Tourmaline: An ideal indicator of its host environment

Canadian Mineralogist

Volumn 49, Issue 1, 2011, Pages 1-16

  Van Hinsberg, Vincent J ^a   Henry, Darrell J ^b   Marschall, Horst R ^c,d  

^a UNIVERSITY OF OXFORD   (United Kingdom)

^b LOUISIANA STATE UNIVERSITY   (United States)

^c UNIVERSITY OF BRISTOL   (United Kingdom)

^d WOODS HOLE OCEANOGRAPHIC INSTITUTION   (United States)

Author keywords

Composition; Crystallography; Isotopes; Petrogenetic indicator mineral; Petrology; Tourmaline; Zoning

Indexed keywords

COMPOSITION; COMPOSITIONAL SENSITIVITY; CRYSTALLOGRAPHIC CHARACTERISTICS; CRYSTALLOGRAPHIC CHARACTERIZATION; EARTH'S CRUST; ENVIRONMENTAL CONDITIONS; FLUID COMPOSITION; HIGH TEMPERATURE; PETROGENETIC INDICATOR MINERAL; QUANTITATIVE INDICATORS; ROCK ALTERATIONS; ROCK COMPOSITION; TORONTO; TOURMALINE;

CRYSTALLOGRAPHY; INDICATORS (CHEMICAL); ISOTOPES; MINERALOGY; MINERALS; PETROGRAPHY; PETROLOGY; ROCKS; STRUCTURAL GEOLOGY; WEATHERING; ZONING;

SILICATE MINERALS;

CRYSTALLOGRAPHY; DIFFUSION; FLUID COMPOSITION; HIGH PRESSURE; HIGH TEMPERATURE; ISOTOPIC COMPOSITION; PETROGENESIS; PETROLOGY; PHYSICOCHEMICAL PROPERTY; TOURMALINE; ZONING;

CANADA; ONTARIO [CANADA]; TORONTO;

EID: 79954527129     PISSN: 00084476     EISSN: None     Source Type: Journal    
DOI: 10.3749/canmin.49.1.1     Document Type: Article

References (129)

