Windmountainite, □Fe3+2Mg2□2Si8O20(OH)2(H2O)4·4H2O, a new modulated, layered Fe3+-Mg-silicate-hydrate from Wind Mountain, New Mexico: Characterization and origin, with comments on the classification of palygorskite-group minerals

IF 1.1 4区地球科学 Q3 MINERALOGY

Canadian Mineralogist Pub Date : 2020-07-01 DOI:10.3749/canmin.1900063

Derek. D. V. Leung, A. McDonald

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引用次数: 3

Abstract

Windmountainite, ideally □Fe3+2Mg2□2Si8O20(OH)2(H2O)4·4H2O, is a new mineral species and member of the palygorskite group discovered as orange-brown, radiating aggregates that commonly fill vesicles (average 1.5 × 2.5 mm) within a phonolite dike at Wind Mountain, Otero County, New Mexico, USA. The mineral develops as tightly bound bundles (up to 0.02 × 6 mm) of acicular to bladed crystals that are elongate on [001] and flattened on the pinacoid {010}. Associated minerals include albite, aegirine, fluorapophyllite-(K), natrolite, neotocite, and montmorillonite, the last of these being observed to replace primary windmountainite. It has a dull luster, silky in aggregates, is translucent and has an orange-brown streak. It does not fluoresce under short-, medium-, or long-wave ultraviolet radiation. Windmountainite is brittle with a splintery fracture and has two good cleavages (predicted) on {110}, an estimated hardness of 2, a calculated density of 2.51 g/cm3, and a calculated navg of 1.593. A total of n = 30 EMPA (WDS) analyses from six grains yielded an average of (wt.%): Na2O 0.08, MgO 3.47, Al2O3 1.15, SiO2 49.76, Cl 0.07, K2O 0.40, CaO 0.68, TiO2 0.30, MnO 5.64, Fe2O3 20.17, H2O (calc.) 16.59, O=Cl –0.02, total 98.29. The empirical formula [based on Σ(T1, T2, M2, M3) = 12 cations pfu, excluding Ca, K, and Na] is: (□0.78Ca0.12K0.08Na0.02)Σ1.00(Fe3+1.93Al0.04Ti0.02)Σ1.99 (Mg0.81Mn2+0.75Fe3+0.44)Σ2.00□2(Si7.81Al0.17Ti0.01Fe3+0.01)Σ8.00O20[(OH)1.98Cl0.02]Σ2.00[(H2O)3.38(OH)0.62]Σ4.00·4H2O, yielding the simplified formula, □Fe3+2Mg2□2Si8O20(OH)2(H2O)4·4H2O. The predominance of Fe3+ is based on color, results from the crystal-structure refinement, the crystal-chemistry of palygorskite-group minerals, the association with Fe3+-dominant minerals, and considerations regarding the late-stage geochemical evolution of agpaitic rocks. The presence of H2O and OH was determined based on results from the refined crystal structure and Fourier-transform infrared spectroscopy. Windmountainite crystallizes in the space group C2/m with a 13.759(3), b 17.911(4), c 5.274(1) Å, β 106.44(3)°, V 1246.6(1) Å3, and Z = 2. The seven strongest powder X-ray diffraction lines are [d in Å (I), (hkl)]: 10.592 (100) (110), 5.453 (16) (130), 4.484 (19) (040), 4.173 (28) , 3.319 (53) (221, 400), 2.652 (30) , 2.530 (27) . The crystal structure was determined from single-crystal X-ray diffraction data and refined to R = 4.01% and wR2 = 10.70% using data from 902 reflections (Fo > 4σFo). It is based on sheets of inverted double chains of SiO4 tetrahedra that sandwich ribbons of Mφ6 octahedra (φ = O, OH, H2O, Cl), giving rise to large channels (∼6.5 × 9 Å) that are occupied by loosely held H2O groups. A modified classification of the palygorskite group [general crystal-chemical formula M1M22M32M42T14T24O20(OH)2(H2O,OH)4·W] is proposed based on the occupants of the four M sites. Within this scheme, windmountainite is the □-Fe3+-Mg-□ member. The palygorskite group includes six members: palygorskite (monoclinic and orthorhombic polytypes), yofortierite, tuperssuatsiaite, raite, windhoekite, and windmountainite. Windmountainite is considered to have formed from late-stage fluids that were alkaline, oxidized, and rich in both Fe3+ and H2O; high aH2O conditions are reflective of abundant, hydrated feldspathoids (natrolite and analcime) forming as primary rock-forming minerals in the phonolite at Wind Mountain.

