Pressure dependence of viscosity of rhyolitic melts
Author(s)
Language
English
Obiettivo Specifico
2.3. TTC - Laboratori di chimica e fisica delle rocce
Status
Published
JCR Journal
JCR Journal
Peer review journal
Yes
Journal
Issue/vol(year)
12/73 (2009)
Publisher
Elsevier
Pages (printed)
3680-3693
Date Issued
June 15, 2009
Abstract
Viscosity of silicate melts is a critical property for understanding volcanic and igneous processes in the Earth. We investigate the pressure effect on the viscosity of rhyolitic melts using two methods: indirect viscosity inference from hydrous species reaction in melts using a piston cylinder at pressures up to 2.8 GPa and direct viscosity measurement by parallel-plate creep viscometer in an internally-heated pressure vessel at pressures up to 0.4 GPa. Comparison of viscosities of a rhyolitic melt with 0.8 wt% water at 0.4 GPa shows that both methods give consistent results. In the indirect method, viscosities of hydrous rhyolitic melts were inferred based on the kinetics of hydrous species reaction in the melt upon cooling (i.e., the equivalence of rheologically defined glass transition temperature and chemically defined apparent equilibrium temperature). The cooling experiments were carried out in a piston-cylinder apparatus using hydrous rhyolitic samples with 0.8–4 wt% water. Cooling rates of the kinetic experiments varied from 0.1 K/s to 100 K/s; hence the range of viscosity inferred from this method covers 3 orders of magnitude. The data from this method show that viscosity increases with increasing pressure from 1 GPa to 3 GPa for hydrous rhyolitic melts with water content 0.8 wt% in the high viscosity range. We also measured viscosity of rhyolitic melt with 0.13 wt% water using the parallel-plate viscometer at pressures 0.2 and 0.4 GPa in an internally-heated pressure vessel. The data show that viscosity of rhyolitic melt with 0.13 wt% water decreases with increasing pressure. Combining our new data with literature data, we develop a viscosity model of rhyolitic melts as a function of temperature, pressure and water content.
Sponsors
NSF Grants EAR-0537598 and EAR-0711050
References
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of lead and zinc to 60 kbar. J. Phys. Chem. Solids 34, 631–636.
Ardia P., Giordano D. and Schmidt M. W. (2008) A model for the
viscosity of rhyolite as a function of H2O-content and pressure:
a calibration based on centrifuge piston cylinder experiments.
Geochim. Cosmochim. Acta 72, 6103–6123.
Behrens H. and Jantos N. (2001) The effect of anhydrous
composition on water solubility of granitic melts. Am. Mineral.
86, 14–20.
Behrens H. and Nowak M. (2003) Quantification of H2O speciation
in silicate glasses and melts by IR spectroscopy – in situ
versus quench techniques. Phase Trans. 76, 45–61.
Behrens H. and Schulze F. (2003) Pressure dependence of melt
viscosity in the system NaAlSi3O8–CaMgSi2O6. Am. Mineral.
88, 1351–1363.
Behrens H., Zhang Y., Leschik M., Wiedenbeck M., Heide G. and
Frischat G. H. (2007) Molecular H2O as carrier for oxygen
diffusion in hydrous silicate melts. Earth Planet. Sci. Lett. 254,
69–76.
Bottinga Y. and Weill D. F. (1972) The viscosity of magmatic
silicate liquids: a model for calculation. Am. J. Sci. 272, 438–
475.
Dingwell D. B. (1986) Viscosity–temperature relationships in the
system Na2Si2O5–Na4Al2O5. Geochim. Cosmochim. Acta 50,
1261–1265.
Dingwell D. B. (1998) Melt viscosity and diffusion under elevated
pressures. Rev. Mineral. 37, 397–422.
Dingwell D. B. and Webb S. L. (1990) Relaxation in silicate melts.
Eur. J. Mineral. 2, 427–449.
Dorfman A., Dingwell D. B. and Bagdassarov N. S. (1997) A
rotating autoclave for centrifuge studies: falling sphere viscometry.
