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1.
The phlogopite, diopside, calcite, anhydrite and apatite pegmatites of Ampandrandava and Beraketa are examples for the many other pegmatites of similar silicocarbonatitic composition found in the Bekily and Betroka-Beraketa Precambrian belts of southern Madagascar. The two studied pegmatites and associated syenites crystallised from immiscible silicocarbonatitic and peralkaline syenitic melts in a time span between 515 and 504 Ma in the final extensional phase of the Panafrican continental collision and connected metamorphic/metasomatic event. Model T Nd ages suggest that the melts were produced by partial melting of 3.5 Ga partially evaporitic continental crust. The studied pegmatites and genetically associated syenitic rocks are very rare examples for crustal silicocarbonatitic melts generated in a Panafrican collisional setting. The overwhelming majority of carbonatites and associated peralkaline rocks are mantle derived, much poorer in phosphate and sulfate and found in a cratonic environment. In light of the present results, genetic models for other sulfate- and phosphate-rich magmatic rocks (e.g., phlogopite–apatite–calcite mineralisations in the Grenville-Hasting formation in Canada and in the Sludyanka group in Eastern Siberia) should be reevaluated.  相似文献   

2.
A suite of vanadian magnesiochromites from the Sludyanka metamorphic complex (South Lake Baikal, Russia) were investigated by means of X-ray single-crystal structural refinements and microprobe analyses. Various morphological types of Cr–V-bearing Mg spinels are located in calc–silicate metamorphic rocks, in an assemblage that also contains other Cr–V minerals such as escolaite–karelianite, uvarovite–goldmanite, Cr–V-bearing clinopyroxene, tourmaline, amphibole, mica, etc. Along the suite there is widespread V–Cr substitution (0.14 V3+ 0.95 afu, 1.02 Cr3+ 1.80 afu), and minor, variable Al contents. The Mg content of slightly lesser than 1 afu, is almost constant. Cell parameters and octahedral bond distances increase with V3+. Unexpectedly, the Mg–O tetrahedral bond distance also increases slowly with V3+. This weak dragging effect contributes towards maintaining distortion of the oxygen array with respect to the ideal CCP, thus providing a shielding effect, which reduces V3+–V3+ repulsion. This leads to the energetic stabilization of the structure, in spite of the increase of bond strain with increasing V3+ contents.  相似文献   

3.
Kyzylkumite has been found in Cr-V-bearing metamorphic rocks of the Sludyanka Complex, Southern Baikal region; it has been identified by X-ray powder diffraction method. This is a late secondary mineral developed after Ti-V-oxides (schreyerite, berdesinskiite) and V-bearing rutile and titanite. Kyzylkumite represents a new structural type with composition Ti4V 2 3+ O10(OH)2 corresponding to octahedral coordination of Ti4+ and V3+. Its unit-cell dimensions are: a = 8.4787(1), b = 4.5624(1), c = 10.0330(1) Å, β = 93.174(1)°. The ideal formula of kyzylkumite Ti4V 2 3+ O10(OH)2 corresponds to composition, wt %: 65.56 TiO2, 30.75 V2O3, 3.69 H2O. Indeed, the contents (wt %) of these constituents range from 62 to 70 TiO2 and from 23 to 33 V2O3. Variations in contents and the Ti/V value are caused by partial substitution V3+ for V4+, isovalent substitutions Ti4+ and V3+ for V4+ and Cr3+, respectively, and coupled substitution V3+ + OH? ? Ti4+ + O2?. Smyslova et al. (1981)—the discovereres of kyzylkumite—assumed its composition to be the same as for schreyerite V 2 3+ Ti3O9 that principally different from kyzylkumite from the Sludyanka Complex. Therefore, re-examination of the kyzylkumite holotype or cotype from its type locality is needed.  相似文献   

