sites to maintain the monoclinic symmetry of augite. The M2 site, a distorted coordinated by six to eight oxygens, is dominated by the larger \ce{Ca^{2+}} and \ce{Na^{+}} cations, while the smaller, more regular M1 octahedral site is filled primarily by \ce{Mg^{2+}}, \ce{Fe^{2+}/^{3+}}, \ce{Al^{3+}}, and \ce{Ti^{4+}}. The tetrahedral (T) sites house \ce{Si^{4+}} and minor \ce{Al^{3+}}, linking into infinite single chains parallel to the crystal's c-axis. The stoichiometric arrangement ensures overall charge balance in the pyroxene structure, with the total cationic charge of +12 neutralizing the -12 from the six \ce{O^{2-}} anions per formula unit. In the simplest end-member like diopside (\ce{CaMgSi2O6}), divalent cations in M1 and M2 paired with tetravalent silicon achieve perfect neutrality; however, the inclusion of trivalent or tetravalent cations such as \ce{Al^{3+}} in tetrahedral or M1 sites requires coupled heterovalent substitutions (e.g., \ce{Na^{+}} for \ce{Ca^{2+}} or \ce{Fe^{3+}} for \ce{Mg^{2+}}) to preserve electroneutrality across the structure.

Substitutions and Variations

Augite displays significant compositional variability through series, primarily with (CaMgSi₂O₆) and hedenbergite (CaFeSi₂O₆) as end-members, forming a continuous series within the quadrilateral in Ca-Mg-Fe-Si space. This quadrilateral encompasses high-calcium clinopyroxenes like augite alongside low-calcium phases such as pigeonite and orthopyroxene, with augite occupying the Ca-rich region characterized by high Ca contents (typically 40-50 mol% component). Common cation substitutions in augite include Al³⁺ replacing Si⁴⁺ in tetrahedral (T) sites, Na⁺ substituting for Ca²⁺ in the larger M2 octahedral sites, and Ti⁴⁺ or Al³⁺ replacing Mg²⁺ or Fe²⁺ in the smaller octahedral sites, often coupled to preserve charge balance via mechanisms like the Tschermak exchange (Al³⁺_T + Al³⁺_M1 ⇌ Si⁴⁺_T + Mg²⁺_M1). These substitutions extend the stability field of augite but are constrained by gaps, notably a persistent gap with pigeonite at 15-25 % Wo that widens at lower temperatures, and broader immiscibility with orthopyroxene at Wo contents below about 5 %. The Ca content in augite, expressed as the ratio Ca/(Ca + Mg + Fe²⁺), varies systematically with and , decreasing at higher pressures for a given temperature due to partitioning effects in coexisting assemblages. This sensitivity underpins geothermobarometric applications, where the Ca distribution between augite and low-Ca pyroxenes like pigeonite provides estimates of equilibration conditions in igneous and metamorphic rocks, with calibrations valid over 800-1200°C and pressures up to 15 kbar.

Crystal Structure

Unit Cell and Symmetry

Augite crystallizes in the with C2/c (equivalent to B2/b in some settings). This symmetry reflects the mineral's characteristic asymmetry along one axis, consistent with its pyroxene group affiliation. The contains Z=4 formula units and has approximate dimensions of a ≈ 9.7 , b ≈ 8.8 , c ≈ 5.3 , and β ≈ 107°. In its crystalline form, augite typically exhibits a or tabular , often appearing as stubby prisms elongate along the c-axis. The most commonly developed crystal forms are the prism {110} and the pinacoid {100}, which contribute to its square or octagonal cross-sections in basal views. The unit cell parameters of augite show measurable variations primarily due to substitutions in the Fe-Mg series, where increasing Fe content leads to slight expansions in cell volume and specific lattice parameters like b. These compositional effects can be quantified through diffraction , allowing for geothermometric and petrogenetic inferences based on refined cell metrics.