1. ANGLIN, C.D., JONASSON, I.R. & FRANKLIN, J.M. (1996): SmNd dating of scheelite and tourmaline: implications for the genesis of Archean gold deposits, Val d'Or, Canada. Econ. Geol. 91, 1372-1382.
2. ANOVITZ, L.M. & GREW, E.S. (1996): Mineralogy, petrology and geochemistry of boron: an introduction. In Boron:. Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 1-40.
3. ANSDELL, K.M. & KYSER, T.K. (1992): Mesodermal gold mineralization in a Proterozoic Greenstone Belt: western Flin Flon Domain, Saskatchewan, Canada. Econ. Geol. 87, 1496-1524.
4. ANTHONY, J.W., BIDEAUX, R.A., BLADH, K.W. & NICHOLS, M.C. (1995): Handbook of Mineralogy. II. Silica, Silicates. Mineral Data Publishing, Tucson, Arizona.
5. BAČÍK, P., MERES, Š. & UHER, P. (2011): Vanadium-rich tourmaline in the metacherts from Chvojnica, Slovakia: crystal chemistry and multistage evolution. Can. Mineral. 49.
6. BAKSHEEV, I.A., PROKOF'EV, V. Y., YAPASKURT, V.O., VIOASINA, M.F., ZORINA, L.D. & SOLOV'EV, V.N. (2011) : Ferric-ironrich tourmaline from the Darasun gold deposit, Transbaikalia, Russia. Can. Mineral. 49, 263-276.
7. 39Ar chronology of tourmaline-rich rocks from central Iberia dates the main Variscan deformation phases. Geol. Acta 7, 399-412.
8. BEBOUT, G.E. & NAKAMURA, E. (2003): Record in metamorphic tourmalines of subduction-zone devolatilization and boron cycling. Geology 31, 407-410.
9. BEURLEN, H., DE MOURA, O.J.M., SOARES, D.R., DA SILVA, M.R.R. & RHEDE, D. (2011): Geochemical and geological controls on the genesis of gem-quality "Paraíba Tourmaline" in granitic pegmatites from northeastern Brazil. Can. Mineral. 49, 277-300.
10. 2+ over octahedrally coordinated sites of tourmaline. Am. Mineral. 93, 1647-1653.
11. Bosi, F. (2011): Stereochemical constraints in tourmaline: from short-range to long-range structure. Can. Mineral. 49, 17-27.
12. Bosi, F., BALIĆ-ŽUNIĆ, T. & SUROUR, A.A. (2010): Crystal structure analysis of four tourmaline from the Cleopatra's Mines (Egypt) and Jabal Zalm (Saudi Arabia) and the role of Al in the tourmaline group. Am. Mineral. 95, 510-518.
13. Bosi, F. & LUCCHESI, S. (2004): Crystal chemistry of the schorl-dravite series. Eur. J. Mineral. 16, 335-344. (Pubitemid 38550199)
14. Bosi, F. & LUCCHESI, S. (2007): Crystal chemical relationships in the tourmaline group: structural constraints on chemical variability. Am. Mineral. 92, 1054-1063. (Pubitemid 47162954)
15. BRADY, J.B. (1995): Diffusion data for silicate minerals, glasses, and liquids. In A Handbook of Physical Constants. Am. Geophys. Union, Reference Shelf 2: Mineral Physics and Crystallography (269-290).
16. BÜTTNER, S.H. (2005): Deformation-controlled cation diffusion in compositionally zoned tourmaline. Mineral. Mag. 69, 471-489.
17. BOTTNER, S.H. & KASEMANN, S.A. (2007): Deformationcontrolled cation diffusion in tourmaline: a microanalytical study on trace elements and boron isotopes. Am. Mineral. 92, 1862-1874.
18. CADY, W.G. (1930): Electroelastic and pyroelectric phenomena. In International Critical Tables. McGraw-Hill, New York, N.Y (207-212).
19. CHAUSSIDON, M. & ALBARÉDE, F. (1992): Secular boron isotope variations in the continental crust: an ion microprobe study. Earth Planet. Sci. Lett. 108, 229-241.
20. CHEN, CHANG-HWA, DEPAOLO, D.J. & LAN, CHING-YING (1996): Rb-Sr microchrons in the Manaslu granite: implications for Himalayan thermochronology. Earth Planet. Sci. Lett. 143, 125-135.