4.
Zusammenfassung Die Kristallstruktur des Johannits wurde anhand eines verzwillingten Kristalls von Joachimsthal, Böhmen, mit dreidimensionalen Röntgendaten bestimmt und für 2005 unabhängige Reflexe aufR=0,039 verfeinert. Johannit kristallisiert triklin, RaumgruppeP1, mita=8,903 (2),b=9,499 (2),c=6,812 (2) Å, =109,87 (1) =112,01 (1), =100,40 (1)° undV=469,9 Å3. Chemische Formel und Zellinhalt lauten Cu(UO2)2(OH)2(SO4)2·8H2O, das ist um zwei H2O-Moleküle mehr als bisher angenommen. In der Struktur sind pentagonal dipyramidale (UO2)(OH)2O3-Polyeder paarweise über eine von zwei OH-Gruppen gebildete Kante zu Doppelpolyedern und diese wiederum durch SO4-Gruppen zu (UO2)2(OH)2(SO4)2-Schichten parallel (100) verknüpft. Die Schichten sind parallel über gestreckte Cu(H2O)4O2-Oktaeder und Wassermoleküle miteinander verbunden. Folgende Bindungslängen wurden gefunden: U–O=1,78 Å (2x) und 2,34–2,39 Å (5x); Cu–O=1,97 Å (4x) und 2,40 Å (2x); =1,47 Å; O–O in Wasserstoffbrücken 2,71–2,91 Å (8x) und 3,30 Å.
The crystal structure of johannite, Cu(UO2)2(OH)2(SO4)2·8H2O
Summary The crystal structure of johannite has been determined from threedimensional X-ray data measured on a twinned crystal from Joachimsthal, Böhmen, and has been refined toR=0.039 for 2005 independent reflections. Johannite crystallizes triclinic, space groupP1, witha=8.903 (2),b=9.499 (2),c=6.812 (2) Å, =109.87(1), =112.01(1), =100.40 (1)° andV=469.9 Å3. Chemical formula and cell content are Cu(UO2)2(OH)2(SO4)2·8H2O, by two H2O molecules more than previously assumed. Pairs of pentagonal dipyramidal (UO2) (OH)2O3 polyhedra form double polyhedra by edgesharing via two OH groups. The double polyhedra are linked by the SO4 tetrahedra to form layers (UO2)2(OH)2(SO4)2 parallel zu (100). These layers are interconnected parallel toa by elongated Cu(H2O)4O2 octahedra and water molecules. Following bond lengths have been observed: U–O=1.78 Å (2x) and 2.34–2.39 Å (5x); Cu–O=1.97 Å (4x) and 2.40 Å (2x); =1.47 Å; O–O for hydrogen bonds 2.71–2.91 Å (8x) and 3.30 Å.

Mit 2 Abbildungen  相似文献   

5.
题词(2)     
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6.
Three types of clinopyroxene megacrysts have been collected from Cenozoic basaltic rocks from Hainan Island and the Leizhou Peninsula in southern China. These megacrysts are dark green, black, and pale green in color, and are classified as Al-augite, Al-rich Fe-Na salite, and endiopside, respectively. Although they have different geochemical compositions, they all exhibit convex-upward, MREE-enriched patterns.

The Al-augite megacrysts contain 8.45 to 9.01% Al2O3, 1.26 to 1.59% TiO2, 1.60 to 1.88% Na2O; have Mg# values of 69.5 to 75.4; and possess ΣREE contents of 24.7 to 26.9 ppm. Their LREE contents are enriched relative to the HREE (La/Ybn = 3.05 to 4.09). The Al-rich Fe-Na salite megacrysts have higher FeOT (10.4 to 11.4%) and Na2O (2.07 to 2.78%) contents, and lower Mg' values (54.9 to 59.9), than do the Al-augite megacrysts. They contain high ΣREE contents (29.4 to 41.9 ppm) and have pronounced LREE/HREE enrichment (La/Ybn = 3.86 to 20.6). Their Al2O3 contents (10.1 to 12.2%) are much higher than those of the Al-augite megacrysts (8.45 to 9.01%). One Al-rich Fe-Na salite megacryst has 87Sr/86Sr of 0.702913 ± 25 and 143Nd/144Nd of 0.512939 ± 20. The endiopside megacrysts possess high En and low Fs contents (Mg# values up to 89.3), and are characterized by high Cr2O3 (0.35 to 0.61%) and low Al2O3 (6.38 to 6.98%), TiO2 (0.30 to 0.48%), and ΣREE (7.71 ppm) contents. They have similar values of normalized LREE and HREE (La/Ybn = 1.09). One endiopside megacryst has 87Sr/86Sr of 0.703946 + 40 and 143Nd/144Nd of 0.512816 ± 18.

