Hydrous species geospeedometer in rhyolite: Improved calibration and application

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Youxue Zhang
  • Zhengjiu Xu
  • Harald Behrens

Research Organisations

External Research Organisations

  • University of Michigan
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Details

Original languageEnglish
Pages (from-to)3347-3355
Number of pages9
JournalGeochimica et cosmochimica acta
Volume64
Issue number19
Publication statusPublished - 1 Oct 2000

Abstract

The hydrous species geospeedometer is based on the homogeneous interconversion reaction between molecular H2O species and OH species in silicate melts and glasses. Here we report new data for the calibration of the geospeedometer in rhyolitic glass, extending the coverage of quench rate to 94 K/s and of H2O(t) to 7.7 wt.% by using a piston-cylinder apparatus at low pressures (200-500 MPa) to prevent bubble growth and to generate high and monitored quench rates. The new experimental data at pressure are highly reproducible and consistent with earlier data at 0.1 MPa, indicating negligible pressure effect on the relation between speciation and quench rate at P ≤ 500 MPa. In order to avoid calibration uncertainties, the original infrared data are used to represent species concentrations and the equilibrium constant. Ā523 and Ā452 (absorbances of the 523 and 452 mm-1 bands in terms of peak height per mm sample thickness) are used to represent concentrations of molecular H2O and OH groups, respectively, and Q' (=Ā4522523) is used to represent the quotient of the species interconversion reaction, since there is rough proportionality between the corresponding parameters (Ā523 and molecular H2O, Ā452 and OH, Q' and the quotient Q). Zhang et al. [Geochim. Cosmochim. Acta 61, 3089-3100 (1997a)] showed that for a given quench rate (q), there is an excellent linear relation between ln Q' and ln(Ā523 + Ā452) when total H2O is ≤3.0%. With new data at higher total H2O, the linear relation does not hold anymore. Furthermore, the new data show that the linear relation between ln Q' and ln q does not hold at high q. Hence, the geospeedometry model of Zhang et al. can be used for interpolation, but extrapolation may lead to large errors. A new geospeedometry model using the combined data set is presented in this work and applied to natural rhyolitic glasses. The new geospeedometer can be used to quantify cooling rates in a quench medium or an experimental apparatus. Furthermore, it can be used to determine the cooling rates of individual pyroclasts, different parts of a lava flow, and melt inclusions in phenocrysts, thus allowing inference of rich details of volcanic processes. Copyright (C) 2000 Elsevier Science Ltd.

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Cite this

Hydrous species geospeedometer in rhyolite: Improved calibration and application. / Zhang, Youxue; Xu, Zhengjiu; Behrens, Harald.
In: Geochimica et cosmochimica acta, Vol. 64, No. 19, 01.10.2000, p. 3347-3355.

Research output: Contribution to journalArticleResearchpeer review

Zhang Y, Xu Z, Behrens H. Hydrous species geospeedometer in rhyolite: Improved calibration and application. Geochimica et cosmochimica acta. 2000 Oct 1;64(19):3347-3355. doi: 10.1016/S0016-7037(00)00424-5
Zhang, Youxue ; Xu, Zhengjiu ; Behrens, Harald. / Hydrous species geospeedometer in rhyolite : Improved calibration and application. In: Geochimica et cosmochimica acta. 2000 ; Vol. 64, No. 19. pp. 3347-3355.
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T1 - Hydrous species geospeedometer in rhyolite

T2 - Improved calibration and application

AU - Zhang, Youxue

AU - Xu, Zhengjiu

AU - Behrens, Harald

N1 - Funding Information: We thank A. T. Anderson, J. Ganguly and an anonymous reviewer for comments, and Raleigh Belcher, Juleen Jenkins, Yang Liu, Heidi Scharich, and Wenbing Yu for the analyses of some of the pyroclasts in Fig. 6 . This research is funded by NSF Grants Nos. EAR-9458368 and EAR-9706107 and German DAAD.