21. 3F, a new mineral species of the tourmaline group from the Crabtree emerald mine, Mitchell County, North Carolina: description and crystal structure. Can. Mineral. 49, 57-62.
22. COLOPIETRO, M.R. & FRIBERG, L.M. (1987): Tourmaline-biotite as a potential geothermometer for metapelites, Black Hills, South Dakota. Geol. Soc. Am., Abstr. Programs 19, 624.
23. DEKSISSA, D.J. & KOEBERL, C. (2002): Geochemistry and petrography of gold - quartz - tourmaline veins of the Okote area, southern Ethiopia: implications for gold exploration. Mineral. Petrol. 75, 101-122.
24. DESBOIS, G. & INGRIN, J. (2007): Anisotropy of hydrogen diffusion in tourmaline. Geochim. Cosmochim. Acta 71, 5233-5243.
25. DIETRICH, R. V (1985): The Tourmaline Group. Van Nostrand Reinhold Co. Inc., New York, N.Y
26. DOMMANGET, A., MILÉSI, J.-P. & DIALLO, M. (1993): The Loulo gold and tourmaline-bearing deposit. Mineral. Deposita 28, 253-263.
27. DONNAY, G. (1977): Structural mechanisms of pyroelectricity in tourmaline. Acta Crystallogr. A33, 927-932.
28. DUTROW, B.L., FOSTER, C.T, JR. & HENRY, D.J. (1999): Tourmaline-rich pseudomorphs in sillimanite zone metapelites: demarcation of an infiltration front. Am. Mineral. 84, 794-805.
29. ERTL, A., DRAGRANITS, E., GRASEMANN, B., NTAFLOS, T., GIESTER, G. & TILLMANS, E. (2011): Synkinematic growth of tourmaline in brittle-ductile normal faults, Despotiko Island, Aegean Sea, Greece. Can. Mineral. 49, 105-116.
30. ERTL, A., KOLITSCH, U., PROWATKE, S., DYAR, M.D. & HENRY, D.J. (2006): The F-analogue of schorl from Grasstein, Trentino - South Tyrol, Italy: crystal structure and chemistry. Eur. J. Mineral. 18, 583-588.
31. ERTL, A., MARSCHALL, H.R., GIESTER, G., HENRY, D.J., SCHERTL, H.-P, NTAFLOS, T, LUVIZOTTO, G.L., NASDALA, L. & TlLLMANNS, E. (2010): Metamorphic ultrahigh-pressure tourmaline: structure, chemistry, and correlation to P-T conditions. Am. Mineral. 95, 1-10.
32. ERTL, A., TILLMANNS, E., NTAFLOS, T., FRANCIS, C., GIESTER, G., KÖRNER, W., HUGHES, J.M., LENGAUER, C. & PREM, M. (2008): Tetrahedrally coordinated boron in Al-rich tourmaline and its relationship to the pressure-temperature conditions of formation. Eur. J. Mineral. 20, 881-888.
33. FAURE, G. (1986): Principles of Isotope Geology (second ed.). John Wiley & Sons, New York, N.Y.
34. FORD, W.E. & DANA, E.S. (1932): A Textbook of Mineralogy (fourth ed.). John Wiley & Sons, New York, N.Y.
35. FOSTER, G.L., POGGE VON STRANDMANN, P.A.E. & RAE, J.W.B. (2010): Boron and magnesium isotopic composition of seawater. Geochem. Geophys. Geosys. 11, Q08015.
36. GAROFALO, P., AUDÉTAT, A., GÜNTHER, D., HEINRICH, C.A. & RIDLEY, J. (2000): Estimation and testing of standard molar thermodynamic properties of tourmaline end-members using data of natural samples. Am. Mineral. 85, 78-88.
37. GREW, E.S. (1996): Borosilicates (exclusive of tourmaline) and boron in rock-forming minerals in metamorphic environments. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 387-502.
38. GRICE, J.D. & ERCIT, T.S. (1993): Ordering of Fe and Mg in the tourmaline crystal structure: the correct formula. Neues Jahrb. Mineral, Abh. 165, 245-266.
39. GRICE, J.D., ERCIT, T.S. & HAWTHORNE, F.C. (1993): Povondraite, a redefinition of the tourmaline ferridravite. Am. Mineral. 78, 433-436.
40. Guo, JIBAO & QIAN, YAQIAN (1997): Hydrogen isotope fractionation and hydrogen diffusion in the tourmaline-water system. Geochim. Cosmochim. Acta 61, 4679-4688.
