H in Wadsleyite

Updated 4-Jul-2023 by GR Rossman

1980s

Smyth JR (1987) beta-Mg₂SiO₄: a potential host for water in the mantle? American Mineralogist 72, 1051–1055.
Downs JW (1989) Possible sites for protonation in beta-Mg₂SiO₄ from an experimentally derived electrostatic potential. American Mineralogist 74, 1124–1129.

1990s

McMillan PF, Akaogi M, Sato RK, Poe B, Foley J (1991) Hydroxyl groups in beta-Mg₂SiO₄. American Mineralogist76: 354–360.
Young TE, Green HW II, Hofmeister AM, Walker D (1993) Infrared spectroscopic investigation of hydroxyl in beta-(Mg,Fe)₂SiO₄ and coexisting olivine: implications for mantle evolution and dynamics. Physics and Chemistry of Mineralals 19, 409–422.
Cynn H, Hofmeister AM (1994) High-pressure IR spectra of lattice modes and OH vibrations in Fe-bearing wadsleyite. Journal of Geophysical Research 99, 17,717–17,727.
Smyth JR (1994) A crystallographic model for hydrous wadsleyite (beta-Mg₂SiO₄): an ocean in the earth's interior? American Mneralogist 79, 1021–1024.
Kohlstedt DL, Keppler H, Rubie DC (1996) Solubility of water in the alpha, beta and gamma phases of (Mg,Fe)₂SiO₄. Contributions to Mineralogy and Petrology 122, 345-357.

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.
Kohn S, Brooker R, Frost D, Slesinger A, Wood B (2002) Ordering hydroxyl defects in hydrous wadsleyite (beta-Mg₂SiO₄). American Mineralogist 87, 293–301.
2002 Smyth The effect of water on the 410-km discontinuity: An experimental study. Geophhysical Research Letters 29, 123, 014418.
Smyth JR, Holl CM, Frost DJ, Jacobsen SD, Langenhorst F, McCammon CA (2003) Structural systematics of hydrous ringwoodite and water in Earth’s interior. American Mineralogiat 88, 402–1407.
Demouchy S, Deloule E, Frost DJ, Keppler H (2005) Pressure and temperature-dependence of water solubility in Fe-free wadsleyite. American Mineralogist 90, 1084–1091.
Jacobsen S D, Demouchy S, Frost DJ, Ballaran TB, Kung J (2005). A systematic study of OH in hydrous wadsleyite from polarized FTIR spectroscopy and single‐crystal X‐ray diffraction: Oxygen sites for hydrogen storage in Earth's interior. American Mineralogist 90, 61–70.
Smyth JR, Holl CM, Langehnorst F, Laustsen HMS, Rossman GR, Kleppe A, McCammon CA, Kawamoto T, van Aken PA (2005) Crystal chemistry of wadsleyite II and water in the Earth’s interior. Phys Chem Min 31, 691-705.
Hae R, Ohtani E, Kubo T, Koyama T, Utada H (2006) Hydrogen diffusivity in wadsleyite and water distribution in the mantle transition zone. Earth and Planetary Science Letters 243, 141-148.

2010-2014

Deon F, Koch-Muller M, Rhede D, Gottschalk M, Wirth R, Thomas SM (2010) Location and quantification of hydroxyl in wadsleyite: New insights. American Mineralogistb 95, 312–322.
Ye Y, Smyth JR, Hushur A, Manghnani MH, Lonappan H, Dera P, Frost DJ (2010) Crystal structure of hydrous wadsleyite with 2.8% H₂O and compressibility to 60 GPa . American Mineralogist 95, 1765-1772.
Litasov DK, Shatskiy A, Ohtani E, Katsura T (2011) Systematic study of hydrogen incorporation into Fe-free wadsleyite. Phys Chem Min 38. 75-84.
Ye Y, Smyth JR, Frost DJ (2011) Structural study of the coherent dehydration of wadsleyite. American Mineralogist 96, 1760–1767.
Bolfan-Casanova N Munoz M, McCmmon C, Deloule E, Ferot A, Demouchy S, France L, Andrault D, Pascarelli S (2012) Ferric iron and water incorporation in wadsleyite under hydrous and oxidizing conditions: A XANES, Mössbauer, and SIMS study. American Mineralogist 97, 1483-1493
Deon F, Kkoch-Muller M, Rhede D, Gottshalk M, Wirth R, Thomas SM (2012) Location and quantification of hydroxyl in wadsleyite: New insights - American Mineralogist 95, 312-322.
Blanchard M, Roberge M, Balan E, Fiquet G, Bureau H (2013) Infrared signatures of OH-defects in wadsleyite: A first-principles study. American Mineralogist 98, 2132-2143.
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

2015-2019

Chang YY, Jacobsen SD, Bina CR, Thomas SM, Smyth JR, Frost DF, Ballaran TB, McCammon CA, Hauri EH, Inoue T, Yurimoto H, Meng Y, Dera P (2015) Comparative compressibility of hydrous wadsleyite and ringwoodite: Effect of H₂O and implications for detecting water in the transition zone. Journal of Geophysical Research - Solid Earth 120, 8250-8280.
Kawazoe T, Chaudhari A, Smyth JR, McCammon C (2016) Coupled substitution of Fe³⁺ and H⁺ for Si in wadsleyite: A study by polarized infrared and Mossbauer spectroscopies and single-crystal X-ray diffraction. American Mineralogist 101, 1236-1239
Moran FR, McKay D, Pickardk CJ, Berry AJ, Griffin JM, Ashbrook SE (2016) Hunting for hydrogen: random structure searching and prediction of NMR parameters of hydrous wadsleyite - Physical Chemical Chemical Physics 18, 10173-10181.
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.
Karato SI (2019) Some remarks on hydrogen-assistedelectrical conductivity in olivine and other minerals.Progress in Earth and Planetary Science 6, 55.

2020-2025

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.