Eur. J. Mineral. 9, 345–350.
Friedman I., Long W. and Smith R. L. (1963) Viscosity and water
content of rhyolitic glass. J. Geophys. Res. 68, 6523–6535.
Funakoshi K.-i., Suzuki A. and Terasaki H. (2002) In situ viscosity
measurements of albite melt under high pressure. J. Phys.:
Condens. Matter 14, 11343–11347.
Girodano D., Romano C., Dingwell D. B., Poe B. and Behrens H.
(2004) The combined effects of water and fluorine on the viscosity
of silicic magmas. Geochim. Cosmochim. Acta 68, 5159–5168.
Hess K.-U. and Dingwell D. B. (1996) Viscosities if hydrous
leucogranitic melts: a non-Arrhenian model. Am. Mineral. 81,
1297–1300.
Hui H. and Zhang Y. (2007) Toward a general viscosity equation
for natural anhydrous and hydrous silicate melts. Geochim.
Cosmochim. Acta 71, 403–416.
Hui H., Zhang Y., Xu Z. and Behrens H. (2008) Pressure
dependence of the speciation of dissolved water in rhyolitic
melts. Geochim. Cosmochim. Acta 72, 3229–3240.
Hummel W. and Arndt J. (1985) Variation of viscosity with
temperature and composition in the plagioclase system. Contrib.
Mineral. Petrol. 90, 83–92.
Ihinger P. D., Zhang Y. and Stolper E. M. (1999) The speciation of
dissolved water in rhyolitic melt. Geochim. Cosmochim. Acta 63,
3567–3578.
Kanzaki M., Kurita K., Fujii T., Kato T., Shimomura O. and
Akimoto S. (1987) A new technique to measure the viscosity
and density of silicate melts at high pressure. In High-Pressure
Research in Mineral Physics, vol. 39 (eds. M. H. Manghnani
and Y. Syono). Geophysical Monograph, pp. 195–200.
Kushiro I. (1976) Changes in viscosity and structure of melt of
NaAlSi2O6 composition at high pressures. J. Geophys. Res. 81,
6347–6350.
Kushiro I. (1978) Density and viscosity of hydrous calc-alkalic
andesite magma at high pressures. Carnegie Inst. Washington
Year Book 77, 675–677.
Kushiro I., Yoder, Jr., H. S. and Myson B. O. (1976) Viscosities of
basalt and andesite melts at high pressures. J. Geophys. Res. 81,
6351–6356.
Lange R. A. (1994) The effect of H2O, CO2 and F on the density
and viscosity of silicate melts. Rev. Mineral. 30, 331–365.
Lees J. and Williamson B. H. J. (1965) Combined very high
pressure/high temperature calibration of the tetrahedral anvil
apparatus, fusion curves of zinc, aluminium, germanium and
silicon to 60 kilobars. Nature 208, 278–279.
Liebske C., Behrens H., Holtz F. and Lange R. A. (2003) The
influence of pressure and composition on the viscosity of
andesitic melts. Geochim. Cosmochim. Acta 67, 473–485.
Liebske C., Schmickler B., Terasaki H., Poe B. T., Suzuki A.,
Funakoshi K.-i., Ando R. and Rubie D. C. (2005) Viscosity of
peridotite liquid up to 13 GPa: implications for magma ocean
viscosities. Earth Planet. Sci. Lett. 240, 589–604.
Lillie H. R. (1931) Viscosity of glass between the strain point and
melting temperature. J. Am. Ceram. Soc. 14, 502–512.
Liu Y. and Zhang Y. (2000) Bubble growth in rhyolitic melt. Earth
Planet. Sci. Lett. 181, 251–264.
Moynihan C. T., Easteal A. J., Wilder J. and Tucker J. (1976)
Dependence of the glass transition temperature on heating and
cooling rate. J. Phys. Chem. 78, 2673–2677.