Chain Structure

Augite exhibits a single-chain inosilicate structure, characteristic of the pyroxene group, consisting of infinite chains of silica tetrahedra with the repeating unit (\mathrm{Si,Al})_2\mathrm{O}_6. These chains run parallel to the c-axis and are cross-linked by metal cations occupying two distinct sites: the M1 site, which forms regular octahedra coordinated by six oxygen atoms and is primarily occupied by smaller cations such as Mg, Fe²⁺, Al, or Ti; and the M2 site, a more distorted octahedron also coordinated by six oxygens but accommodating larger cations like Ca and Na. The overall arrangement is encapsulated within a monoclinic unit cell, providing the framework for the mineral's lattice geometry. In some augite specimens, particularly those from rapidly cooled igneous environments, an -like sectoral is observed due to exsolution processes during . This arises from compositional variations between alternating sectors, where Ca-rich domains exhibit exsolved augite lamellae and Fe-rich domains show distinct lamellae orientations, creating a visually symmetric, pattern visible under or in polished sections. The chains are bonded laterally to the and polyhedra through shared oxygen atoms, which are the bridging oxygens between adjacent tetrahedra within the chain and the apical oxygens linking to the octahedra. This bonding configuration results in planes of weakness parallel to {110}, manifesting as two prominent directions intersecting at angles of approximately 87° and 93°.

Physical and Optical Properties

Mechanical Properties

Augite exhibits a Mohs hardness of 5.5 to 6, making it moderately resistant to scratching compared to common minerals like apatite and feldspar. Its specific gravity ranges from 3.2 to 3.6, reflecting its dense composition dominated by calcium, magnesium, iron, and silicon oxides. The mineral displays a vitreous to dull luster, which can appear glassy in fresh surfaces but may dull upon weathering. It produces a greenish-white streak when rubbed on an unglazed porcelain plate. In hand specimens, augite typically appears dark green to black, with color variations largely influenced by its iron content; higher iron concentrations result in darker shades. This coloration arises from the substitution of iron for magnesium in its , affecting both the overall hue and opacity. Augite features perfect in two directions, nearly at right angles, specifically at 87° and 93°, due to weaknesses in its single-chain structure where octahedral chains break along the {110} planes. This prismatic produces blocky fragments with nearly square cross-sections, distinguishing it macroscopically from other .

Optical Characteristics

Augite is optically biaxial positive, characterized by refractive indices of nα = 1.680–1.735, nβ = 1.684–1.741, and nγ = 1.706–1.774. Its ranges from δ = 0.026–0.039, producing low to moderate second- and third-order interference colors in thin sections under crossed polars. These properties result from the mineral's monoclinic and single-chain structure, which influence light propagation through the crystal lattice. The optic axial angle, denoted as 2V, typically measures 45–65°, with the acute bisectrix aligned approximately parallel to the b crystallographic axis. Augite displays weak under polarized light, exhibiting variations in green to brown hues, such as pale green (X), pale brownish green (Y), and greenish yellow (Z), though this effect is often subtle or masked in darker varieties. is weak to moderate, with r > v. In petrographic thin sections, augite shows high positive due to its refractive indices exceeding those of common mounting like (n ≈ 1.54), making it stand out distinctly against surrounding . This high , combined with its optical characteristics, facilitates identification of augite as a key in igneous and metamorphic rocks during microscopic analysis. Compositional variations, such as substitutions in the section, can slightly alter these indices, with iron-rich augites tending toward higher values.