41. HAWTHORNE, F.C. (2002): Bond-valence constraints on the chemical composition of tourmaline. Can. Mineral. 40, 789-797.
42. HAWTHORNE, F.C. & HENRY, D.J. (1999): Classification of the minerals of the tourmaline group. Eur. J. Mineral. 11, 201-215.
43. HEMINGWAY, B.S., EVANS, H.T., MAZDAB, F.K. & ANOVITZ, L.M. (1996): Thermal expansion of some borate and borosilicate minerals (fluoborite, danburite, sinhalite, datolite, elbaite, dravite, kornerupine, dumortierite, ferro-axinite, and manganaxinite) between 25 and about 1200°C U.S. Geol. Surv., Open File Rep. 96-100.
44. HENRY, D.J. & DUTROW, B.L. (1996): Metamorphic tourmaline and its petrologic applications. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 503-557.
45. HENRY, D.J. & DUTROW, B.L. (2001): Compositional zoning and element partitioning in nickeloan tourmaline from a metamorphosed karstbauxite from Samos, Greece. Am. Mineral. 80, 1130-1142.
46. HENRY, D.J. & DUTROW, B.L. (2011): The incorporation of fluorine in tourmaline: internal crystallographic controls or external environmental influences? Can. Mineral. 49, 41-56.
47. HENRY, D.J. & GUIDOTTI, C.V. (1985): Tourmaline as a petrogenetic indicator mineral: an example from the staurolitegrade metapelites of NW Maine. Am. Mineral. 70, 1-15.
48. HENRY, D.J., KIRKLAND, B.L. & KIRKLAND, D.W. (1999): Sector-zoned tourmaline from the cap rock of a salt dome. Eur. J. Mineral. 11, 263-280.
49. HENRY, D.J., NOVÁK, M., HAWTHORNE, F.C., ERTL, A., DUTROW, B.L, UHER, P. & PEZZOTTA, F. (2011): Nomenclature of the tourmaline supergroup minerals. Am. Mineral. 96.
50. HEZEL, D.C., KALT, A., MARSCHALL, H.R., LUDWIG, T. & MEYER, H.-P. (2011): Major element and Li, Be compositional evolution of tourmaline in an S-type granite-pegmatite system and its country rocks: an example from the island of Ikaria, Aegean Sea, Greece. Can. Mineral. 49 (in press).
51. HOLTZ, F. & JOHANNES, W (1991): Effect of tourmaline on melt fraction and composition of first melts in quartzofeldspathic gneiss. Eur. J. Mineral. 3, 527-536.
52. HUGHES, J.M., ERTL, A., DYAR, M.D., GREW, E.S., SHEARER, C.K., YATES, M.G. & GUIDOTTI, C.V. (2000): Tetrahedrally coordinated boron in a tourmaline: boron-rich olenite from Stoffshutte, Koralpe, Austria. Can. Mineral. 38, 861-868.
53. HUGHES, J.M., RAKOVAN, J., ERTL, A., ROSSMAN, G.R., BAKSHEEV, I. & BERNHARDT H.-J. (2011): Dissymmetrization in tourmaline: the atomic arrangement of sectorally zoned triclinic Ni-bearing dravite. Can. Mineral. 49, 29-40.
54. JIANG, SHAO YONG (1998): Stable and radiogenic isotope studies of tourmaline: an overview. J. Czech Geol. Soc. 43, 75-90.
55. JIANG, SHAO-YONG & PALMER, M.R. (1998): Boron isotope systematics of tourmaline from granites and pegmatites: a synthesis. Eur. J. Mineral. 10, 1253-1265.
56. JOLLIFF, B.L., PAPIKE, J.J. & SHEARER, C.K. (1986): Tourmaline as a recorder of pegmatite evolution: Bob Ingersoll pegmatite, Black Hills, South Dakota. Am. Mineral. 71, 472-500.
57. KASEMANN, S., ERZINGER J. & FRANZ, G. (2000): Boron cycling in the continental crust of the central Andes from the Paleozoic to Mesozoic, NW Argentina. Contrib. Mineral. Petrol. 140, 328-343.
58. KAWAKAMI, T. (2001): Boron depletion controlled by the breakdown of tourmaline in the migmatite zone of the Aoyama area, Ryoke metamorphic belt, southwestern Japan. Can. Mineral. 39, 1529-1546.