The Al-rich Fe-Na salite megacrysts in this study can be distinguished compositionally from Fe-Na salite megacrysts of previous studies. On the basis of the present study, these megacrysts are considered representative of a distinctive type of megacryst that may have a unique origin. Prior to this, endiopside megacrysts have not been described from alkaline basalts. A total of four types of clinopyroxene megacrysts now can be described from Cenozoic basaltic rocks worldwide—i.e. Al-augite, Fe-Na salite, Al-rich Fe-Na salite, and endiopside.  相似文献   

7.
Summary The crystal structure of sigloite, Fe3 [(H2O)3OH] [Al2(PO4)2(OH)2(H2O)2]- 2 H2O, triclinic, a 5.190 (2), b 10.419 (4), c 7.033 (3) Å, 105.00 (3), 111.31(3), 70.87 (3)°, V 330.5 (2) Å3, Z = 1, space group P , has been refined to anR index of 5.3% using 1713 observed (I > 2.5 1) reflections collected with graphite-monochromated MoK X-rays. Sigloite is isostructural with the laueite-group minerals. Corner-linked [A15] chains (: unspecified ligand) are cross-linked by (PO4) tetrahedra to form a mixed corner-linked tetrahedral-octahedral sheet of composition [A12(PO4)2(OH)2(H2O)2]2-. These sheets are linked by (Fe3+O2(OH, H2O)4) octahedra and two (H2O) groups that participate in a hydrogen-bonding network. Sigloite is the oxidized equivalent of paravauxite, Fe2+(H2O)4[Al2(PO4)2(OH)2(H2O)2]-2 H2O, and detailed comparison of the two structures shows that the oxidation mechanism involves loss of hydrogen from one of the (H2O) groups coordinating the Fe3+, and positional disorder of both the Fe3+ and (OH) and (H2O) ligands.
Siggloit: Der Oxidationsmechanismus in (M 2 3 + (PO4)2(OH)2(H2O)2]2- Strukturen
Zusammenfassung Die Kristallstruktur von Sigloit, Fe3+ [(H2O)3OH] [Al2(PO4)2(OH)2(H2O)2].2 H2O, triklin, a 5,190 (2), b 10,419 (4), c 7,033 (3) Å, 105,00 (3), 111,31 (3), 70,87 (3)°, V 330,5 (2) Å3,Z = 1, Raumgruppe P , wurdefür 1713 beobachtete Reflexe (I > 2,5 I), die mit MoKa-Röntgenstrahlung (Graphit-Monochromator) gesammelt wurden, auf einen R-Wert von 5,3% verfeinert. Sigloit ist isotyp mit den Mineralen deer Laueit-Gruppe. Über Ecken verknüpfte [A15]-Ketten (: nicht spezifizierter Ligand) werden über (P04)-Tetraeder zu ebenfalls über Ecken verknüpfte Tetraeder-OktaederSchichten der Zusammensetzung [A12(PO4)2(OH)2(H2O)2]2- verbunden. Diese Schichten werden über (Fe3+O2(OH, H2O)4)-Oktaeder und zwei (H2O)-Gruppen, die amWasserstoffbrücken-Netzwerk beteiligt sind, verbunden. Sigloit ist das oxidierte Analogon zu Paravauxit, Fe2+(H2O)4[A12(PO4)2(OH)2(H2O)2] - 2 H2O; ein detaillierter Vergleich dieser beiden Strukturen zeigt, daß der Oxidationsmechanismus sowohl den Verlust eines Wasserstoffatoms (H2O)-Gruppe, welche ein Fe3+-Atom koordiniert, als auch eine Fehlordnung der Punktlagen von Fe3+ und von den (OH) und (H2O) Liganden bedingt.
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8.
 Thermodynamic properties of high-pressure minerals that are not recoverable from synthesis experiments by conventional quenching methods (“unquenchable” phases) usually are calculated from equation of state data and phase diagram topologies. The present study shows that, with cryogenic methods of recovery and sample treatment, phases with a suitable decomposition rate can be made accessible to direct thermodynamic measurements. A set of samples of Ca(OH)2-II has been synthesized in a multianvil device and subsequently recovered by cooling the high-pressure assembly with liquid nitrogen. Upon heating from liquid nitrogen to room temperature, the material transformed back to Ca(OH)2-I. The heat effect of this backtransformation was measured by differential scanning calorimetry. A commercial differential scanning calorimeter (Netzsch DSC 404), modified to allow sample loading at liquid nitrogen temperature was used to heat the material from −150 to +200 °C at rates varying between 5 and 15 °C min−1. The transformation started around −50 °C very gradually, and peaked at about 0 °C. To obtain a baseline correction, each sample was scanned under exactly the same conditions after the backtransformation was complete. Because of the relative sluggishness, onset and offset temperatures were not well defined as compared to fast (e.g., melting) reactions. To aid in integration, the resulting signals were successfully fitted using a generic asymmetric peak model. The enthalpy of backtransformation was determined to be ΔH =−10.37 ± 0.50 kJ mol−1. From previous in situ X-ray diffraction experiments, the location of the direct transformation in P-T space has been constrained to 5.7 ± 0.4 GPa at 500 °C (Kunz et al. 1996). With the reaction volume known from the same study, and assuming that ΔC p of the transformation remains negligible between the conditions of our measurements and 500 °C, our result gives an estimate of the entropy of transition and the P-T slope of the reaction curve. To a first approximation, the values ΔS = −16.00 ± 0.65 J(mol · K)−1 and dP/dT = 0.0040 ± 0.0002 GPa/K have been determined. These results need to be refined by equation of state data for Ca(OH)2-II. Received: 30 December 1999 / Accepted: 10 April 2000  相似文献   