Occurrence and Formation

In Igneous Rocks

Augite serves as a primary constituent in and ultramafic igneous rocks, including , , and , where it forms through the of mafic magmas under high-temperature conditions typically ranging from 1000°C to 1200°C. In these environments, augite crystallizes early in the magmatic sequence, often as blocky or prismatic crystals that contribute to the dark color and dense texture of the resulting rocks. Its presence is particularly prominent in intrusive equivalents like and extrusive forms like , reflecting the mineral's stability in iron- and magnesium-rich melts derived from sources. In these rocks, augite commonly associates with , calcic , and , forming interlocking crystal frameworks that record the progressive cooling of the . During slow cooling, augite may develop exsolution textures, such as fine lamellae of orthopyroxene or pigeonite within its structure, which provide insights into the thermal history and indicate subsolidus re-equilibration below approximately 1000°C. These textures are observable in thin sections and highlight augite's role in capturing the dynamic evolution of igneous systems. Augite also occurs in extraterrestrial igneous contexts, notably in lunar basalts and Martian meteorites such as the nakhlites, underscoring its significance in understanding off-Earth magmatic processes. In lunar mare basalts, augite appears alongside and in vitrophyric textures, formed from basaltic magmas similar to terrestrial counterparts but influenced by the Moon's reduced conditions. The nakhlites, augite-rich basaltic rocks from Mars, contain abundant augite phenocrysts that crystallized from mantle-derived melts approximately 1.3 billion years ago, offering evidence of volcanic activity on the Martian surface.

In Metamorphic Rocks

Augite forms during high-grade of mafic protoliths, such as basalts or gabbros, under temperature conditions ranging from 600 to 1000°C and pressures of 5 to 15 kbar, typical of granulite- settings. In these environments, augite recrystallizes from primary igneous pyroxenes or forms through reactions involving , , and fluids, contributing to the coarse-grained textures of rocks like granulites and eclogites. In regional and contact metamorphism of rocks, augite is stable and commonly associated with (such as ) and , forming assemblages that indicate equilibration at upper - to granulite-facies conditions. For instance, in metamorphosed basalts, augite persists or nucleates alongside these minerals during prograde heating and burial, reflecting the mineral's resilience in Ca- and Mg-rich compositions under elevated temperatures around 700-900°C and pressures of 6-8 kbar. Augite also appears in metamorphosed iron formations and deposits, where it signals calc-silicate environments dominated by metasomatic fluid-rock interactions. In these settings, often linked to contact metamorphism near intrusions, augite grows in association with , , and other calc-silicates, incorporating iron from the host rocks to form Fe-rich varieties under temperatures exceeding 600°C and variable pressures.

Identification

Diagnostic Features

In hand samples, augite is recognized by its dark green to black color and stubby prismatic . It displays two prominent s intersecting at approximately 90 degrees, which are fair to good in quality. The has a Mohs of 5 to 6, allowing it to be scratched by a knife blade. Under the in thin section, augite exhibits high positive relief and distinct traces at nearly 90 degrees. It appears pale green to brownish green or colorless, often with , and shows weak in plane-polarized light. Under crossed polars, the displays inclined and moderate , contributing to its identification. Chemical confirmation of augite involves detecting calcium, magnesium, and iron through methods such as spot tests or energy-dispersive X-ray spectroscopy (EDS). Unlike reactive minerals, augite shows no effervescence or dissolution when exposed to dilute hydrochloric acid (HCl).

Distinction from Similar Minerals

Augite is distinguished from diopside primarily by its higher content of iron, aluminum, and titanium, which imparts a darker green to black color and higher refractive index, resulting in greater relief in thin section compared to the lighter green or colorless appearance of diopside. Additionally, augite typically exhibits a 2V angle of 45-65°, while diopside shows a slightly higher 2V often exceeding 50° along with greater birefringence. In contrast to pigeonite, augite contains higher calcium (20-45 mol% vs. 5-20 mol% in pigeonite), leading to a larger of 45-65° compared to pigeonite's low 2V of 0-30°. Structurally, augite belongs to the , whereas pigeonite is P2₁/c, contributing to these optical differences observable under the . Augite can be differentiated from by its nearly 90° cleavage angles and stubby prismatic habit, lacking the amphibole's characteristic 56-124° cleavage and elongate prisms. Optically, augite displays inclined up to 45° and a consistent 2V around 60°, while shows parallel extinction and a broader 2V range of 0-80° with stronger .

