Alphabetical Listing for Ringwoodite
Updated 1Aug-2023 by GR Rossman
2000s
- Bolfan-Casanova N, Keppler H, Rubie DC (2000) Water
partitioning between nominally anhydrous minerals in the MgO-SiO2-H2O
system up to 24 GPa: implications for the distribution of water in the
Earth's mantle. Earth and Planetary Science Letters 182, 209-221.
-
Kleppe AK, Jephcoat AP, SMyth JR, Frost DJ (2002) On protons, iron and
the high-pressure behavior of ringwoodite. Geophysical Research
Letters 29, 17.
- Hertweck B, Ingrin J (2005) Hydrogen incorporation in a ringwoodite analogue:: Mg2GeO4 spinel. Mineralogical Magazine 69, 337-343.
- Blanchard
M, Balan E, Wright K (2009) Incorporation of water in iron-free
ringwoodite: A first-principles study. American Mineralogist 84, 83-89,
- Taran MN, Koch-Muller M, Wirth R, Abs-Wurmbach I,
Rhede D, Greshae A (2009) Spectroscopic studies of synthetic and
natural ringwoodite, gamma-(Mg, Fe)2SiO4. Physics and Chemistry Minerals
(2009) 36, 217–232.
2010s - Ganskow
G, Ballaran T, Langenhorst F (2010) Effect of iron on the
compressibility of hydrous ringwoodite. American Mineralogist
95, 747–753,
- Koch-Müller M, Rhede D (2010) IR absorption
coefficients for water in nominally anhydrous high-pressure minerals.
American Mineralogis, 770–775.
- Koch-Müller M,
Speziale S, Deon F, Mrosko M, Schade U (2011) Stress-induced proton
disorder in hydrous ringwoodite. Physics and Chemistry of minerals
38, 65-73.
- Mrosko
M, Lenz S, McCammon CA, Tran M, Wirth R, Koch-Müller M (2013) Hydrogen
incorporation and the oxidation state of iron in ringwoodite: A
spectroscopic study. American Mineralogist 99, 629-636.
- Panero
WR, Smyth JR, Pigott JS, Liu Z, Frost DJ (2013) Hydrous
ringwoodite to 5 K and 35 GPa: Multiple hydrogen bonding sites resolved
with FTIR spectroscopy. American Mineralogist 98, 637–642.
- Pearson
D, Brenker F, Nestola F, McNeill J, Nasdala L, Hutchison MT, Matveev S,
Mather K, Silversmit G, Schmitz S, Vekemans B, Vincze L (2014).
Hydrous mantle transition zone indicated byringwoodite included within diamond. Nature 507, 221–224.
- Yang X, Keppler H, Dubrovinsky L, Kurnosov A (2014) In-situ infrared
spectra of hydroxyl in wadsleyite and ringwoodite at high pressure and
high temperature. American Mineralogist 99, 724-729.
- Thomas SM, Jacobsen
SD, Bina CR, Reichart P, Moser M, Hauri EH, Koch-Müller M, Smyth JR, Dollinger G (2015) Quantification of
water in hydrous ringwoodite. Frontiers in Earth Science 2, article 38.
- Bolfan-Casanova N, Schiavi F, Novella D, Bureau H, Raepsaet C, Khodja
H, Demouchy S (2018) Examination of Water Quantification and
Incorporation in Transition Zone Minerals: Wadsleyite,
Ringwoodite and Phase D Using ERDA (Elastic Recoil Detection
Analysis). Frontiers in Earth Science 6, UNSP 75
2020s- Fei
H, Katsura T (2020) High water solubility of ringwoodite at mantle
transition zone temperature. Earth and Planetary Science Letters 531,
115987.
- Thomson
AR, Piltz RO, Crichton WA, Cerantola V, Ezad IS, Dobson DP, Wood IG,
Brodholt JP (2021) Incorporation of tetrahedral ferric iron into
hydrous ringwoodite. American Mineralogist 106, 900-908.
- Jin Y, Huang W, Wang ZP, Sun W, Liu Y, Xia Q, Yang Y (2023)
Behavior of hydrogen defect and framework of Fe-bearing wadsleyite and
ringwoodite at high temperature and high pressure. American
Mineralogist 108, 1232–1241.
- Jin Y, Huang W, Wang ZP, Sun W, Liu Y, Xia Q, Yang Y (2023)
Behavior of hydrogen defect and framework of Fe-bearing wadsleyite and
ringwoodite athigh temperature and high pressure. American Mineralogist 108, 1232-1241.