9.
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10.
Compressibilities and high-pressure crystal structures have been determined by X-ray methods at several pressures for phenakite and bertrandite. Phenakite (hexagonal, space group R \(\bar 3\) ) has nearly isotropic compressibility with β=1.60±0.03×10?4 kbar?1 and β=1.45±0.07×10?4 kbar?1. The bulk modulus and its pressure derivative, based on a second-order Birch-Murnaghan equation of state, are 2.01±0.08 Mbar and 2±4, respectively. Bertrandite (orthorhombic, space group Cmc21) has anisotropic compression, with β a =3.61±0.08, β b =5.78±0.13 and β c =3.19±0.01 (all ×10?4 kbar?1). The bulk modulus and its pressure derivative are calculated to be 0.70±0.03 Mbar and 5.3±1.5, respectively. Both minerals are composed of frameworks of beryllium and silicon tetrahedra, all of which have tetrahedral bulk moduli of approximately 2 Mbar. The significant differences in linear compressibilities of the two structures are a consequence of different degrees of T-O-T bending.  相似文献   

11.
Amber (Part 2)     
R. J King 《Geology Today》2007,23(2):74-77
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12.
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13.
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14.
Single crystals of two novel calcium oxotellurate(IV) nitrates were grown under hydrothermal conditions and were structurally characterized by X-ray diffraction. Ca $_5$ Te $_4\text {O}_{12}$ (NO $_3$ ) $_2$ (H $_2$ O) $_2$ [ $Cc$ , $Z=4$ , $a=25.258(3)$ Å, $b=5.7289(7)$ Å, $c=17.0066(19)$ Å, $\beta =124.377(2)^{\circ}$ , $R[F^2 > 2\sigma (F^2)]=0.043$ , 4083 $F^2$ data, 281 parameters] can be described as a non-classic order/disorder (OD) structure, which fulfills the basic principle of OD theory, viz. local equivalence of polytypes, but does not strictly follow the vicinity condition (VC) of OD theory. The structure is made up from an alternating stacking of non-polar layers composed of isolated [TeO $_3$ ] units and Ca $^{2+}$ ions and polar layers containing NO $_3^-$ ions and water molecules. The electron lone-pairs of the [TeO $_3$ ] units protrude into the free space of the anion/water layers. The crystal under investigation was a non-classic OD-twin of domains of a maximum degree of order (MDO). At the twin plane a fragment of the second MDO polytype is located. The main building blocks of Ca $_6$ Te $_5\text {O}_{15}$ (NO $_3$ ) $_2$ [ $P2_1/c$ , $Z=4$ , $a=15.494(2)$ Å, $b=5.6145(7)$ Å, $c=39.338(4)$ Å, $\beta =142.480(5)^{\circ}$ , $R[F^2 > 2\sigma (F^2)]=0.043$ , 3026 $F^2$ data, 307 parameters] are isolated [TeO $_3$ ] units and Ca $^{2+}$ ions which are connected to a three-dimensional framework perforated by channels in which the N atoms of the nitrate anions are located and the electron lone-pairs of the [TeO $_3$ ] units protrude. The structure can topologically be derived from the structure of Ca $_5$ Te $_4\text {O}_{12}$ (NO $_3$ ) $_2$ (H $_2$ O) $_2$ by removing the water molecules and connecting the CaTeO $_3$ layers with additional [TeO $_3$ ] units and Ca $^{2+}$ ions.  相似文献   