Geological Significance

Role in Rock Classification

Augite plays a pivotal role in the classification of igneous rocks, particularly as an indicator of composition in plutonic varieties. In the , developed by the for , augite contributes to the mafic mineral fraction that positions rocks within the gabbroic field when combined with dominant , distinguishing them from , which features lower mafic content (typically less than 35-50% mafics) and more or alongside plagioclase. The relative abundance of augite versus other mafics thus helps delineate from , reflecting silica contents of 45-52% in gabbro versus 52-63% in diorite, and underscoring augite's prevalence in lower-crustal mafic intrusions. In , augite functions as a geothermometer through analysis of its / and content, which record mineral-melt equilibria during . These compositional parameters, calibrated via experimental on basaltic systems, enable of temperatures, such as approximately 1100°C for augite in high-alumina basalts under moderate (2-3 wt%) and pressures up to 7 kbar. This approach, integrated into models like COMAGMAT, provides accuracy within ±10-15°C for paths in magmas. Exsolution lamellae of augite in pigeonite or orthopyroxene hosts further reveal cooling rates in volcanic and subvolcanic histories, acting as geospeedometers for thermal evolution. Experimental calibrations show that lamellae thickness and orientation develop during subsolidus cooling, with slow rates (e.g., 0.5°C/hr) promoting augite formation at around 1100°C and growth to 1040°C, while faster rates suppress distinct exsolution patterns. These features thus constrain the post-crystallization cooling trajectories of rocks like basalts.

Applications and Uses

Augite has no significant industrial or economic applications, primarily because it is an abundant rock-forming associated with common and ultramafic rocks like and , which generally lack commercial value. Its presence in these low-value materials precludes extraction for widespread use, though it occasionally contributes indirectly to minor . In the ceramics sector, augite plays a limited role as a flux component derived from basalt quarry residues, where it aids in the formation of glass-ceramics through crystallization during sintering at temperatures around 900–1100°C. These materials exhibit properties suitable for applications such as architectural tiles or refractory components, leveraging the mineral's silicate composition to lower melting points and enhance durability. Beyond industry, augite holds value in scientific research, particularly in . It is a dominant in nakhlite meteorites, augite-rich igneous rocks ejected from Mars, providing insights into the planet's volcanic history and composition through analysis of its chemical signatures. , gem-quality augite crystals, often displaying vitreous luster and colors from to black, are collected by enthusiasts for their aesthetic appeal, though they are not commercially faceted as gemstones. Additionally, augite's compositional variations enable its use in geobarometry, allowing researchers to estimate pressure-temperature conditions in mantle-derived rocks without commercial implications.

