Journal/NDM59 2025 eng — различия между версиями

Версия 16:21, 13 июня 2025

New Data on Minerals, Volume 59, 2025

Содержание

1 DEADLINES FOR ARTICLES
2 Editorial Board
3 Content
- 3.1 Issue 1

DEADLINES FOR ARTICLES

Issue 1 - March 31, 2025
Issue 2 - May 31, 2025
Issue 3 - August 31, 2025
Issue 4 - November 30, 2025

Editorial Board

Editor in Chief:
Plechov P.Yu. -D.Sc. in Geology and Mineralogy, Professor
Members of Editorial Board:
Pekov I.V. - Corresponding Member of the Russian Academy of Sciences
Garanin V.K. - D.Sc. in Geology and Mineralogy, Professor
Borutsky B.E. - D.Sc. in Geology and Mineralogy
Spiridonov B.E. - D.Sc. in Geology and Mineralogy
Chukanov N.V. - D.Sc. in Physical and Mathematical Sciences
Kamenetsky V.S. - Professor (University of Tasmania)
Nenasheva S.N. - PhD in Geology and Mineralogy
Matvienko E.N. - PhD in Geology and Mineralogy
Generalov M.E. - PhD in Geology and Mineralogy
Pautov L.A. - Senior Researcher
Layout Designer
Kronrod E.V. - PhD in Chemistry

Content

Issue 1

Pautov L.A., Shodibekov M.A., Makhmadsharif S. Discovery of tainiolite in the carbonatites of the Dunkeldyk massif, Eastern Pamirs, p. 5-7

Taeniolite, KLiMg₂Si₄O₁₀F₂, was discovered in a strontium-rich carbonatites of the Cenozoic subvolcanic potassium alkaline complex of Dunkeldyk (37^о46'50N, 74^o59'37E), Eastern Pamir, Gorno-Badakhshan Autonomous Oblast, Tajikistan. Taeniolite occurs as light-brown lamellar grains up to 3 mm in diameter and up to 0.4 mm in thick in a rock, which consists of calcium strontianite (Sr_0.54Ca_0.46)CO₃, fluorite, Sr-bearing calcite, strontianite, Sr-bearing fluorapatite, barite, amphibole group member, which close to magnesio-fluoro-arfvedsonite, aegirine, cancrinite group mineral, ankylite-(Ce) and pyrite. Taeniolite is optically biaxial (–), 2V = 5–10(2)^o. Refractive indices of the mineral are: n_g = n_m = 1.547(2), n_p= 1.524(2). Taeniolite from the Dunkeldyk massif is characterized with lithium content close to theoretical and extreme fluorine amount. Chemical analysis by electron microprobe (7 points) and LA-ICP-MS for Li gave SiO₂ 58.98, TiO₂ 0.09, Al₂O₃ 0.23, FeO 0.51, MnO 0.12, MgO 19.89, K₂O 11.28, Na₂O 0.38, Li₂O 3.65, F 9.24, H₂O 0.07, total 104.44; –O=F₂ –3.88; total 100.57 wt%. The empirical formula, based on 10 O apfu is: (K_0.97Na_0.05)_1.02(Li_0.97Mg_0.03)_1.00(Mg_1.97Fe_0.03Mn_0.01)_2.01(Si_3.97Al_0.02Ti_0.01)_4.00O₁₀[F_1.97(OH)_0.03]₂. The main absorption bands in the IR spectrum of taeniolite (cm^–1): 1129, 967, 721, 497, 383. In the Raman spectrum, strong lines (cm^–1): 184, 258, 295, 307, 334, 701, 956, 1146. X-ray powder pattern of taeniolite is given. Apparently, this is the first discovery of a lithium mineral in the Dunkeldyk carbonatites.
Keywords: minnesotaite, ferrohortonolite-fayalite plagiogranites, Castel Mountain, Mountain Crimean mesozoids. читать далее...

Russian page (V. 59)