15.
在山东蒙阴金伯利岩中,首次发现了沂蒙矿类质同象系列新的富Ti矿物(变)种。理想的晶体化学式可表达为:K(Ti5Fe3Cr2Mg2)12O19(简称K-Ti沂蒙矿)(Ba,K)(Ti5Fe4Mg2Cr)12O19(简称Ba-Ti沂蒙矿)从而与原来确定的沂蒙矿K(Cr5Ti3Fe2Mg2)12O19和钡钛铁铝矿(Ba,K)(Cr4Fe4Ti3Mg)12O19一起构成了金伯利岩中AM12O19磁铁铅矿型矿物的K-Cr、Ba-Cr、K-Ti、Ba-Ti四种端元类型的复杂类质同象系列。新发现的两个矿物(变)种均产出于具叶片状尖晶石出溶体的镁钛铁矿中。根据结构已知的沂蒙矿中原子的占位和配位多面体情况,分析了K-Ti,Ba-Ti沂蒙矿中各原子的占位和配位多面体,认为新发现的两个(变)种在成分上与沂蒙矿和钡钛铁铬矿有明显的区别。根据镁钛铁矿、尖晶石、沂蒙矿新(变)种、钙钛矿之间的相互关系,探讨了它们的形成环境,从而为这类矿物的地幔成因提供了直接证据。  相似文献   

16.
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17.
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18.
Summary The crystal structure of meta-uranocircite II, Ba(UO2)2(PO4)2·6H2O, has been determined with a synthetic crystal using three-dimensional X-ray techniques.R=0.071 andR w =0.064 were obtained for 1743 observed reflections. Ba(UO2)2(PO4)2·6H2O is monoclinic, space groupP1121/a, a=9.789,b=9.822,c=16.868 Å, =89.95° andZ=4. The structure consists of slightly corrugated UO2PO4 layers parallel (001). The layers are connected by Ba atoms and H2O molecules. Uranium exhibits a (2+4)-coordination with mean U-O bond lengths of 1.78 Å for the uranyl oxygens and 2.28 Å for the phosphate oxygens. The average P-O bond length is 1.52 Å. Barium is coordinated by two uranyl oxygens. two phosphate oxygens and five water molecules. The Ba–O bond lengths vary from 2.74 to 3.11 Å. Two of the six water molecules of the formula are not bonded to barium.
Die Kristallstruktur des Meta-Uranocircits II, Ba(UO2)2(PO4)2·6H2O
Zusammenfassung Die Kristallstruktur des Meta-Uranocircits II, Ba(UO2)2(PO4)2·6H2O, wurde anhand eines künstlichen Kristalls mit dreidimensionalen Röntgendaten bearbeitet und für 1743 Reflexe aufR=0,071 undR w =0,064 verfeinert. Ba(UO2)2(PO4)2·6H2O kristallisiert monoklin in der RaumgruppeP1121/a, a=9,789,b=9,882,c=16,868 Å, =89,95° und einem Zellinhalt von vier Formeleinheiten. Die Struktur besteht aus schwach gewellten UO2PO4-Schichten parallel (001), die durch Ba-Atome und H2O-Moleküle miteinander verknüpft sind. Uran besitzt oktaedrische (2+4)-Koordination mit mittleren U-O-Abständen von 1,78 Å für die Uranylsauerstoffatome und 2,28 Å für die Phosphatsauerstoffatome. Die P-O-Abstände der Phosphattetraeder messen im Mittel 1.52 Å. Barium ist von je zwei Uranyl- und Phosphatsauerstoffatomen sowie von fünf Wassermolekülen koordiniert. Die Ba-O-Abstände betragen 2,74–3,11 Å. Von den sechs H2O-Molekülen der Formel sind zwei nicht an Barium gebunden.

