Journal/NDM40 2005 eng

The volume 40 includes articles on new mineral species, among which chukhrovite(Nd), tsepiniteSr, senkevichite, and kyrgyzstanite are described. The new data on rare minerals calcurmolite and turanite, easily oxidizable chalcopyrite from black smokers of the Rainbow hydrothermal field (MidAtlantic Ridge), vanadium hematite associated with minerals of precious metals, copper, zinc, and iron is given; also there is data on fahlores from the Kvartsitovye Gorki deposit and the nickelinebreithauptite mineral series from the Norilsk ore field. Features of bismuth mineralization of the Djimidon deposit (North Osetia) and raremetal mineralization connected with bituminous matters from pegmatites of the Khibiny and Lovozero massifs are revealed. The results of study of metacolloidal gold and delhayelite crystals are published.
In the «Mineralogical Museums and collections» part, the minerals named in honour of collaborators of the Fersman Mineralogical Museum, specimens of platinum of the Ugolnyi stream (Norilsk) from the Museum collection are described; interesting historical data on the items of Decorative and Precious Stones collection (PDK) is given. «Mineralogical Notes» part includes the mineralogical summary of main mineral types of ores of Europe and the article devoted to mineral drawings of Victor Slyotov and Vladimir Makarenko. In new «Discussions» part, the polemics on the theme «What are the mineral and mineral species» is opened. The review of new books is published.
The volume is of interest for mineralogists, geochemists, geologists, and also collaborators of naturalhistorical museums, collectors and amateur of minerals.

• Editor in Chief Margarita I .Novgorodova, Doctor in Science, Professor
• Editor in Chief of the volume: Elena A.Borisova, Ph.D
• Moisei D. Dorfman, Doctor in Science
• Svetlana N. Nenasheva, Ph.D
• Marianna B. Chistyakova, Ph.D
• Elena N. Matvienko, Ph.D
• Мichael Е. Generalov, Ph.D
• N.A.Sokolova Secretary
• Translator: Yiulia Belovistkaya

• Photo: Michael B. Leybov, Michael E. Generalov
• Leader of publishing group Michael B. Leibov
• Executive Editor Ludmila А. Cheshko
• Art Director Nikolay О. Parlashkevich
• Editor Ekaterina V. Yakunina
• Design (idea) Dmitrii Ershov
• Layout Elena Yurlova

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© Text, photo, drawings, Fersman Mineralogical Museum Russian Academy of Science, 2005
© Design, Ocean Pictures, 2005
Authorized for printing by the Fersman Mineralogical Museum of Russian Academy of Science
Text, photos, drawings, Fersman Mineralogical Museum of Russian Academy of Science, 2007
Design AlLTUM Ltd, 2007
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In specimens from the oxidized zone of the KaraOba deposit (Central Kazakhstan), a new neodymiumdominant analogue of chukhrovite(Y) and chukhrovite(Ce) has been found; it has been named chukhrovite(Nd). The new mineral occurs in the form of isometric grains and small crystals represented by a combination of {100} and {111} faces, with sizes ranging from 0.05 to 0.4 mm; it forms zones within the larger crystals of chukhrovite(Y) also. Chukhrovite(Nd) is associated with quartz, fluorite, halloysite, chukhrovite(Y), anglesite, gearksutite, creedite, and the jarosite group minerals. The mineral is colourless, rarely white. Streak is white. Hardness is 3.54 on Mohs' scale. Density (meas.) is 2.42(3) g/cm³, density (calc.) is 2.42 g/cm³. The mineral is transparent, and in thin sections it has anomalous grey interference colours, n=1.443(2) (589 nm). Chemical composition (electron microprobe instrument, wt %) is following: CaO – 20.03; Y₂O₃ – 1.94, La₂O₃ – 2.32; Ce₂O₃ – 1.37; Pr₂O₃ – 1.37; Nd₂O₃ – 6.26; Sm₂O₃ – 1.90; Gd₂O₃ – 1.12; Dy₂O₃– 0.44; Ho₂O₃– 0.10; Al₂O₃– 12.09; SO₃– 9.38; F – 28.93; H2O (by difference) – 24.93, less O=F 12.18, total 100.00 wt%.Empirical formula is Ca_3.06(Nd_0.32Y_0.15La_0.12Sm_0.09Ce_0.07Pr_0.07Gd_0.05Dy_0.02Ho_0.01)_0.90 Al_2.03S_1.01O_3.96F_13.06·11.87H₂O. Ideal formula is Ca₃(Nd,Y)Al₂(SO₄)F₁₃·12H₂O. Cubic, space group Fd3, a=16.759(3) Å, V=4707.0(1) ų, Z=8. Strong lines of Xray pouder pattern are following (dI(hkl)): 9.710(111); 5.927(220); 3.22-8(511); 2.555-7(533); 2.240-5(642); 2.180-6(731); 1.827-5(842). The IR spectrum is as follows: 3548, 3423, 1630, 1090, 586, 465 cm^-1. The type specimen of the new mineral is at the Fersman Mineralogical Museum, RAS (Moscow). читать далее...

