Transport of oxygen in silicate glasses

“…The similar H 2 O-dD negative correlation was also found in clinopyroxene megacryst and ascribed to diffusive H loss during magma ascent to the surface (e.g., Newman et al, 1988). While in principle the H-rich fluid diffuses much faster than the Drich fluid, it is more possible that molecular H 2 O diffuses faster than the structural OH (e.g., Zhang et al, 1991;Doremus, 2004). Thus, the observed H isotope variations in the two CCSD-MH core segments may be principally caused by the preferential loss of molecular H 2 O from garnet and omphacite during the exhumation of deeply subducted continental crust.…”

Origin of retrograde fluid in ultrahigh-pressure metamorphic rocks: Constraints from mineral hydrogen isotope and water content changes in eclogite–gneiss transitions in the Sulu orogen

“…The similar H 2 O-dD negative correlation was also found in clinopyroxene megacryst and ascribed to diffusive H loss during magma ascent to the surface (e.g., Newman et al, 1988). While in principle the H-rich fluid diffuses much faster than the Drich fluid, it is more possible that molecular H 2 O diffuses faster than the structural OH (e.g., Zhang et al, 1991;Doremus, 2004). Thus, the observed H isotope variations in the two CCSD-MH core segments may be principally caused by the preferential loss of molecular H 2 O from garnet and omphacite during the exhumation of deeply subducted continental crust.…”

Origin of retrograde fluid in ultrahigh-pressure metamorphic rocks: Constraints from mineral hydrogen isotope and water content changes in eclogite–gneiss transitions in the Sulu orogen

“…This observation indicates that there are two types of mobile oxygen species whose properties are largely different. The 18 O-rich layer near the outer surface has been believed to be formed by the diffusion of the network oxygen; however, recent reports have indicated the importance of residual water in determining the 18 O profile [5,30]. In contrast, the oxygen flow that forms the interface 18 O-rich layer has been attributed to interstitial oxygen species, which migrate thorough interstitial voids without extensive interactions with the Si-O network [6,[30][31][32].…”

Diffusion and reactions of interstitial oxygen species in amorphous SiO2: A review

“…The diffusion of interstitial O 2 in a-SiO 2 can be regarded basically as permeation [3][4][5][6][7][8][9][10], however, exchange between interstitial O 2 and oxygen atoms in the a-SiO 2 network also takes place, particularly at high temperatures [11][12][13][14][15]. The activation energy for the oxygen exchange is~2 eV [13][14][15] and is much larger than that of the permeation (diffusion) of interstitial O 2 (~0.8-1.2 eV [3,8,9,[16][17][18]).…”

Oxygen-excess amorphous SiO2 with 18O-labeled interstitial oxygen molecules