PY - 2000/10/1

Y1 - 2000/10/1

N2 - The hydrous species geospeedometer is based on the homogeneous interconversion reaction between molecular H2O species and OH species in silicate melts and glasses. Here we report new data for the calibration of the geospeedometer in rhyolitic glass, extending the coverage of quench rate to 94 K/s and of H2O(t) to 7.7 wt.% by using a piston-cylinder apparatus at low pressures (200-500 MPa) to prevent bubble growth and to generate high and monitored quench rates. The new experimental data at pressure are highly reproducible and consistent with earlier data at 0.1 MPa, indicating negligible pressure effect on the relation between speciation and quench rate at P ≤ 500 MPa. In order to avoid calibration uncertainties, the original infrared data are used to represent species concentrations and the equilibrium constant. Ā523 and Ā452 (absorbances of the 523 and 452 mm-1 bands in terms of peak height per mm sample thickness) are used to represent concentrations of molecular H2O and OH groups, respectively, and Q' (=Ā4522/Ā523) is used to represent the quotient of the species interconversion reaction, since there is rough proportionality between the corresponding parameters (Ā523 and molecular H2O, Ā452 and OH, Q' and the quotient Q). Zhang et al. [Geochim. Cosmochim. Acta 61, 3089-3100 (1997a)] showed that for a given quench rate (q), there is an excellent linear relation between ln Q' and ln(Ā523 + Ā452) when total H2O is ≤3.0%. With new data at higher total H2O, the linear relation does not hold anymore. Furthermore, the new data show that the linear relation between ln Q' and ln q does not hold at high q. Hence, the geospeedometry model of Zhang et al. can be used for interpolation, but extrapolation may lead to large errors. A new geospeedometry model using the combined data set is presented in this work and applied to natural rhyolitic glasses. The new geospeedometer can be used to quantify cooling rates in a quench medium or an experimental apparatus. Furthermore, it can be used to determine the cooling rates of individual pyroclasts, different parts of a lava flow, and melt inclusions in phenocrysts, thus allowing inference of rich details of volcanic processes. Copyright (C) 2000 Elsevier Science Ltd.

AB - The hydrous species geospeedometer is based on the homogeneous interconversion reaction between molecular H2O species and OH species in silicate melts and glasses. Here we report new data for the calibration of the geospeedometer in rhyolitic glass, extending the coverage of quench rate to 94 K/s and of H2O(t) to 7.7 wt.% by using a piston-cylinder apparatus at low pressures (200-500 MPa) to prevent bubble growth and to generate high and monitored quench rates. The new experimental data at pressure are highly reproducible and consistent with earlier data at 0.1 MPa, indicating negligible pressure effect on the relation between speciation and quench rate at P ≤ 500 MPa. In order to avoid calibration uncertainties, the original infrared data are used to represent species concentrations and the equilibrium constant. Ā523 and Ā452 (absorbances of the 523 and 452 mm-1 bands in terms of peak height per mm sample thickness) are used to represent concentrations of molecular H2O and OH groups, respectively, and Q' (=Ā4522/Ā523) is used to represent the quotient of the species interconversion reaction, since there is rough proportionality between the corresponding parameters (Ā523 and molecular H2O, Ā452 and OH, Q' and the quotient Q). Zhang et al. [Geochim. Cosmochim. Acta 61, 3089-3100 (1997a)] showed that for a given quench rate (q), there is an excellent linear relation between ln Q' and ln(Ā523 + Ā452) when total H2O is ≤3.0%. With new data at higher total H2O, the linear relation does not hold anymore. Furthermore, the new data show that the linear relation between ln Q' and ln q does not hold at high q. Hence, the geospeedometry model of Zhang et al. can be used for interpolation, but extrapolation may lead to large errors. A new geospeedometry model using the combined data set is presented in this work and applied to natural rhyolitic glasses. The new geospeedometer can be used to quantify cooling rates in a quench medium or an experimental apparatus. Furthermore, it can be used to determine the cooling rates of individual pyroclasts, different parts of a lava flow, and melt inclusions in phenocrysts, thus allowing inference of rich details of volcanic processes. Copyright (C) 2000 Elsevier Science Ltd.

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