References

  1. [1]
    Augite - Smith College
    Petrographic Data File. Augite is a clinopyroxene, part of a solid solution series. It is an intermediate member of diopside and hedenbergite. Vitreous, ...
  2. [2]
    Augite: A rock-forming mineral found throughout the world
    Augite is a common rock-forming mineral found in dark-colored igneous rocks, in some metamorphic rocks and in some meteorites.
  3. [3]
    Augite: Mineral information, data and localities.
    Geological Setting: Major rock forming mineral in mafic igneous rocks, ultramafic rocks, and some high-grade metamorphic rocks.Augite porphyry · Augite monzonite · Transitional basalt · Fourchite
  4. [4]
    CLAS: Colby Liberal Arts Symposium: Augite
    Augite was discovered in 1792 by Abraham Gotlobb Werner, a German geologist ... The name augite originates from the Greek word auge or augites meaning ...
  5. [5]
    Nomenclature of Pyroxenes | Mineralogy and Petrology
    This is the final report on the nomenclature of pyroxenes by the Subcommittee on Pyroxenes established by the Commission on New Minerals and Mineral Names.
  6. [6]
    35. Werner and the Aqueous Origin of Basalt, 1789 - Linda Hall Library
    Werner was a neptunist, meaning he believed that all of the earth's rocks were deposited from water. This included basalt.Missing: theory augite
  7. [7]
    Pyroxene Group: Mineral information, data and localities.
    Named in 1796 by René Just Haüy from the Greek words for fire (πυρ) and stranger (ξένος). Pyroxene was named because of its presence in a glassy or vitreous ...
  8. [8]
    Neptunism | The Foundation of Modern Geology - Publish
    Neptunism was a theory stating that the majority of the rocks that comprise earth's surface were once precipitated out of a vast ocean. Abraham Werner.Missing: augite | Show results with:augite
  9. [9]
    Augite Mineral Data - Mineralogy Database
    Physical Properties of Augite, Optical Properties of Augite, Calculated Properties of Augite, Augite Classification, Other Augite Information
  10. [10]
    [PDF] Augite (Ca,Na)(Mg,Fe,Al,Ti)(Si,Al)2O6
    ○2001 Mineral Data Publishing, version 1.2. Crystal Data: Monoclinic. Point Group: 2/m. Stubby prismatic crystals, square or octagonal in section, to 10 cm; ...Missing: Henry | Show results with:Henry<|separator|>
  11. [11]
    https://rruff.geo.arizona.edu/doclib/hom/augite.pdf
  12. [12]
    [PDF] Structural and chemical variations in pyroxenes - RRuff
    The M2 site is irregularly coordinated by six, seven, or eight oxygens. The M2 coordination depends upon the size of the cation occupying the site: higher ...
  13. [13]
    6.4.7: Pyroxenes - Geosciences LibreTexts
    Dec 16, 2022 · We generally use six to keep formulas consistent with other pyroxenes such as diopside and hedenbergite and also because Ca, Fe, and Mg occupy ...
  14. [14]
    Inosilicates (Pyroxenes and Amphiboles) - Tulane University
    Nov 14, 2011 · Augite is closely related to the diopside - Hedenbergite series with addition of Al and minor Na substitution - (Ca,Na)(Mg,Fe,Al)(Si,Al)2O6.
  15. [15]
    [PDF] Nomenclature of pyroxenes - RRuff
    Throughout this report, the standard pyroxene formula isused with superscripted Arabic numerals. (e.g. Fe2+) referring to charges, and subscripted numerals ( ...
  16. [16]
    A two‐pyroxene thermometer - Lindsley - 1983 - AGU Journals - Wiley
    Feb 10, 1983 · The thermometer can be used directly with natural pyroxenes that have low contents of Al and other minor components. Samples with higher ...
  17. [17]
    A Two-Pyroxene Thermometer - NASA ADS
    11794 The CaSIO3 contents of coexisting high-Ca and low-Ca pyroxenes have long been recognized as potential geothermometers for lunar and terrestrial rocks.
  18. [18]
    [PDF] Augite from Nishigatake, Japan. - RRuff
    Crystallography. The forms observed are .(100), b(010), c(001), m(ll0), o( ...
  19. [19]
    The role of Fe content on the Fe-Mg exchange reaction in augite
    Dec 1, 2016 · Table 1 shows the unit-cell parameters, obtained by a least-squares procedure to refine the position of about 7000 reflections in the 6–110 ...
  20. [20]
    [PDF] Mg Content (apfu) Unit-Cell Volume (Å3) Olivine