59. KAWAKAMI, T. (2004): Tourmaline and boron as indicators of the presence, segregation and extraction of melt in pelitic migmatites: examples from the Ryoke metamorphic belt, SW Japan. Trans. R. Soc. Edinburgh: Earth Sci. 95, 111-123.
60. KAWAKAMI, T. & IKEDA, T. (2003): Boron in metapelites controlled by the breakdown of tourmaline and retrograde formation of borosilicates in the Yanai area, Ryoke metamorphic belt, SW Japan. Contrib. Mineral. Petrol. 145, 131-150.
61. KELLER, P., RODA ROBLES, E., PESQUERA PÉREZ, A. & FONTÁN, F. (1999): Chemistry, paragenesis and significance of tourmaline in pegmatites of the Southern Tin Belt, central Namibia. Chem. Geol. 158, 203-225.
62. KLEMME, S., MARSCHALL, H.R., JACOB, D.E., PROWATKE, S. & LUDWIG, T. (2011): Trace- element partitioning and boron isotope fractionation between white mica and tourmaline. Can. Mineral. 49, 165-176.
63. 39Ar dating of tourmaline from metamorphic rocks of the Kokchetav Massif, Kazachstán. Dokl. Earth Sci. 424, 168-170.
64. KROSSE, S. (1995): Hochdrucksynthese, Stabilität und Eigenschaften der Borsilikate Dravit und Kornerupln, sowie Darstellung und Stabilitätsverhalten eines neuen Mg-Alborates. Thesis, Ruhr- Universität Bochum, Germany.
65. KUSNÍR, I. (1999): Gold in Mali. Acta Montan. Slovaca 4, 311-318.
66. KUYUNKO, N.S., SEMENOV, YU. V., GUREVICH, V.M., KUZ'MIN, V.l., TOPOR, N.D. & GORBUNOV, V.E. (1984): Experimental determination of thermodynamic properties of tourmaline dravite. Geokhimiya 10, 1458-1465 (in Russian).
67. LANG, S.B. (1974): Sourcebook of Pyroelectricity (Ferroelectricity and Related Phenomena). Gordon & Breach Science, London, U.K.
68. LANG, S.B. (2005): Pyroelectricity: from ancient curiosity to modern imaging tool. Phys. Today 58, 31-36.
69. LEEMAN, W.P. & SISSON, V.B. (1996): Geochemistry of boron and its implications for the crustal and mantle processes. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 645-708.
70. LONDON, D. (2011): Experimental synthesis and stability of tourmaline: a historical perspective. Can. Mineral. 49, 117-136.
71. LONDON, D., MORGAN, G.B., VI & WOLF, M.B. (1996): Boron in granitic rocks and their contact aureoles. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 299-330.
72. LONGFELLOW, K.M. & SWANSON, S.E. (2011): Skeletal tourmaline, undercooling, and crystallization history of the Stone Mountain granite, Georgia, U.S.A. Can. Mineral. 49, 341-357.
73. 27Al MAS NMR spectroscopy. Can. Mineral. 49, 63-88.
74. LUSSIER, A.J. & HAWTHORNE, F.C. (2011): Oscillatory zoned liddicoatite from Anjanabonoina, central Madagascar. II. Compositional variation and mechanisms of substitution. Can. Mineral. 49, 89-104.
75. MAROCCHI, M., MARSCHALL, H.R., KONZETT, J., TROPPER, P., LUDWIG, T., MAIR, V & BARGOSSI, G.M. (2011): Metasomatic tourmaline in hybrid contact-bands between gneiss and peridotite in the Ulten Zone of the Eastern Italian Alps: chemistry and boron isotopic composition. Can. Mineral. 49, 245-261.
76. MARSCHALL, H.R., ALTHERR, R., KALT, A. & LUDWIG, T. (2008): Detrital, metamorphic and metasomatic tourmaline in high-pressure metasediments from Syros (Greece): intra-grain boron isotope patterns determined by secondary-ion mass spectrometry. Contrib. Mineral. Petrol. 155, 703-717.
