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Andersson, Lars Olov (2019) Comments on Beryl Colors and on Other Observations Regarding Iron-containing Beryls. The Canadian Mineralogist, 57 (4) 551-566 doi:10.3749/canmin.1900021

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Reference TypeJournal (article/letter/editorial)
TitleComments on Beryl Colors and on Other Observations Regarding Iron-containing Beryls
JournalThe Canadian Mineralogist
AuthorsAndersson, Lars OlovAuthor
Year2019 (July 15)Volume57
Issue4
PublisherMineralogical Association of Canada
DOIdoi:10.3749/canmin.1900021Search in ResearchGate
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Mindat Ref. ID65583Long-form Identifiermindat:1:5:65583:1
GUID0
Full ReferenceAndersson, Lars Olov (2019) Comments on Beryl Colors and on Other Observations Regarding Iron-containing Beryls. The Canadian Mineralogist, 57 (4) 551-566 doi:10.3749/canmin.1900021
Plain TextAndersson, Lars Olov (2019) Comments on Beryl Colors and on Other Observations Regarding Iron-containing Beryls. The Canadian Mineralogist, 57 (4) 551-566 doi:10.3749/canmin.1900021
In(2019, July) The Canadian Mineralogist Vol. 57 (4) Mineralogical Association of Canada
Abstract/NotesAbstract
Trivalent iron ions substituting for Al3+ are present in many beryls and are abundant in dark red and dark blue beryl. These ions do not contribute any color to the crystals. Dark blue beryl also contains octahedral Fe2+ ions, which are involved in giving the crystal the blue color. The colors of dark red and dark blue beryls are very stable. Tetrahedral iron ions are practically absent in these beryls, but are present in other beryls which change their color upon irradiation and heating. Their colors depend more on the radiation and temperature history of the crystals than on chemistry.
Trivalent iron ions substituting for Si4+ also do not contribute color. Rare observations by EPR (electron paramagnetic resonance) indicate that the charge difference can be compensated either by protons or by alkali ions in the beryl channels. It is shown that about 1% of the Fe3+ ions in dark red beryl substitute for Si4+.
The changing colors of iron-containing beryls have been interpreted in many different ways, but it is likely that they are due to ions substituting for Be2+. The present study suggests that the iron ions do not substitute isomorphically for Be, but that they enter a distorted tetrahedron which consists of one O(1) oxygen and three O(2) oxygens. The center of this T(3) tetrahedron is at (0.432, 0.344, 0.167) in the beryl structure and the distance to the four oxygen ions is 1.84 Ã…, compared to 1.65 Ã… in the Be tetrahedron, thus providing more space for the much larger iron ions. This site is so close to the Be site that both sites cannot be simultaneously occupied. Beryl crystals with Fe2+ ions in T(3) are colorless. Irradiation oxidizes these Fe2+ ions to Fe3+, which gives the beryl a yellow color. The aquamarine color is caused by pairs of Fe2+ and Fe3+ ions in neighboring T(3) tetrahedra. When both configurations are present, the crystal assumes a shade of green, depending on their relative proportion. The electrons released by the irradiation are trapped at sites which are probably associated with water molecules in the beryl channels. These electrons leave the traps upon heating and reduce the Fe3+ ions in the T(3) tetrahedra. The yellow color vanishes and the beryl becomes aquamarine blue. More electrons are released at higher temperatures and reduce both ions of the pairs, leaving the beryl colorless. The oxidation of the iron ions at even higher temperatures is connected with the release of water from the beryl crystal.
A number of small EPR signals in addition to the large signal from octahedral Fe3+ ions in iron-containing beryl crystals are investigated. Many arise from exchanged-coupled Fe3+ ion pairs, and one is related to the yellow color.

Mineral Pages

MineralCitation Details
Aquamarine
Beryl
Raspberyl
Red Beryl

See Also

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Andersson, L. O. (2013) The yellow color center and trapped electrons in beryl. The Canadian Mineralogist, 51 (1) 15-25 doi:10.3749/canmin.51.1.15
Makovicky, Emil, Merlino, Stefano (2019) Order-disorder Twinning of Malachite. The Canadian Mineralogist, 57 (4) 475-488 doi:10.3749/canmin.1900007
Clarke, D. Barrie (2019) The Origins of Strongly Peraluminous Granitoid Rocks. The Canadian Mineralogist, 57 (4) 529-550 doi:10.3749/canmin.1800075
Kigai, Ingrid N. (2019) The genesis of agates and amethyst geodes. The Canadian Mineralogist, 57 (6) 867-883 doi:10.3749/canmin.1900028
Makovicky, Emil (2019) The pseudomalachite-ludjibaite-reichenbachite conundrum: OD description. The Canadian Mineralogist, 57 (5) 571-581 doi:10.3749/canmin.1900016
Henry, Rhiana E., Groat, Lee A., Evans, R. James, Cempírek, Jan, Škoda, Radek (2022) Crystal-Chemical Observations and the Relation Between Sodium and H2O in Different Beryl Varieties. The Canadian Mineralogist, 60 (4) 625-675 doi:10.3749/canmin.2100050
Wang, Xian, Li, Jiankang (2020) In situ observations of the transition between beryl and phenakite in aqueous solutions using a hydrothermal diamond-anvil cell. The Canadian Mineralogist, 58 (6) 803-814 doi:10.3749/canmin.1900104
Wehrle, Elliot A., McDonald, Andrew M. (2019) Cathodoluminescence and trace-element chemistry of quartz from Sudbury offset dikes: Observations, interpretations, and genetic implications. The Canadian Mineralogist, 57 (6) 947-963 doi:10.3749/canmin.1900049
Elliott, Peter, Willis, Anthony C. (2019) Whiteite-(MnMnMg), a new jahnsite-group mineral from Iron Monarch, South Australia: description and crystal structure. The Canadian Mineralogist, 57 (2) 215-223 doi:10.3749/canmin.1800070
Andersson, Lars Olov (2010) EPR investigation of NO2 and CO2 − and other radicals in beryl. Physics and Chemistry of Minerals, 37 (7) 435-451 doi:10.1007/s00269-009-0345-8
Bayliss, Peter (2015) Mineral Nomenclature. The Canadian Mineralogist, 53 (4) 775 doi:10.3749/canmin.4358
 
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