@@ Строка 28: / Строка 28: @@
 | Авторы = Pautov L.A., Shodibekov M.A., Makhmadsharif S.
 | Название = Discovery of tainiolite in the carbonatites of the Dunkeldyk massif, Eastern Pamirs, p. 5-7
-| Аннотация = Taeniolite, KLiMg<sub>2</sub>Si<sub>4</sub>O<sub>10</sub>F<sub>2</sub>, was discovered in a strontium-rich carbonatites of the Cenozoic subvolcanic potassium alkaline complex of Dunkeldyk (37<sup>о</sup>46'50''N, 74<sup>o</sup>59'37''E), Eastern Pamir, Gorno-Badakhshan Autonomous Oblast, Tajikistan. Taeniolite occurs as light-brown lamellar grains up to 3 mm in diameter and up to 0.4 mm in thick in a rock, which consists of calcium strontianite (Sr<sub>0.54</sub>Ca<sub>0.46</sub>)CO<sub>3</sub>, fluorite, Sr-bearing calcite, strontianite, Sr-bearing fluorapatite, barite, amphibole group member, which close to magnesio-fluoro-arfvedsonite, aegirine, cancrinite group mineral, ankylite-(Ce) and pyrite. Taeniolite is optically biaxial (–), 2<i>V</o> = 5–10(2)<sup>o</sup>. Refractive indices of the mineral are: <i>n<sub>g</sub></i> = <i>n<sub>m</sub></i> = 1.547(2), <i>n<sub>p</sub></i>= 1.524(2). Taeniolite from the Dunkeldyk massif is characterized with lithium content close to theoretical and extreme fluorine amount. Chemical analysis by electron microprobe (7 points) and LA-ICP-MS for Li gave SiO<sub>2</sub> 58.98, TiO<sub>2</sub> 0.09, Al<sub>2</sub>O<sub>3</sub> 0.23, FeO 0.51, MnO 0.12, MgO 19.89, K<sub>2</sub>O 11.28, Na<sub>2</sub>O 0.38, Li<sub>2</sub>O 3.65, F 9.24, H<sub>2</sub>O 0.07, total 104.44; –O=F<sub>2</sub> –3.88; total 100.57 wt%. The empirical formula, based on 10 O apfu is: (K<sub>0.97</sub>Na<sub>0.05</sub>)<sub>1.02</sub>(Li<sub>0.97</sub>Mg<sub>0.03</sub>)<sub>1.00</sub>(Mg<sub>1.97</sub>Fe<sub>0.03</sub>Mn<sub>0.01</sub>)<sub>2.01</sub>(Si<sub>3.97</sub>Al<sub>0.02</sub>Ti<sub>0.01</sub>)<sub>4.00</sub>O<sub>10</sub>[F<sub>1.97</sub>(OH)<sub>0.03</sub>]<sub>2</sub>. The main absorption bands in the IR spectrum of taeniolite (cm<sup>–1</sup>): 1129, 967, 721, 497, 383. In the Raman spectrum, strong lines (cm<sup>–1</sup>): 184, 258, 295, 307, 334, 701, 956, 1146. X-ray powder pattern of taeniolite is given. Apparently, this is the first discovery of a lithium mineral in the Dunkeldyk carbonatites.<br>
+| Аннотация = Taeniolite, KLiMg<sub>2</sub>Si<sub>4</sub>O<sub>10</sub>F<sub>2</sub>, was discovered in a strontium-rich carbonatites of the Cenozoic subvolcanic potassium alkaline complex of Dunkeldyk (37<sup>о</sup>46'50''N, 74<sup>o</sup>59'37''E), Eastern Pamir, Gorno-Badakhshan Autonomous Oblast, Tajikistan. Taeniolite occurs as light-brown lamellar grains up to 3 mm in diameter and up to 0.4 mm in thick in a rock, which consists of calcium strontianite (Sr<sub>0.54</sub>Ca<sub>0.46</sub>)CO<sub>3</sub>, fluorite, Sr-bearing calcite, strontianite, Sr-bearing fluorapatite, barite, amphibole group member, which close to magnesio-fluoro-arfvedsonite, aegirine, cancrinite group mineral, ankylite-(Ce) and pyrite. Taeniolite is optically biaxial (–), 2<i>V</i> = 5–10(2)<sup>o</sup>. Refractive indices of the mineral are: <i>n<sub>g</sub></i> = <i>n<sub>m</sub></i> = 1.547(2), <i>n<sub>p</sub></i>= 1.524(2). Taeniolite from the Dunkeldyk massif is characterized with lithium content close to theoretical and extreme fluorine amount. Chemical analysis by electron microprobe (7 points) and LA-ICP-MS for Li gave SiO<sub>2</sub> 58.98, TiO<sub>2</sub> 0.09, Al<sub>2</sub>O<sub>3</sub> 0.23, FeO 0.51, MnO 0.12, MgO 19.89, K<sub>2</sub>O 11.28, Na<sub>2</sub>O 0.38, Li<sub>2</sub>O 3.65, F 9.24, H<sub>2</sub>O 0.07, total 104.44; –O=F<sub>2</sub> –3.88; total 100.57 wt%. The empirical formula, based on 10 O apfu is: (K<sub>0.97</sub>Na<sub>0.05</sub>)<sub>1.02</sub>(Li<sub>0.97</sub>Mg<sub>0.03</sub>)<sub>1.00</sub>(Mg<sub>1.97</sub>Fe<sub>0.03</sub>Mn<sub>0.01</sub>)<sub>2.01</sub>(Si<sub>3.97</sub>Al<sub>0.02</sub>Ti<sub>0.01</sub>)<sub>4.00</sub>O<sub>10</sub>[F<sub>1.97</sub>(OH)<sub>0.03</sub>]<sub>2</sub>. The main absorption bands in the IR spectrum of taeniolite (cm<sup>–1</sup>): 1129, 967, 721, 497, 383. In the Raman spectrum, strong lines (cm<sup>–1</sup>): 184, 258, 295, 307, 334, 701, 956, 1146. X-ray powder pattern of taeniolite is given. Apparently, this is the first discovery of a lithium mineral in the Dunkeldyk carbonatites.<br>
 '''Keywords:''' minnesotaite, ferrohortonolite-fayalite plagiogranites, Castel Mountain, Mountain Crimean mesozoids.
 | Файл = Pautov_et_al_1_2025-1.pdf