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Windmountanite，□Fe3+2Mg2□2Si8O20（OH）2（H2O）4·4H2O，一种来自新墨西哥州风山的新型调制层状Fe3+-Mg硅酸盐水合物：表征和起源，并对坡缕石族矿物的分类进行了评述

Windmountanite，理想情况下□Fe3+2Mg2□2Si8O20（OH）2（H2O）4·4H2O是一种新的矿物物种，也是坡缕石群的一员，在美国新墨西哥州奥特罗县Wind Mountain的响岩岩脉中被发现为橙棕色辐射状聚集体，通常填充囊泡（平均1.5×2.5mm）。矿物发育为紧密结合的针状至叶片状晶体束（高达0.02×6mm），在[001]上伸长，在棘突{010}上变平。伴生矿物包括钠长石、赤铁矿、氟质叶绿石-（K）、钠长石、新托西岩和蒙脱石，最后一种被观察到可以取代原生风山岩。它有暗淡的光泽，聚集体丝滑，半透明，有橙棕色条纹。它在短波、中波或长波紫外线辐射下不会发出荧光。Windmountanite是脆性的，带有碎裂的裂缝，在{110}上有两个良好的解理（预测），估计硬度为2，计算密度为2.51g/cm3，计算navg为1.593。从六个晶粒进行的总共n=30次EMPA（WDS）分析得出平均值（wt.%）：Na2O 0.08，MgO 3.47，Al2O3 1.15，SiO2 49.76，Cl 0.07，K2O 0.40，CaO 0.68，TiO2 0.30，MnO 5.64，Fe2O3 20.17，H2O（计算值）16.59，O=Cl–0.02，总计98.29。经验公式[基于∑（T1，T2，M2，M3）=12个阳离子pfu，不包括Ca、K和Na]为：(□0.78Ca0.12K0.08Na0.02）∑1.00（Fe3+1.93Al0.04Ti0.02）∑1.99（Mg0.81Mn2+0.75Fe3+0.44）∑2.00□2（Si7.81Al0.17Ti0.01Fe3+0.01）∑8.00O20[（OH）1.98Cl0.02]∑2.00[（H2O）3.38（OH）0.62]∑4.00·4H2O，得到简化公式，□Fe3+2Mg2□2Si8O20（OH）2（H2O）4·4H2O。Fe3+的优势是基于颜色的，这是由于晶体结构的细化、坡缕石族矿物的晶体化学、与Fe3+优势矿物的结合以及对银铁质岩石后期地球化学演化的考虑。H2O和OH的存在是基于精细晶体结构和傅立叶变换红外光谱的结果来确定的。Windmountanite在空间群C2/m中结晶，具有13.759（3），b 17.911（4），c 5.274（1）Å，β106.44（3）°，V 1246.6（1）å3和Z=2。最强的七条粉末X射线衍射线是[dinÅ（I），（hkl）]:10.592（100）（110），5.453（16）（130），4.484（19）（040），4.173（28），3.319（53）（221400），2.652（30），2.530（27）。晶体结构由单晶X射线衍射数据确定，并使用902次反射（Fo>4σFo）的数据细化为R=4.01%和wR2=10.70%。它基于SiO4四面体的倒双链片，该片夹着Mφ6八面体（φ=O，OH，H2O，Cl）的带，产生由松散的H2O基团占据的大通道（~6.5×9Å）。基于四个M位点的占有者，提出了坡缕石基团的改良分类[晶体化学通式M1M22M32M42T14T24O20（OH）2（H2O，OH）4·W]。在这个方案中，windmountanite是□-Fe3+-Mg-□ 成员坡缕石群包括六个成员：坡缕石（单斜和斜方多型）、云闪长岩、透辉石、白榴石、风辉石和风闪长岩。Windmountanite被认为是由碱性、氧化且富含Fe3+和H2O的晚期流体形成的；高aH2O条件反映了丰富的水合长石（钠长石和方沸石）作为风山响岩中的主要岩石形成矿物而形成。

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来源期刊

Canadian Mineralogist 地学-矿物学

CiteScore

2.20

自引率

22.20%

发文量

审稿时长

4-8 weeks

期刊介绍： Since 1962, The Canadian Mineralogist has published papers dealing with all aspects of mineralogy, crystallography, petrology, economic geology, geochemistry, and applied mineralogy.