With 3 Figures  相似文献   

19.
Summary The crystal structure of walpurgite has been determined from three-dimensional X-ray single crystal data and has been refined toR=0.041 for 1381 independent reflections using a crystal from Schneeberg, Sachsen. Walpurgite crystallizes triclinic, space group , witha=7.135 (2),b=10.426 (4),c=5.494 (1) Å, =101 47 (2), =110.82 (2), =88.20 (2)o andV-374 A3. Cell content and chemical formula are (UO2)Bi4O4(AsO4)2·2H2O, which is one H2O less than previously known. The structure consists of complex layers Bi4O4(AsO4)2·2H2O extending parallel to (010). Each layer is built up from a network of bismuth and oxygen atoms, to both sides of which AsO4 groups and water molecules are attached. (UO2)O4 octahedra link the layers parallel tob via the AsO4 groups and thus simultaneously from UO2(AsO4)2 chains parallel toc. The two independent Bi atoms are trivalent and form pronounced one-sided BiO polyhedra: 4–5 oxygens are at distances of 2.11–2.48 Å, 4 additional oxygens are at distances of 2.63–3.35 Å.
Die Kristallstruktur des Walpurgins, (UO2)Bi4O4(AsO4)2·2H2O
Zusammenfassung Die Kristallstruktur des Walpurgins wurde anhand eines Kristalls von Schneeberg, Sachsen, mit dreidimensionalen Röntgen-Einkristalldaten bestimmt und für 1381 Reflexe aufR=0,041 verfeinert. Walpurgin kristallisiert triklin, Raumgruppe ,a=7,135 (2),b=10,426 (4),c=5,494 (1) Å, =101,47 (2), =110,82 (2), =88,20 (2)o undV=374 Å3. Zellinhalt und chemische Formel lauten (UO2)Bi4O4(AsO4)2·2H2O, das ist um ein H2O-Molekül weniger als bislang bekannt. Die Struktur enthält kompliziert gebaute Bi4O4(AsO4)2·2H2O-Schichten, die sich parallel (010) erstrecken. Jede Schicht besteht aus einem Netz von Wismut- und Sauerstoffatomen, an das zu beiden Seiten AsO4-Gruppen und H2O-Moleküle anknüpfen. (UO2)O4-Oktaeder verbinden die Schichten über die AsO4-Gruppen parallel zub und bilden so gleichzeitig (UO2)(AsO4)2-Ketten parallel zuc aus. Die zwei unabhängigen, dreiwertigen Wismutatome des Walpurgins sind von 4–5 Sauerstoffatomen in Abständen von 2,11–2,48Å einseitig koordiniert und darüber hinaus noch von vier weiteren Sauerstoffatomen in Abständen von 2,63–3,35 Å umgeben.

With 4 Figures  相似文献   

20.
Summary The mineral trigonite crystallizes in the monoclinic space groupPn–C s 2 witha 0=7.26,b 0=6.78,c 0=11.09Å; =91.5°,Z=2. The structure was determined from 1250 X-ray intensities collected on an automatic two circle Weissenberg-type diffractometer. The final residual isR=6.5% using anisotropic temperature factors for Pb, Mn and As, and isotropic temperature factors for O.The structure consists of MnO6 octahedra, sharing all six oxygens with arsenite groups to form a framework. The Pb atoms are attached to this framework with Pb–O distances2.23Å. One oxygen, bound only to an As atom, is interpreted as the donor for a hydrogen bond of 2.75Å.
Die Kristallstruktur des Trigonits, Pb3Mn(AsO3)2(AsO2OH)
Zusammenfassung Das Mineral Trigonit kristallisiert monoklin, RaumgruppePn–C s 2 ,a 0=7,26,b 0=6,78,c 0=11,09Å; =91,5°;Z=2. Die Strukturermittlung erfolgte anhand von 1250 Röntgenintensitäten, die auf einem automatischen Zweikreis-Weissenbergdiffraktometer gesammelt wurden. Mit anisotropen Temperaturfaktoren für Pb, Mn und As sowie isotropen für die O-Atome ergibt sich einR-Wert von 6,5%.Die MnO6-Oktaeder werden über die sechs Sauerstoffe mit Arsenitgruppen zu einem dreidimensionalen Gerüst verknüpft. Über Pb-O-Abstände2,23 Å sind die Pb-Atome in dieses Gerüst eingebaut. Ein Sauerstoff, nur an ein As-Atom gebunden, wird als Donator einer H-Brücke von 2,75 Å interpretiert.

With 2 Figures  相似文献   

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