77. MARSCHALL, H.R., ERTL, A., HUGHES, J.M. & McCAMMON, C (2004): Metamorphic Na- and OH-rich disordered dravite with tetrahedral boron, associated with omphacite, from Syros, Greece: chemistry and structure. Eur. J. Mineral. 16, 817-823.
78. MARSCHALL, H.R., KORSAKOV, A.V., LUVIZOTTO, G.L., NASDALA, L. & LUDWIG, T. (2009a): On the occurrence and boron isotopic composition of tourmaline in (ultra) high-pressure metamorphic rocks. J. Geol. Soc. London 166, 811-823.
79. MARSCHALL H.R. & LUDWIG, T. (2006): Re-examination of the boron isotopic composition of tourmaline from the Lavicky granite, Czech Republic, by secondary ion mass spectrometry: back to normal. Geochem. J. 40, 631-638.
80. MARSCHALL, H.R., LUDWIG, T, ALTHERR, R., KALT, A. & TONARINI, S. (2006): Syros metasomatic tourmaline: evidence for very high-8 B fluids in subduction zones. J. Petrol. 47, 1915-1942.
81. MARSCHALL, H.R., MEYER, C., WUNDER, B., LUDWIG, T. & HEINRICH, W. (2009b): Experimental boron-isotope fractionation between tourmaline and fluid: confirmation from in-situ analyses by secondary-ion mass spectrometry and from Rayleigh fractionation modelling. Contrib. Mineral. Petrol. 158, 675-681.
82. MEYER C., WUNDER, B., MEIXNER, A., ROMER, R.L. & HEINRICH, W. (2008): Boron-isotope fractionation between tourmaline and fluid: an experimental re-investigation. Contrib. Mineral. Petrol. 156, 259-267.
83. MOORE, J.N., CHRISTENSON, B.W., ALLIS, R.G., BROWNE, P.R.L. & LUTZ, S.J. (2004): The mineralogical consequences and behavior of descending acid-sulfate waters: an example from the Karaha - Telaga Bodas geothermal system, Indonesia. Can. Mineral. 42, 1483-1499.
84. MORGAN, G.B., VI & LONDON, D. (1989): Experimental reactions of amphibolite with boron-bearing aqueous fluids at 200 MPa: implications for tourmaline stability and partial melting in mafic rocks. Contrib. Mineral. Petrol. 102, 281-297.
85. NAKANO, T. & NAKAMURA, E. (2001): Boron isotope geochemistry of metasedimentary rocks and tourmalines in a subduction zone metamorphic suite. Phys. Earth Planet. Int. 127, 233-252.
86. NASCIMENTO, M.S., GÓES, A.M., MACAMBIRA, M.J.B. & BROD, JA. (2007): Provenance of Albian sandstones in the São Luis - Grajad Basin (northern Brazil) from evidence of Pb-Pb zircon ages, mineral chemistry of tourmaline and palaeocurrent data. Sed. Geol. 201, 21-42.
87. NOVAK, M., HENRY, D.J., HAWTHORNE, F.C., ERTL, A., UHER, P., DUTROW, B. & PEZZOTTA, F. (2009): Nomenclature of the tourmaline-group minerals. Report of the Subcommittee on Tourmaline Nomenclature to the International Mineralogical Association's Commission on New Minerals, Nomenclature and Classification.
88. NOVAK, M., ŠKODA, R., FILIP, J., MACEK, I. & VACULOVIČ, T. (2011): Compositional trends in tourmaline from intragranitic NYF pegmatites of the Třebíč pluton, Czech Republic: an electron microprobe, Mössbauer and LA-ICP-MS study. Can. Mineral. 49, 359-380.
89. OGORODOVA, L.P., MELCHAKOVA, L.V, KISELEVA, I.A. & PERETYAZHKO, I.S. (2004): Thermodynamics of nalural tourmaline elbaite. Thermochim. Acta 419, 211-214.
90. OTA, T., KOBAYASHI, K., KATSURA, T. & NAKAMURA, E. (2008a): Tourmaline breakdown in a pelitic system: implications for boron cycling through subduction zones. Contrib. Mineral. Petrol. 155, 19-32.
91. OTA, T, KOBAYASHI, K., KUNIHIRO, T. & NAKAMURA, E. (2008b): Boron cycling by subducted lithosphère; insights from diamondiferous tourmaline from the Kokchetav ultrahigh-pressure metamorphic belt. Geochim. Cosmochim.Acta 72, 3531-3541.