Neuville D. R. and Richet P. (1991) Viscosity and mixing in molten
(Ca, Mg) pyroxenes and garnets. Geochim. Cosmochim. Acta
55, 1011–1019.
Neuville D. R., Courtial P., Dingwell D. B. and Richet P. (1993)
Thermodynamic and rheological properties of rhyolite and
andesite melts. Contrib. Mineral. Petrol. 113, 572–581.
Newman S., Stolper E. M. and Epstein S. (1986) Measurement of
water in rhyolitic glasses: calibration of an infrared spectroscopic
technique. Am. Mineral. 71, 1527–1541.
Ni H. and Zhang Y. (2008) H2O diffusion models in rhyolitic melt
with new high pressure data. Chem. Geol. 250, 68–78.
Rapp R. P. and Watson E. B. (1995) Dehydration melting of
metabasalt at 8–32 kbar: implications for continental growth
and crust–mantle recycling. J. Petrol. 36, 891–931.
Reid J. E., Suzuki A., Funakoshi K., Terasaki H., Poe B. T., Rubie
D. C. and Ohtani E. (2003) The viscosity of CaMgSi2O6 liquid
at pressures up to 13 GPa. Phys. Earth Planet. Inter. 139, 45–54.
Rosenhauer M., Scarfe C. M. and Virgo D. (1979) Pressure
dependence of the glass transition temperature in glasses of
diopside, albite, and sodium trisilicate composition. Carnegie
Inst. Washington Year Book 78, 556–559.
Scarfe C. M. and Cronin D. J. (1986) Viscosity–temperature
relationships at 1 atm in the system diopside–albite. Am.
Mineral. 71, 767–771.
Scarfe C. M., Mysen B. O. and Virgo D. (1979) Changes in
viscosity and density of melts of sodium disilicate, sodium
metasilicate, and diopside composition with pressure. Carnegie
Inst. Washington Year Book 78, 547–551.
Scarfe C. M., Mysen B. O. and Virgo D. (1987) Pressure
dependence of the viscosity of silicate melts. In Magmatic
Processes: Physicochemical Principles. Geochem. Soc. Spec.
Pub. (ed. B.O. Mysen), vol. 1. pp. 59–67.
Scherer G. W. (1984) Use of the Adam–Gibbs equation in the
analysis of structural relaxation. J. Am. Ceram. Soc. 67, 504–
511.
Schulze F., Behrens H. and Hurkuck W. (1999) Determination of
the influence of pressure and dissolved water on the viscosity of
highly viscous melts: application of a new parallel-plate
viscometer. Am. Mineral. 84, 1512–1520.
Schulze F., Behrens H., Holtz F., Roux J. and Johannes W. (1996)
The influence of H2O on the viscosity of a haplogranitic melt.
Am. Mineral. 81, 1155–1165.
Shaw H. R. (1963) Obsidian-H2O viscosities at 1000 and 2000 bars
in the temperature range 700 to 900 C. J. Geophys. Res. 68,
6337–6343.
Shaw H. R. (1972) Viscosities of magmatic silicate liquids: an
empirical method of prediction. Am. J. Sci. 272, 870–893.
Silver L. A., Ihinger P. D. and Stolper E. (1990) The influence of
bulk composition on the speciation of water in silicate glasses.
Contrib. Mineral. Petrol. 104, 142–162.
Sipp A. and Richet P. (2002) Equivalence of volume, enthalpy and
viscosity relaxation kinetics in glass-forming silicate liquids. J.
Non-Cryst. Solids 298, 202–212.
Stevenson R. J., Dingwell D. B., Webb S. L. and Bagdassarov N. S.
(1995) The equivalence of enthalpy and shear stress relaxation
in rhyolitic obsidians and quantification of the liquid–glass
transition in volcanic processes. J. Volcanol. Geotherm. Res. 68,
297–306.
Stolper E. M. (1982a) The speciation of water in silicate melts.
Geochim. Cosmochim. Acta 46, 2609–2620.
Stolper E. M. (1982b) Water in silicate glasses: an infrared
spectroscopic study. Contrib. Mineral. Petrol. 81, 1–17.