TsepiniteSr is a new mineral of the labuntsovite group (the vuoriyarvite subgroup); it is an analogue of tsepinite-Na, tsepiniteK, and tsepinite-Ca, with predominance of Sr among the extraframework cations. Tsepinite-Sr has been found in hydrothermal paragenesis in cavities of nepheline-syenite pegmatite at the Mt. Eveslogchorr in the Khibiny massif, Kola Peninsula, Russia. It is associated with microcline, albite, natrolite, analcime, aegirine, eudialyte, leifite, vuoriyarviteK, tsepiniteCa, kuzmenkoite-Zn, paratsepinite-Ba, takanelite, etc. The mineral forms coarseprismatic crystals up to 0.2 x 0.4 x 2 mm in size and crusts up to 4 x 5 mm. It is translucent, colourless or white; the streak is white, and the lustre is vitreous. The mineral is brittle, without cleavage; the fracture is uneven. The Mohs' hardness is ~5. The measured density is 2.67(2), and the calculated density is 2.63 g/cm³ . The mineral is optically biaxial, positive; N_p=1.649(2), N_m=1.651(2), N_g=1.770(4); 2V_meas=20(5)°, 2V_calc=16°. Chemical composition is as follows (the electron microprobe data, H₂O by TGA, wt %): Na₂O 0.61, K₂O 1.30, CaO 0.92, SrO 5.12, BaO 4.27, MgO 0.01, MnO 0.05, FeO 0.08, ZnO 0.26, Al₂O₃ 0.18, SiO₂ 41.89, TiO₂ 18.49, Nb₂O₅ 16.07, H₂O 11.14, total 100.39. The empirical formula calculated on (Si,Al)₄O₁₂(O,OH)₂ is as follows: (Sr_0.28Ba_0.16K_0.16Na_0.11Ca_0.09Zn_0.02) 0.82 (Ti_1.32Nb_0.69Fe_0.01)_2.02(Si_3.98Al_0.02)₄O₁₂[(OH)_1.89O_0.11]₂·2.59H₂O. The ideal formula is (Sr,Ba,K)(Ti,Nb)₂ (Si₄O₁₂)(OH,O)₂·3H₂O (Z=4). The mineral is monoclinic; space group Cm. The unit cell parameters (from the single crystal data) are as follows: a=14.490(3), b=14.23(1), c=7.881(3) Å, β=117.28(2)° , V=1444(1) Å ³. The strongest lines on the X-ray powder pattern are as follows (d,Å -I (hkl)): 7.10-90 (020, 001); 6.45-50 (200, 20-1); 5.01-40 (021); 3.230-100 (42-1, 400, 40-2); 3.135-80 (022, 041, 24-1); 2.510-80 (44-1, 401, 40-3, 042), 1.728-50 (461, 46-3, 081, 442, 44-4), 1.570-45 (84-1, 820, 84-3, 190, 82-4). The IR spectrum is given. The type specimen is deposited in the Fersman Mineralogical Museum RAS, Moscow. читать далее...

Senkevichite is a new cesium mineral, which has been found in the alkaline massif of Darai-Piyoz (Tajikistan). The mineral forms intergrowths of elongated boardlike grains up to 1 mm in light in quartzpectolite aggregates from blocks consisting mainly of granulated massive quartz. When transparent, the mineral is colourless, otherwise, white. The fracture is brittle. The Mohs hardness is 5.56. Measured density is 3.12 g/cm³ . The mineral is biaxial, optically positive; α_p=1.616(2), β_m=1.645(2), γ_g=1.683(2). Triclinic, space group P1; a=10.4191(4) Å, b=12.2408(5) Å, c=7.0569(3) Å, V=887.8(1) Å ³, Z=2. Chemical composition is as follows (electron microprobe analysis; H₂O is calculated, wt %): SiO₂ – 50.48, TiO₂ – 8.94, Nb₂O₅ – 0.64, FeO – 0.50, MnO – 2.59, CaO – 11.09, Na₂O – 3.73, K₂O – 6.13, Cs₂O – 15.28, H2O (calc) – 1.09, total – 100.47. Empirical formula of the mineral is Cs_0.90K_1.08Na_1.00(Ca_1.65Mn_0.30Fe_0.06)_2.01(Ti_0.93Nb_0.04)_0.97O_0.97[Si₇O₁₈(OH)]. Ideal formula is CsKNaCa₂TiO[Si₇O₁₈(OH)]. Strong lines on Xray powder diagram are following (d, I): 4.08 (13), 3.33 (11), 3.25(25), 3.14 (21), 3.06 (100), 2.959 (20), 2.038 (17). Crystal structure is solved with R=4.5%. The type specimen of the new mineral is kept in the Fersman Mineralogical Museum RAS (Moscow, Russia). читать далее...