92. PALMER, M.R. & SLACK, J.F. (1989): Boron isotopic composition of tourmaline from massive sulfide deposits and tourmalinites. Contrib. Mineral. Petrol. 103, 434-451.
93. PALMER, M.R. & SWIHART, G.H. (1996): Boron isotope geochemistry: an overview. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 709-744.
94. PASSCHIER, C.W. & TROUW, R.A.J. (2005): Microtectonics (second ed.). Springer-Verlag, Berlin, Germany.
95. PIECZKA, A. & KRACZKA, J. (2004): Oxidized tourmalines - a combined chemical, XRD and Mössbauer study. Eur. J. Mineral. 16, 309-321.
96. ROBBINS, CR. & YODER, H.S., JR. (1962): Stability relations of dravite, a tourmaline. Carnegie Inst. Wash. Yearbook 61, 106-108.
97. RODA-ROBLES, E., PESQUERA, A., GIL-CRESPO, P.P. & TORRESRUIZ, J. (2011): Occurrence, paragenesis and compositional evolution of tourmaline from the Tormes Dome area, Central Iberian Zone, Spain. Can. Mineral. 49, 207-224.
98. RUSTEMEYER, P. (2003): Faszination Turmalin: Formen, Farben, Strukturen. Spektrum Akademischer Verlag, Heidelberg, Germany.
99. SCHERTL, H-.P, SCHREYER, W. & CHOPIN C. (1991): The pyrope-coesite rocks and their country rocks at Parigi, Dora Maira Massif, western Alps: detailed petrography, mineral chemistry and PT-path. Contrib. Mineral. Petrol. 108, 1-21.
100. SELWAY, J.B., ČERNÝ, P. & HAWTHORNE, F.C. (2000): The Tanco pegmatite at Bernic Lake, Manitoba. XIV Internal tourmaline. Can. Mineral. 38, 877-891.
101. SELWAY, J.B., NOVAK, M., ČERNÝ, P. & HAWTHORNE, F. (1999): Compositional evolution of tourmaline in lepidolitesubtype pegmatites. Eur. J. Mineral. 11, 569-584. (Pubitemid 29432181)
102. SHELLEY, D. (1992): Igneous and Metamorphic Rocks under the Microscope. Classification, Textures, Microstructures and Mineral Preferred Orientation. Chapman & Hall, London, U.K.
103. SIMMONS, W.B., FALSTER, A.U. & LAURS, B.M. (2011): A survey of Mn-rich yellow tourmaline from worldwide localities and implications for pegmatite petrogenesis. Can. Mineral. 49, 301-319.
104. SLACK, J. F. (1996): Tourmaline associations with hydrothermal ore deposits. In Boron: Mineralogy, Petrology and Geochemistry (E.S. Grew & L.M. Anovitz, eds.). Rev. Mineral. 33, 559-644.
105. SLACK, J.F, PALMER, M.R., STEVENS, B.P. & BARNES, R.G. (1993): Origin and significance of tourmaline-rich rocks in the Broken Hill district, Australia. Econ. Geol. 88, 505-541.
106. SPERLICH, R. (1990): Zoning and Crystal Chemistry of Tourmalines in Prograde Metamorphic Sequences of the Central Alps. Ph.D. thesis, Univ. of Basel, Basel, Switzerland.
107. SPERLICH, R., GIERÉ, R. & FREY, M. (1996): Evolution of compositional polarity and zoning in tourmaline during prograde metamorphism of sedimentary rocks in the Swiss Central Alps. Am. Mineral. 81, 1222-1236.
108. SPICER, E.M., STEVENS, G. & BUICK, I.S. (2004): The low-pressure partial-melting behaviour of natural boron-bearing metapelites from the Mt. Stafford area, central Australia. Contrib. Mineral. Petrol. 148, 160-179.
109. SWIHART, G.H. & MOORE, RB. (1989): A reconnaissance of the boron isotopic composition of tourmaline. Geochim. Cosmochim. Acta 53, 911-916.
110. TATLI, A. & PAVLOVIC, A.S. (1988): Thermal expansion of tourmaline single crystals from 80 to 300 K. Phys. Rev. B 38, 10072-10074.
111. THOMSON, J.A. (2006): A rare garnet - tourmaline - sillimanite - biotite - ilmenite - quartz assemblage from the granulitefacies region of south-central Massachusetts. Am. Mineral. 91, 1730-1738.