Sylvester P. J. (1998) Post-collisional strongly peraluminous
granites. Lithos 45, 29–44.
Tinker D., Lesher C. E., Baxter G. M., Uchida T. and Wang Y.
(2004) High-pressure viscometry of polymerized silicate melts
and limitations of the Eyring equation. Am. Mineral. 89, 1701–
1708.
Toplis M. J., Gottsmann J., Knoche R. and Dingwell D. B. (2001)
Heat capacities of haplogranitic glasses and liquids. Geochim.
Cosmochim. Acta 65, 1985–1994.
Whittington A., Richet P. and Holtz F. (2000) Water and the
viscosity of depolymerized aluminosilicate melts. Geochim.
Cosmochim. Acta 64, 3725–3736.
Withers A. C. and Behrens H. (1999) Temperature-induced
changes in the NIR spectra of hydrous albitic and rhyolitic
glasses between 300 and 100 K. Phys. Chem. Miner. 27, 119–
132.
Zhang Y. (1994) Reaction kinetics, geospeedometry, and relaxation
theory. Earth Planet. Sci. Lett. 122, 373–391.
Zhang Y. (1999) H2O in rhyolitic glasses and melts: measurement,
speciation, solubility, and diffusion. Rev. Geophys. 37, 493–516.
Zhang Y. and Behrens H. (2000) H2O diffusion in rhyolitic melts
and glasses. Chem. Geol. 169, 243–262.
Zhang Y., Belcher R., Ihinger P. D., Wang L., Xu Z. and Newman
S. (1997a) New calibration of infrared measurement of
dissolved water in rhyolitic glasses. Geochim. Cosmochim. Acta
61, 3089–3100.
Zhang Y., Jenkins J. and Xu Z. (1997b) Kinetics of the reaction
H2O + O = 2OH in rhyolitic glasses upon cooling: geospeedometry
and comparison with glass transition. Geochim. Cosmochim.
Acta 61, 2167–2173.
Zhang Y., Stolper E. M. and Ihinger P. D. (1995) Kinetics of the
reaction H2O + O = 2OH in rhyolitic and albitic glasses:
Preliminary results. Am. Mineral. 80, 593–612.
Zhang Y., Stolper E. M. and Wasserburg G. J. (1991) Diffusion of
water in the rhyolitic glasses. Geochim. Cosmochim. Acta 55,
441–456.
Zhang Y. and Xu Z. (2007) A long-duration experiment on
hydrous species geospeedometer and hydrous melt viscosity.
Geochim. Cosmochim. Acta 71, 5226–5232.
Zhang Y., Xu Z. and Behrens H. (2000) Hydrous species
geospeedometer in rhyolite: improved calibration and
applications. Geochim. Cosmochim. Acta 64, 3347–
3355.
Zhang Y., Xu Z. and Liu Y. (2003) Viscosity of hydrous rhyolitic
melts inferred from kinetic experiments, and a new viscosity
model. Am. Mineral. 88, 1741–1752.
of lead and zinc to 60 kbar. J. Phys. Chem. Solids 34, 631–636.
Ardia P., Giordano D. and Schmidt M. W. (2008) A model for the
viscosity of rhyolite as a function of H2O-content and pressure:
a calibration based on centrifuge piston cylinder experiments.
Geochim. Cosmochim. Acta 72, 6103–6123.
Behrens H. and Jantos N. (2001) The effect of anhydrous
composition on water solubility of granitic melts. Am. Mineral.
86, 14–20.
Behrens H. and Nowak M. (2003) Quantification of H2O speciation
in silicate glasses and melts by IR spectroscopy – in situ
versus quench techniques. Phase Trans. 76, 45–61.
Behrens H. and Schulze F. (2003) Pressure dependence of melt
viscosity in the system NaAlSi3O8–CaMgSi2O6. Am. Mineral.
88, 1351–1363.