    Augite and pigeonite were constrained to the Ca-. Fe-Mg system. ... Variation of Mg-content with b unit-cell parameter in augite obtained from literature data.
  21. [21]
    ALEX STREKEISEN-Pyroxene-
    The M1 sites are occupied by smaller cations such as magnesium, iron, aluminum, and manganese, which are coordinated to six oxygen atoms to form a regular ...
  22. [22]
    Hourglass structure in augite - Mineralogical Society of America
    A more obscure hourglass structure, defined by composition and exsolution features, characterizes a common augite from a dolerite pegmatite.
  23. [23]
    An unusual hourglass structure in augite | American Mineralogist
    Jul 6, 2018 · A more obscure hourglass structure, defined by composition and exsolution features, characterizes a common augite from a dolerite pegmatite.
  24. [24]
    Augite - Geology - rocks and minerals - University of Auckland
    Augite is commonly found in igneous rocks such as gabbros, basalts and andesites, and high grade metamorphic rocks (granulites).<|control11|><|separator|>
  25. [25]
    Pyroxene - Common Minerals
    Pyroxene is a group of silicate minerals, usually dark green, brown, or black, with a hardness of 5-6, and two cleavage directions. They are harder than glass.
  26. [26]
    4 Pyroxenes and Pyroxenoids - Optical Mineralogy
    Occurrence—Diopside-hedenbergite is a Fe-Mg solid solution series of Ca-rich clinopyroxenes. Minerals of this series are similar to augite but contain Ca:(Fe+ ...Missing: substitutions | Show results with:substitutions
  27. [27]
    6 Igneous Rocks and Silicate Minerals – Mineralogy - OpenGeology
    For example, basalt and gabbro contain more iron and magnesium than andesite and diorite, and andesite and diorite contain more iron and magnesium than rhyolite ...
  28. [28]
    RESULTS
    Similarly, plagioclase appears at 1177ºC with an uncertainty of ± 5ºC, and augite appears at 1167 ± 5ºC. Thus, the melt under equilibrium conditions is multiply ...
  29. [29]
    [PDF] AUGITE - A. E. Seaman Mineral Museum
    Augite is a common and widespread rock-forming mineral, chiefly in ultramafic, mafic, and intermediate igneous rocks, both intrusive and extrusive.<|separator|>
  30. [30]
    ALEX STREKEISEN-Olivine-
    Olivine is typically associated with calcic plagioclase, magnesium-rich pyroxenes, and iron-titanium oxides such as magnetite and ilmenite. This mineralogical ...
  31. [31]
    Exsolution lamellae in Pyroxene - ALEX STREKEISEN
    Exsolution lamellae in pyroxene are thin, oriented intergrowths formed when a solid solution unmixes during slow cooling, often planar and crystallographically ...
  32. [32]
    Pyroxene exsolution; an indicator of high-pressure igneous ...
    Mar 2, 2017 · The exsolution history of these pyroxenes consists of (1) crystallization of high-temperature augite or pigeonite, (2) exsolution of coarse “001 ...
  33. [33]
    [PDF] An Apollo 15 mare basalt fragment and lunar mare provinces
    Most mineral grains are anhedral and < 10/tm across, but a variolitic or radial texture is partly developed by continuity or elongation of the augite. The ...<|separator|>
  34. [34]
    An Apollo 15 Mare Basalt Fragment and Lunar Mare Provinces
    Jan 1, 1996 · Lunar sample 15474,4 is a tiny fragment of olivine-augite vitrophyre that is a mare basalt. Although petroraphically distinct from all other ...
  35. [35]
    Most Nakhlite Martian Meteorites Were Magmas, not Crystal ...
    Oct 22, 2025 · The nakhlite martian meteorites, basaltic rocks with abundant crystals of augite pyroxene, have been interpreted as cumulates – formed as ...
  36. [36]
    Metamorphic Rocks- Classification, Field Gradients, & Facies
    Mar 31, 2004 · Eclogites: These are medium to coarse grained consisting mostly of garnet and green clinopyroxene called omphacite, that result from high grade ...
  37. [37]
    Metamorphic evolution of high-pressure and ultrahigh-temperature ...
    Dec 21, 2023 · ... augite, and melt (Green et al., 2016); ternary feldspars ... granulite-facies metamorphism—Implications for the Sm-Nd closure temperature.
  38. [38]
    [PDF] 17. Petrology of Metamorphic Rocks Associated with Volcanogenic ...