112. TROGER, W.E. (1971): Optische Bestimmung der gesteinbildenden Minerale. 1. Bestimmungstabellen (fourth ed.). E. Schweizerbart'sche Verlagsbuchhandlung, Stuttgart, Germany.
113. TRUMBULL, R.B., SLACK, J.F., KRIENITZ, M.-S., BELKIN, H.E. & WIEDENBECK, M. (2011): Fluid sources and metallogenesis in the Blackbird Co-Cu-Au-Bi-Y-REE district, Idaho, U.S.A.: insights from major-element and boron isotopic compositions of tourmaline. Can. Mineral. 49, 225-244.
114. VAN HINSBERG, VJ. (2011): Preliminary experimental data on trace-element partitioning between tourmaline and silicate melt. Can. Mineral. 49, 153-163.
115. VAN HINSBERG, V.J. & MARSCHALL, H.R. (2007): Boron isotope and light element sector zoning in tourmaline: implications for he formation of B-isotopic signatures. Chem. Geol. 238, 141-148.
116. VAN HINSBERG, V.J. & SCHUMACHER, J.C. (2007): Intersector element partitioning in tourmaline: a potentially powerful single crystal thermometer. Contrib. Mineral. Petrol. 153, 289-301.
117. VAN HINSBERG, V.J. & SCHUMACHER, J.C. (2009a): Using estimated thermodynamic properties to model accessory phases: the case of tourmaline. J. Metamorph. Geol. 25, 769-779.
118. VAN HINSBERG, V.J. & SCHUMACHER, J.C. (2009b): The geothermobarometric potential of tourmaline, based on experimental and natural data. Am. Mineral. 94, 761-770.
119. VAN HINSBERG, V.J. & SCHUMACHER, J.C. (2011): Tourmaline as a petrogenetic indicator mineral in the Haut-Allier metamorphic suite, Massif Central, France. Can. Mineral. 49, 177-194.
120. VAN HINSBERG, V.J., SCHUMACHER, J.C., KEARNS, S., MASON, P.R.D. & FRANZ, G. (2006): Hourglass sector zoning in metamorphic tourmaline and resultant major and traceelement fractionation. Am. Mineral. 91, 717-728.
121. VOLL, G. (1969): Klastische Mineralien aus den Sedimentserien der Schottischen Highlands und ihr Schiksal bei aufsteigender Regional- und Kontaktmetamorphose. Habilitations These, Technische Universität Berlin, Germany.
122. VON GOERNE, G., FRANZ, G. & WIRTH, R. (1999): Hydrothermal synthesis of large dravite crystals by the chamber method. Eur. J. Mineral. 11, 1061-1078.
123. 2OHCl. Mineral. Petrol. 69, 161-182.
124. 2O-HCl and the distribution of Na between tourmaline and fluid at 300 to 700°C and 100 MPa. Contrib. Mineral. Petrol. 141, 160-173.
125. 2O. Can. Mineral. 49, 137-152.
126. WADOSKI, E.R., GREW, E.S. & YATES, M.G. (2011): Compositional evolution of tourmaline-supergroup minerals from granitic pegmatites in the Larsemann Hills, East Antarctica. Can. Mineral. 49, 381-405.
127. WILLIAMSON, B.J., SPRATT, J., ADAMS, J.T., TINDLE, A.G. & STANLEY, C.J. (2000): Geochemical constraints from zoned hydrothermal tourmalines on fluid evolution and Sn mineralization: an example from fault breccias at Roche, SW England. J. Petrol. 41, 1439-1453.
128. WOLF, M.B. & LONDON, D. (1997): Boron in granitic magmas: stability of tourmaline in equilibrium with biotite and cordierite. Contrib. Mineral. Petrol. 130, 12-30.
129. XAVIER, R.P., WIEDENBECK, M., TRUMBULL, R.B., DEHER, A.M., MONTEIRO, L.VS., RHEDE, D., DE ARAÚJO, C.E.G. & TORRESI, I. (2008): Tourmaline B-isotopes fingerprint marine evaporites as the source of high-salinity ore fluids in iron oxide copper-gold deposits, Carajás Mineral Province (Brazil). Geology 36, 743-746.