Behrens H., Zhang Y., Leschik M., Wiedenbeck M., Heide G. and
Frischat G. H. (2007) Molecular H2O as carrier for oxygen
diffusion in hydrous silicate melts. Earth Planet. Sci. Lett. 254,
69–76.
Bottinga Y. and Weill D. F. (1972) The viscosity of magmatic
silicate liquids: a model for calculation. Am. J. Sci. 272, 438–
475.
Dingwell D. B. (1986) Viscosity–temperature relationships in the
system Na2Si2O5–Na4Al2O5. Geochim. Cosmochim. Acta 50,
1261–1265.
Dingwell D. B. (1998) Melt viscosity and diffusion under elevated
pressures. Rev. Mineral. 37, 397–422.
Dingwell D. B. and Webb S. L. (1990) Relaxation in silicate melts.
Eur. J. Mineral. 2, 427–449.
Dorfman A., Dingwell D. B. and Bagdassarov N. S. (1997) A
rotating autoclave for centrifuge studies: falling sphere viscometry.
Eur. J. Mineral. 9, 345–350.
Friedman I., Long W. and Smith R. L. (1963) Viscosity and water
content of rhyolitic glass. J. Geophys. Res. 68, 6523–6535.
Funakoshi K.-i., Suzuki A. and Terasaki H. (2002) In situ viscosity
measurements of albite melt under high pressure. J. Phys.:
Condens. Matter 14, 11343–11347.
Girodano D., Romano C., Dingwell D. B., Poe B. and Behrens H.
(2004) The combined effects of water and fluorine on the viscosity
of silicic magmas. Geochim. Cosmochim. Acta 68, 5159–5168.
Hess K.-U. and Dingwell D. B. (1996) Viscosities if hydrous
leucogranitic melts: a non-Arrhenian model. Am. Mineral. 81,
1297–1300.
Hui H. and Zhang Y. (2007) Toward a general viscosity equation
for natural anhydrous and hydrous silicate melts. Geochim.
Cosmochim. Acta 71, 403–416.
Hui H., Zhang Y., Xu Z. and Behrens H. (2008) Pressure
dependence of the speciation of dissolved water in rhyolitic
melts. Geochim. Cosmochim. Acta 72, 3229–3240.
Hummel W. and Arndt J. (1985) Variation of viscosity with
temperature and composition in the plagioclase system. Contrib.
Mineral. Petrol. 90, 83–92.
Ihinger P. D., Zhang Y. and Stolper E. M. (1999) The speciation of
dissolved water in rhyolitic melt. Geochim. Cosmochim. Acta 63,
3567–3578.
Kanzaki M., Kurita K., Fujii T., Kato T., Shimomura O. and
Akimoto S. (1987) A new technique to measure the viscosity
and density of silicate melts at high pressure. In High-Pressure
Research in Mineral Physics, vol. 39 (eds. M. H. Manghnani
and Y. Syono). Geophysical Monograph, pp. 195–200.
Kushiro I. (1976) Changes in viscosity and structure of melt of
NaAlSi2O6 composition at high pressures. J. Geophys. Res. 81,
6347–6350.
Kushiro I. (1978) Density and viscosity of hydrous calc-alkalic
andesite magma at high pressures. Carnegie Inst. Washington
Year Book 77, 675–677.
Kushiro I., Yoder, Jr., H. S. and Myson B. O. (1976) Viscosities of
basalt and andesite melts at high pressures. J. Geophys. Res. 81,
6351–6356.
Lange R. A. (1994) The effect of H2O, CO2 and F on the density
and viscosity of silicate melts. Rev. Mineral. 30, 331–365.
Lees J. and Williamson B. H. J. (1965) Combined very high
pressure/high temperature calibration of the tetrahedral anvil
apparatus, fusion curves of zinc, aluminium, germanium and
silicon to 60 kilobars. Nature 208, 278–279.
Liebske C., Behrens H., Holtz F. and Lange R. A. (2003) The
influence of pressure and composition on the viscosity of
andesitic melts. Geochim. Cosmochim. Acta 67, 473–485.
