Tourmaline spectra

The Tourmaline Group

Tourmaline Classification Scheme
(as proposed by Hawthorne and Henry (1999))

Buergerite	NaFe³⁺₃Al₆(BO₃)₃Si₆O₁₈(O)₃(OH)
Chromdravite	NaMg₃Cr₆(BO₃)₃Si₆O₁₈(OH)₄
Dravite	NaMg₃Al₆(BO₃)₃Si₆O₁₈(OH)₄
Elbaite	Na(Li_1.5Al_1.5)Al₆(BO₃)₃Si₆O₁₈(OH)₄
Foitite	[][Fe²⁺₂Al]Al₆(BO₃)₃Si₆O₁₈(OH)₄
Hydroxy-feruvite	CaFe²⁺₃[Al₅Mg](BO₃)₃Si₆O₁₈(OH)₄
Magnesiofoitite	[][Mg₂Al]Al₆(BO₃)₃Si₆O₁₈(OH)₄
Liddicoatite	Ca(Li₂Al)Al₆(BO₃)₃Si₆O₁₈(OH)₃F
Olenite	NaAl₃Al₆(BO₃)₃Si₆O₁₈(O)₃(OH)
Povondraite	NaFe³⁺₃[Fe³⁺₄Mg₂](BO₃)₃Si₆O₁₈(OH)₃O
Rossmanite	[](LiAl₂)Al₆(BO₃)₃Si₆O₁₈(OH)₄
Schorl	NaFe²⁺₃Al₆(BO₃)₃Si₆O₁₈(OH)₄
Uvite	CaMg₃[Al₅Mg](BO₃)₃Si₆O₁₈(OH)₃F

[] in these formulas refers to a vacant cation site (the X site)

Tourmaline colors

The color of tourmaline originates from the metal ions (Fe, Mn, Cr, V, Ti, Cu) in its structure. Colors come both from light absorption by the individual ions (eg, Fe²⁺ or Cr³⁺) and by light absorbed by interactions between ions (eg, Fe²⁺-Ti⁴⁺, Mn²⁺-Ti⁴⁺ or Fe²⁺-Fe³⁺ intervalence charge transfer [IVCT]).

Blue color is usually caused by Fe²⁺ but can also come from Cu²⁺ in rare Brazilian elbaites [spectrum, 7K].

Green color comes from Fe²⁺-Ti⁴⁺ IVCT together with Fe²⁺, or from Cr³⁺ or V³⁺ alone.

Amber to orange-brown colors (often seen in dravites) come from Fe²⁺-Ti⁴⁺ alone.

A greenish yellow color is from Mn²⁺ [Mn-elbaite spectrum 5K].

Pink and red colors are from Mn³⁺. The color of pink manganese-containing tourmalines often is associated with exposure to ionizing radiation (such as from the decay of ⁴⁰K, a common constituent of pegmatites).

Brown to orange-brown colors result from Mn²⁺-Ti⁴⁺ IVCT.

Black tourmalines (schorls (60 cm cluster, Czech Republic), etc.) are dark because of their high concentrations of iron, manganese and titanium. When they are ground very thin, they are usually blue or brownish-green [schorl spectrum, 6K].

Many tourmalines owe their color to a mixture of metal ions. The great diversity of color in tourmalines is due the the variability in which these mixtures occur.

Images of Tourmaline Slices

For images of colorful tourmaline slices and more information about their color go to the section on tourmaline slices .

Images of representative tourmaline spectra

Visible Spectra: polarizations: (a = incident light polarized perpendicular to c-axis; c = parallel to c-axis)

Blue, green, brown and black Fe-containing tourmalines

GRR 512 image, 6K; Schorl, GRR 512, White Queen Mine, Pala, California, 0.010 mm thick. Black in mass, blue when very thin. Contains 13.5% "FeO" and 0.95% "MnO". Data Files: a 0K; c 0K;

GRR 596 image, 6K; Elbaite, GRR 596G, Afghanistan, 0.25 mm thick. Dark green crystal colored by Fe²⁺ and Ti⁴⁺ - Fe²⁺ interactions. Contains 4.32% "FeO", 1.67% "MnO" and 0.04% "TiO₂". Data Files: a 8K ; c 8K ;