    augite, hornblende, garnet,. Al-spinel. Quartz, plagioclase, orthoclase ... and granulite-facies conditions (Morton and Franklin, 1987;. Bonnet and ...
  39. [39]
    https://www2.tulane.edu/~sanelson/eens212/metaclassification&facies.htm
  40. [40]
    [PDF] MINOR ELETYIENT DISTRIBUTION IN SOME METAMORPHIC ...
    Pyroxene, usually augite or diopside, occurs in all five of the difierent skarn types, in the marbles and amphibolites of the series and in the hybrid igneous ...
  41. [41]
    [PDF] Mineral resource assessment map for skarn deposits of gold, silver ...
    endoskarn, which consists of tremolite-actinolite, augite, calcite, quartz ... calc-silicate minerals of skarn zones. In the Butte quadran- gle, the ...
  42. [42]
    Calcic Clinopyroxene
    Important properties: ·Color - Common augite is generally light green; Fe-free clinopyroxene such as diopside may be clear; other varieties may be light brown ...
  43. [43]
    Silicates - Augite - Lucid key
    Does not react with hydrochloric acid (HCl). Occurrence: Pyroxenes including augite occur in medium and high grade metamorphic rocks, many igneous rocks and ...
  44. [44]
    Pyroxene - Geology is the Way
    Pyroxenes are a group of chain silicates that occur as fundamental Mg, Fe, Ca, and Na-bearing minerals in many igneous and metamorphic rocks.
  45. [45]
    [PDF] Nomenclature of pyroxenes - Mineralogical Society of America
    There is a miscibility gap between augite and pigeonite, and many pyroxenes with I 5-250/o Wo have proved to be mixtures of the two. Augite with less than ...
  46. [46]
    [PDF] full-text PDF - Alaska Volcano Observatory
    The augite is light green in color, and at first glance might readily be mistaken for a green variety of hornblende. Its cleavage and optical properties are, ...
  47. [47]
    Gabbro: A Coarse-Grained Mafic Intrusive Rock - Sandatlas
    Feb 28, 2012 · Gabbro (red) shown on the QAPF diagram, which is used to classify most plutonic igneous rocks. Gabbro in the broader sense (yellow) includes ...
  48. [48]
    Gabbro - Geology is the Way
    Gabbro Plutonic igneous rock. Felsic minerals: • Ca-plagioclase. Mafic minerals: • pyroxene • olivine · QAPF classification: Q = 0 – 5% Plagioclase/feldspars ...
  49. [49]
    [PDF] COMAGMAT: Development of a Magma Crystallization Model and ...
    (i = Na, Ca, Al, Si) were calculated and a dependence of on 1/T was derived ... A. A. Ariskin, G. S. Barmina, S. S. Meshalkin, et al.,. “INFOREX-3.0: A ...
  50. [50]
    Geothermobarometry of basaltic glasses from the Tamu Massif ...
    Jul 31, 2013 · The internal standards were albite for Na, wollastonite for Si and Ca, Al ... augite geothermometer described in Ariskin and Barmina [2004]).
  51. [51]
    https://geologyistheway.com/igneous/classification-of-gabbroic-rocks/gabbro/
  52. [52]
    Augite Mineral Physical - Optical Properties, Uses and Occurrence
    Mar 15, 2019 · Most augite has a dull, dark green, brown, or black finish. Augite occurs chiefly as short, thick, prismatic crystals with a square or octagonal ...
  53. [53]
    (PDF) Augite-anorthite glass-ceramics from residues of basalt quarry ...
    Aug 9, 2025 · Glass-ceramic containing augite and anorthite was prepared using ceramic wastes and residue of basalt quarry [11] . ... Manufacture of low ...
  54. [54]
    Basaltic glass-ceramic: A short review - ScienceDirect.com
    Some studies have presented the possibility of using basalt glass-ceramics ... Augite-anorthite glass-ceramics from residues of basalt quarry and ceramic wastes.
  55. [55]
    What Martian Meteorites Reveal About the Interior and Surface of Mars
    Nov 20, 2020 · Scientists learn about the formation and evolution of planets, such as Mars, by studying rock samples. ... The nakhlite meteorites: Augite-rich ...
  56. [56]
    Augite gemstone information - Gemdat.org
    Augite forms glassy crystals ranging in colour from purple and brown to black. ... This table shows the variety of hues this gemstone can be found in.
  57. [57]
    A precise olivine-augite Mg-Fe-exchange geothermometer
    These results encourage confidence in the olivine-augite geothermometer over at least the 800–1250°C interval at low pressures.