Skip to Main Content
Skip Nav Destination

Crystal structure of monoclinic hydrous wadsleyite [β-(Mg,Fe)2 SiO4 ]

American Mineralogist (1997) 82 (3-4): 270–275.
This article has been cited by the following articles in journals that are participating in CrossRef Cited-by Linking.
Hydrous wadsleyite crystal structure up to 32 GPa
American Mineralogist (2023) 108 (10): 1948.
Twinning in hydrous wadsleyite: Symmetry relations, origin, and consequences
American Mineralogist (2023) 108 (11): 2096.
Pauling’s rules for oxide-based minerals: A re-examination based on quantum mechanical constraints and modern applications of bond-valence theory to Earth materials
American Mineralogist (2022) 107 (7): 1219.
The Elastic Properties of β-Mg2SiO4 Containing 0.73 wt.% of H2O to 10 GPa and 600 K by Ultrasonic Interferometry with Synchrotron X-Radiation
Minerals (2020) 10 (3): 209.
Fe2+ substitution in coexisting wadsleyite and clinopyroxene under hydrous conditions: implications for the 520-km discontinuity
Physics and Chemistry of Minerals (2020) 47 (1)
Dehydration Melting Below the Undersaturated Transition Zone
Geochemistry, Geophysics, Geosystems (2020) 21 (2)
Study notes on water and magmas in the depths of the Earth
Japanese Magazine of Mineralogical and Petrological Sciences (2018) 47 (1): 13.
High oxide-ion conductivity in Si-deficient La9.565(Si5.826□0.174)O26apatite without interstitial oxygens due to the overbonded channel oxygens
Journal of Materials Chemistry A (2018) 6 (23): 10835.
The equation of state of wadsleyite solid solutions: Constraining the effects of anisotropy and crystal chemistry
American Mineralogist (2017) 102 (12): 2494.
Partial melting of stagnant oceanic lithosphere in the mantle transition zone and its geophysical implications
Lithos (2017) 292-293: 379.
Hydrogen mobility in transition zone silicates
Progress in Earth and Planetary Science (2017) 4 (1)
Quantitative Analysis of Hydrogen Site and Occupancy in a Deep-Earth Hydrous Mineral by Time-of-Flight Single Crystal Laue Neutron Diffraction
Nihon Kessho Gakkaishi (2017) 59 (6): 309.
Quantitative analysis of hydrogen sites and occupancy in deep mantle hydrous wadsleyite using single crystal neutron diffraction
Scientific Reports (2016) 6 (1)
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 (2015) 120 (12): 8259.
Water in the Earth's mantle: a solid-state NMR study of hydrous wadsleyite
Chemical Science (2013) 4 (4): 1523.
Thermodynamic properties of anhydrous and hydrous wadsleyite, β−Mg2SiO4
High Pressure Research (2013) 33 (3): 584.
P wave anisotropic tomography of the Nankai subduction zone in Southwest Japan
Geochemistry, Geophysics, Geosystems (2012) 13 (5)
Olivine–wadsleyite–pyroxene topotaxy: Evidence for coherent nucleation and diffusion-controlled growth at the 410-km discontinuity
Physics of the Earth and Planetary Interiors (2012) 200-201: 85.
Investigation of hydrogen sites of wadsleyite: A neutron diffraction study
Physics of the Earth and Planetary Interiors (2011) 189 (1-2): 56.
Systematic study of hydrogen incorporation into Fe-free wadsleyite
Physics and Chemistry of Minerals (2011) 38 (1): 75.
Behavior of Hydrogen in Crystal Structures of Slab and Mantle Minerals
Nihon Kessho Gakkaishi (2011) 53 (1): 19.
First principles investigation of the structural and elastic properties of hydrous wadsleyite under pressure
Journal of Geophysical Research: Solid Earth (2009) 114 (B2)
Combinatorial modular design of the structures of spinel-type phases
Glass Physics and Chemistry (2008) 34 (4): 401.
Carbonatite and silicate melt metasomatism of the mantle surrounding the Hawaiian plume: Evidence from volatiles, trace elements, and radiogenic isotopes in rejuvenated‐stage lavas from Niihau, Hawaii
Geochemistry, Geophysics, Geosystems (2008) 9 (9)
Single-crystal elasticity of wadsleyites, β-Mg2SiO4, containing 0.37–1.66 wt.% H2O
Earth and Planetary Science Letters (2008) 268 (3-4): 540.
Single-crystal elasticity of wadsleyites, β-Mg2SiO4, containing 0.37–1.66 wt.% H2O
Earth and Planetary Science Letters (2008) 266 (1-2): 78.
High-pressure Raman spectroscopic study of Fo90 hydrous wadsleyite
Physics and Chemistry of Minerals (2006) 32 (10): 700.
WATER, MELTING, AND THE DEEP EARTH H2O CYCLE
Annual Review of Earth and Planetary Sciences (2006) 34 (1): 629.
Element partitioning between transition‐zone minerals and ultramafic melt under hydrous conditions
Geophysical Research Letters (2006) 33 (16)
Storage capacity of H2O in nominally anhydrous minerals in the upper mantle
Earth and Planetary Science Letters (2005) 236 (1-2): 167.
Oxidation state of iron in hydrous mantle phases: implications for subduction and mantle oxygen fugacity
Physics of the Earth and Planetary Interiors (2004) 143-144: 157.
Thermal expansion of wadsleyite, ringwoodite, hydrous wadsleyite and hydrous ringwoodite
Physics of the Earth and Planetary Interiors (2004) 143-144: 279.
Elasticity and strength of hydrous ringwoodite at high pressure
Earth and Planetary Science Letters (2003) 214 (3-4): 645.
The effect of water on the 410‐km discontinuity: An experimental study
Geophysical Research Letters (2002) 29 (10)
Hydrogen in the Deep Earth
Annual Review of Earth and Planetary Sciences (2001) 29 (1): 365.
Stabilities and equations of state of dense hydrous magnesium silicates
Physics of the Earth and Planetary Interiors (2001) 127 (1-4): 181.
Mineral phases of the Earth´s mantle
Zeitschrift für Kristallographie - Crystalline Materials (2001) 216 (5): 248.
Close Modal

or Create an Account

Close Modal
Close Modal