GRR 787 image, 5K; Dravite, GRR 787, Sweeney Canyon, Anza Borrego, California, USA, 0.10 mm thick. The black crystal that most people would call schorl is green when thin. The intense absorptions in the perpendicular to c direction at 730 and 1120 nm result from enhancement of Fe²⁺ bands caused by interactions with Fe³⁺. The intense absorption in the same direction near 430 nm is from Fe²⁺ - Ti⁴⁺ intervalence charge transfer. The crystal contains 6.93% "FeO", 0.05% "MnO" and 0.53% "TiO₂". Data Files: a 0K ; c 0K .

GRR 794 image, 5K; Foitite, GRR 794, Schindler Mine, California, USA, 0.048 mm thick. Black crystal, blue when thin. Data Files: a 22 K ; c 22 K .

S3 image, 4K, Dravite, S3, Newry, Maine, USA. Brown to green, complexly zoned. Spectra from a green zone. Contains Mg1.19 Fe1.16 Ti 0.04. Data files: a 0K ; c 0K .

CIT 12683 image, 5K, Dravite, CIT 12683, Yinnietharra, Australia. Brown crystal, 0.680 mm thick. The absorption band near 450 nm arising from Fe²⁺ - Ti⁴⁺ intervalence charge transfer is the primary cause of the color of this crystal. Data files: a 67 K ; c 66 K .

GRR 2098 image; Uvite, GRR 2098, Wata Poore area, Konar Province, Afghanistan. 3.98 mm thick. Pale brown crystal. The color is dominated by the Fe²⁺ - Ti⁴⁺ intervalance charge transfer arising from the minor amounts of both Fe and Ti that are in this crystal. Data Files: a 0K ; c 0K .

S 8 image, 5K; Uvite, S 8, Pierrepont, New York, USA, NMNH 81511, 0.10 mm thick. Black crystal. Contains 8.23% "FeO" and 0.55% "TiO₂". Data Files: a 0K ; c 0K .

Pink and yellow-green Mn-containing tourmalines

GRR 1368 image 5K; dark pink elbaite from Otjimbinque, Namibia. The color is from Mn³⁺ and represents one of the deeper colored natural pink tourmalines.

GRR 565 image 5K; light pink elbaite from the Himalaya Mine, Mesa Grande, California. The color is natural color from Mn³⁺.

GRR 565 image 5K; dark pink elbaite from the Himalaya Mine, Mesa Grande, California. This sample has been irradiated with ⁶⁰Co gamma rays to enhance its color. The color is from Mn³⁺ and represents a typical treated color for pink tourmalines.

GRR 876 image 5K; heavily irradiated pink elbaite from the Stewart Mine, Pala, California. Although the sample has been treated, the color is from Mn³⁺ and resembles the color of natural pink tourmaline.

GRR 757 image, 5K; Yellow-green elbaite, GRR 757, Zambia, 2.00 mm thick, with high Mn²⁺ content. Ref: Rossman & Mattson (1986) Amer. Mineral 71, 599-602. Data Files: a 0K ; c 0K ;

GRR 1932 image, 4K; rossmanite, GRR 1932, Rozná, Czech Republic, 2.976 mm thick. This is a light pink crystal of the type specimen. The color comes from the radiation-induced Mn³⁺ content. Here is the NIR OH region 4K; of the same crystal. Data Files: a 0K ; c 0K ;

Paraib a pink tourmaline. Elbaite, São José da Batalha, Paraíba, Brazil, 1.84 mm thick. Pink crystal colored by both Mn and Cu²⁺. Contributed data from M Taran, Kiev. Data Files: a 14K ; c 14K .

Other colored varieties and species of tourmalines

R030 image, 7K; Elbaite, São José da Batalha, Paraíba, Brazil, 0.20 mm thick. Blue crystal colored by Cu²⁺. Ref: Rossman et al. (1991) Amer. Mineral 76, 1479-1484. Data Files: a 7K ; c 12K .

Back to the list of minerals
Back to the Mineral Spectroscopy home page