Kyrgyzstanite is a new hydrous sulphate of aluminium and zinc with the formula ZnAl₄(SO₄)(OH)₁₂·3H₂O (monoclinic, sp. group P2₁/n, a=10.246(9) Å, b=8.873(4) Å, c=17.22(1) Å, β=96.41(7)°, V=1556(3) ų, Z=4), which has been found in vanadium-bearing slates of the KaraTangi deposit (Batken region, Kirgizia) in assemblage with quartz, calcite, alumohydrocalcite, nickelalumite, and allophane. The mineral forms crusts of radiating fibrous aggregates of split crystals. The dominant forms as follows: {001}, {110}, {010}, and {310}. Colour is light blue to greenish. The mineral is transparent; lustre is vitreous. The Mohs' hardness is 2–2.5; VHN=70 kg/mm² . Cleavage is perfect on (001). Density is 2.25(1) (meas), 2.242 g/cm³ (calc). Kyrgyzstanite is optically negative, biaxial; n_p=1.517(1), n_m=1.525(1), n_g=1.527(1), 2V_calc=53°. Dispersion is strong, r<v . Orientation is c˄Np=6°. Strong lines on X-ray powder diagram are as follows (d, I): 8.60(100), 7.93(70), 4.83(80), 4.27(100), 2.516(70), 2.292(80), 1.998(95), 1.896(65), 1.720(65). Chemical composition (electron microprobe analysis, wt %, average on 6 measurements) is as follows: ZnO 10.02 , NiO 4.13, CuO 0.58, FeO 0.32, V₂O₅ 0.08, Al₂O₃ 38.45, SiO₂ 0.33, SO₃ 15.00, H₂O 31.10 (wet chemistry), total 99.01. The empirical formula is (Zn_0.65Ni_0.29 Cu_0.04Fe_0.02)_0.99 Al_4.00Si_0.03(SO₄)_0.99 (OH)_12.12·2.81H₂O. Kyrgyzstanite is a structural analogue of nickelalumite. Crystal structure of the latter was solved on a single crystal of zincrich variety from the same geological formation; it represents brucitelike octahedral layers along (001) (octahedra Al and М). In the interlayer space the single (SO₄) tetrahedra and H2O molecules are localized. The IR spectrum is given. Mineral genesis is hydrothermal. Kyrgyzstanite was named in honour of Kirgizia (the Republic of Kyrgyzstan), where it was first discovered. Type material has been deposited in the collection of the Fersman Mineralogical Museum, Moscow. читать далее...

The revised crystallochemical formula of calcurmolite, (Ca,Na)₂(UO₂)₃Mo₂(O,OH)₁₁ nH₂O, is given on the basis of electron microprobe analyses of the samples from Kazakhstan (KyzylSai) and Armenia (Kadjaran). Parameters of the monoclinic unit cell: a=16.30 0.03 Å, b=25.49 0.05 Å, c=19.50 0.06 Å, β=90°07’, are estimated by X-ray diffraction method. The IR spectra and spectra of laser luminescence of two mentioned findings of the mineral have been obtained for the first time; they show the identity, stability, and diagnostic value of both methods. Micro-textural and structural peculiarities of calcurmolite prevent from the research of a crystal structure of the mineral. Calcurmolite was formed as a pseudomorph after uranophane. читать далее...

The new data has been obtained for turanite described in the beginning of the last century at the Tyuya-Muyun deposit; there are the results of study of the holotype specimen from the Fersman Mineralogical Museum RAS (Moscow) and new field collections. Turanite forms spherulite aggregates in assemblage with tangeite, malachite, barite, quartz, calcite; also turanite forms the cavernous aggregations with tangeite. Turanite is olivegreen, transparent, often it is represented by polysynthetic twins; the mineral is brittle. The Mohs hardness is 4.5-5, VHN=436 (354-570 kg/mm²). The cleavage is perfect on (011). Density (calc)=4.452 g/cm³ . The unit cell parameters calculated by the X-ray powder pattern are as follows: a=5.377(6) Å, b=6.276(7) Å, c=6.833(7) Å, α=86.28(2), β=91.71(3), γ=92.35(2)°, V=229.8(1) ų. Chemical composition is as follows (the holotype specimene/new collections; wt %): CuO 62.94/64.81, V₂O₅ 28.90/29.86, H₂O 5.85 (calculation by the crystal structural data)/5.81 (calculation by the charge balance), total 97.69/100.52. The empirical formula is Сu_4.97(VO₄)_2.00(OH)_4.08. The IR spectra of turanite and tangeite are given. The mineral genesis is hydrothermal. The turanite study results along with the earlier determined crystal structure confirm its status as the original mineral species. At the same time, a revision of information about findings of turanite in Nevada, USA, is necessary. читать далее...

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