Liebske C., Schmickler B., Terasaki H., Poe B. T., Suzuki A.,
Funakoshi K.-i., Ando R. and Rubie D. C. (2005) Viscosity of
peridotite liquid up to 13 GPa: implications for magma ocean
viscosities. Earth Planet. Sci. Lett. 240, 589–604.
Lillie H. R. (1931) Viscosity of glass between the strain point and
melting temperature. J. Am. Ceram. Soc. 14, 502–512.
Liu Y. and Zhang Y. (2000) Bubble growth in rhyolitic melt. Earth
Planet. Sci. Lett. 181, 251–264.
Moynihan C. T., Easteal A. J., Wilder J. and Tucker J. (1976)
Dependence of the glass transition temperature on heating and
cooling rate. J. Phys. Chem. 78, 2673–2677.
Neuville D. R. and Richet P. (1991) Viscosity and mixing in molten
(Ca, Mg) pyroxenes and garnets. Geochim. Cosmochim. Acta
55, 1011–1019.
Neuville D. R., Courtial P., Dingwell D. B. and Richet P. (1993)
Thermodynamic and rheological properties of rhyolite and
andesite melts. Contrib. Mineral. Petrol. 113, 572–581.
Newman S., Stolper E. M. and Epstein S. (1986) Measurement of
water in rhyolitic glasses: calibration of an infrared spectroscopic
technique. Am. Mineral. 71, 1527–1541.
Ni H. and Zhang Y. (2008) H2O diffusion models in rhyolitic melt
with new high pressure data. Chem. Geol. 250, 68–78.
Rapp R. P. and Watson E. B. (1995) Dehydration melting of
metabasalt at 8–32 kbar: implications for continental growth
and crust–mantle recycling. J. Petrol. 36, 891–931.
Reid J. E., Suzuki A., Funakoshi K., Terasaki H., Poe B. T., Rubie
D. C. and Ohtani E. (2003) The viscosity of CaMgSi2O6 liquid
at pressures up to 13 GPa. Phys. Earth Planet. Inter. 139, 45–54.
Rosenhauer M., Scarfe C. M. and Virgo D. (1979) Pressure
dependence of the glass transition temperature in glasses of
diopside, albite, and sodium trisilicate composition. Carnegie
Inst. Washington Year Book 78, 556–559.
Scarfe C. M. and Cronin D. J. (1986) Viscosity–temperature
relationships at 1 atm in the system diopside–albite. Am.
Mineral. 71, 767–771.
Scarfe C. M., Mysen B. O. and Virgo D. (1979) Changes in
viscosity and density of melts of sodium disilicate, sodium
metasilicate, and diopside composition with pressure. Carnegie
Inst. Washington Year Book 78, 547–551.
Scarfe C. M., Mysen B. O. and Virgo D. (1987) Pressure
dependence of the viscosity of silicate melts. In Magmatic
Processes: Physicochemical Principles. Geochem. Soc. Spec.
Pub. (ed. B.O. Mysen), vol. 1. pp. 59–67.
Scherer G. W. (1984) Use of the Adam–Gibbs equation in the
analysis of structural relaxation. J. Am. Ceram. Soc. 67, 504–
511.
Schulze F., Behrens H. and Hurkuck W. (1999) Determination of
the influence of pressure and dissolved water on the viscosity of
highly viscous melts: application of a new parallel-plate
viscometer. Am. Mineral. 84, 1512–1520.
Schulze F., Behrens H., Holtz F., Roux J. and Johannes W. (1996)
The influence of H2O on the viscosity of a haplogranitic melt.
Am. Mineral. 81, 1155–1165.
Shaw H. R. (1963) Obsidian-H2O viscosities at 1000 and 2000 bars
in the temperature range 700 to 900 C. J. Geophys. Res. 68,
6337–6343.
Shaw H. R. (1972) Viscosities of magmatic silicate liquids: an
empirical method of prediction. Am. J. Sci. 272, 870–893.
Silver L. A., Ihinger P. D. and Stolper E. (1990) The influence of
bulk composition on the speciation of water in silicate glasses.
Contrib. Mineral. Petrol. 104, 142–162.
Sipp A. and Richet P. (2002) Equivalence of volume, enthalpy and
viscosity relaxation kinetics in glass-forming silicate liquids. J.
Non-Cryst. Solids 298, 202–212.
Stevenson R. J., Dingwell D. B., Webb S. L. and Bagdassarov N. S.
(1995) The equivalence of enthalpy and shear stress relaxation
in rhyolitic obsidians and quantification of the liquid–glass
transition in volcanic processes. J. Volcanol. Geotherm. Res. 68,
297–306.
Stolper E. M. (1982a) The speciation of water in silicate melts.
Geochim. Cosmochim. Acta 46, 2609–2620.
Stolper E. M. (1982b) Water in silicate glasses: an infrared
spectroscopic study. Contrib. Mineral. Petrol. 81, 1–17.
Sylvester P. J. (1998) Post-collisional strongly peraluminous
granites. Lithos 45, 29–44.
Tinker D., Lesher C. E., Baxter G. M., Uchida T. and Wang Y.
(2004) High-pressure viscometry of polymerized silicate melts
and limitations of the Eyring equation. Am. Mineral. 89, 1701–
1708.
Toplis M. J., Gottsmann J., Knoche R. and Dingwell D. B. (2001)
Heat capacities of haplogranitic glasses and liquids. Geochim.
Cosmochim. Acta 65, 1985–1994.
Whittington A., Richet P. and Holtz F. (2000) Water and the
viscosity of depolymerized aluminosilicate melts. Geochim.
Cosmochim. Acta 64, 3725–3736.
Withers A. C. and Behrens H. (1999) Temperature-induced
changes in the NIR spectra of hydrous albitic and rhyolitic
glasses between 300 and 100 K. Phys. Chem. Miner. 27, 119–
132.
Zhang Y. (1994) Reaction kinetics, geospeedometry, and relaxation
theory. Earth Planet. Sci. Lett. 122, 373–391.
Zhang Y. (1999) H2O in rhyolitic glasses and melts: measurement,
speciation, solubility, and diffusion. Rev. Geophys. 37, 493–516.
Zhang Y. and Behrens H. (2000) H2O diffusion in rhyolitic melts
and glasses. Chem. Geol. 169, 243–262.
Zhang Y., Belcher R., Ihinger P. D., Wang L., Xu Z. and Newman
S. (1997a) New calibration of infrared measurement of
dissolved water in rhyolitic glasses. Geochim. Cosmochim. Acta
61, 3089–3100.
Zhang Y., Jenkins J. and Xu Z. (1997b) Kinetics of the reaction
H2O + O = 2OH in rhyolitic glasses upon cooling: geospeedometry
and comparison with glass transition. Geochim. Cosmochim.
Acta 61, 2167–2173.
Zhang Y., Stolper E. M. and Ihinger P. D. (1995) Kinetics of the
reaction H2O + O = 2OH in rhyolitic and albitic glasses:
Preliminary results. Am. Mineral. 80, 593–612.
Zhang Y., Stolper E. M. and Wasserburg G. J. (1991) Diffusion of
water in the rhyolitic glasses. Geochim. Cosmochim. Acta 55,
441–456.
Zhang Y. and Xu Z. (2007) A long-duration experiment on
hydrous species geospeedometer and hydrous melt viscosity.
Geochim. Cosmochim. Acta 71, 5226–5232.
Zhang Y., Xu Z. and Behrens H. (2000) Hydrous species
geospeedometer in rhyolite: improved calibration and
applications. Geochim. Cosmochim. Acta 64, 3347–
3355.
Zhang Y., Xu Z. and Liu Y. (2003) Viscosity of hydrous rhyolitic
melts inferred from kinetic experiments, and a new viscosity
model. Am. Mineral. 88, 1741–1752.
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