Pseudo-retrograde hydrate phenomena at low pressures

A. L. Ballard; M. D. Jager; Kh Nasrifar; M. M. Mooijer-Van Den Heuvel; C. J. Peters; E. D. Sloan

doi:10.1016/S0378-3812(01)00458-7

Pseudo-retrograde hydrate phenomena at low pressures

A. L. Ballard, M. D. Jager, Kh Nasrifar, M. M. Mooijer-Van Den Heuvel, C. J. Peters, E. D. Sloan^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

A Gibbs free energy minimization technique has been applied to calculating phase equilibria of solid hydrates. The van der Waals and Platteeuw theory was used to predict the fugacity of water in each of the hydrate phases. Model parameters for ethane and propane were optimized to pure and binary incipient hydrate equilibrium data as well as to structural transition points for the ethane+propane+water system.It is usually assumed that hydrates never dissociate with an increase in pressure. Predictions show, however, that for a wide water-free composition range, slight increases in pressure will result in the dissociation of sII hydrates (pseudo-retrograde dissociation). Pressure versus temperature and pressure versus composition phase diagrams for the ethane+propane+water system showed that pseudo-retrograde phenomena exist at low pressures (approximately 10-15atm) near a temperature of 278K. Pseudo-retrograde hydrate behavior was predicted in the ethane+i-butane+water and ethane+propane+decane+water systems as well. Two different experimental methods were used to verify the model predictions for the ethane+propane+water system.

Original language	English
Pages (from-to)	77-87
Number of pages	11
Journal	Fluid Phase Equilibria
Volume	185
Issue number	1-2
DOIs	https://doi.org/10.1016/S0378-3812(01)00458-7
Publication status	Published - Jul 30 2001
Externally published	Yes

Keywords

Data
Gibbs energy
Hydrate
Model
Pseudo-retrograde
Solid-fluid equilibria

ASJC Scopus subject areas

Chemical Engineering(all)
Physics and Astronomy(all)
Physical and Theoretical Chemistry

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10.1016/S0378-3812(01)00458-7

Cite this

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title = "Pseudo-retrograde hydrate phenomena at low pressures",

abstract = "A Gibbs free energy minimization technique has been applied to calculating phase equilibria of solid hydrates. The van der Waals and Platteeuw theory was used to predict the fugacity of water in each of the hydrate phases. Model parameters for ethane and propane were optimized to pure and binary incipient hydrate equilibrium data as well as to structural transition points for the ethane+propane+water system.It is usually assumed that hydrates never dissociate with an increase in pressure. Predictions show, however, that for a wide water-free composition range, slight increases in pressure will result in the dissociation of sII hydrates (pseudo-retrograde dissociation). Pressure versus temperature and pressure versus composition phase diagrams for the ethane+propane+water system showed that pseudo-retrograde phenomena exist at low pressures (approximately 10-15atm) near a temperature of 278K. Pseudo-retrograde hydrate behavior was predicted in the ethane+i-butane+water and ethane+propane+decane+water systems as well. Two different experimental methods were used to verify the model predictions for the ethane+propane+water system.",

keywords = "Data, Gibbs energy, Hydrate, Model, Pseudo-retrograde, Solid-fluid equilibria",

author = "Ballard, {A. L.} and Jager, {M. D.} and Kh Nasrifar and {Mooijer-Van Den Heuvel}, {M. M.} and Peters, {C. J.} and Sloan, {E. D.}",

note = "Funding Information: We would like to thank ARCO for financial support of this project. We would also like to thank Dr. Vu Thieu for fabricating the optical cell used in this study.",

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AU - Ballard, A. L.

AU - Jager, M. D.

AU - Nasrifar, Kh

AU - Mooijer-Van Den Heuvel, M. M.

AU - Peters, C. J.

AU - Sloan, E. D.

N1 - Funding Information: We would like to thank ARCO for financial support of this project. We would also like to thank Dr. Vu Thieu for fabricating the optical cell used in this study.

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Y1 - 2001/7/30

N2 - A Gibbs free energy minimization technique has been applied to calculating phase equilibria of solid hydrates. The van der Waals and Platteeuw theory was used to predict the fugacity of water in each of the hydrate phases. Model parameters for ethane and propane were optimized to pure and binary incipient hydrate equilibrium data as well as to structural transition points for the ethane+propane+water system.It is usually assumed that hydrates never dissociate with an increase in pressure. Predictions show, however, that for a wide water-free composition range, slight increases in pressure will result in the dissociation of sII hydrates (pseudo-retrograde dissociation). Pressure versus temperature and pressure versus composition phase diagrams for the ethane+propane+water system showed that pseudo-retrograde phenomena exist at low pressures (approximately 10-15atm) near a temperature of 278K. Pseudo-retrograde hydrate behavior was predicted in the ethane+i-butane+water and ethane+propane+decane+water systems as well. Two different experimental methods were used to verify the model predictions for the ethane+propane+water system.

AB - A Gibbs free energy minimization technique has been applied to calculating phase equilibria of solid hydrates. The van der Waals and Platteeuw theory was used to predict the fugacity of water in each of the hydrate phases. Model parameters for ethane and propane were optimized to pure and binary incipient hydrate equilibrium data as well as to structural transition points for the ethane+propane+water system.It is usually assumed that hydrates never dissociate with an increase in pressure. Predictions show, however, that for a wide water-free composition range, slight increases in pressure will result in the dissociation of sII hydrates (pseudo-retrograde dissociation). Pressure versus temperature and pressure versus composition phase diagrams for the ethane+propane+water system showed that pseudo-retrograde phenomena exist at low pressures (approximately 10-15atm) near a temperature of 278K. Pseudo-retrograde hydrate behavior was predicted in the ethane+i-butane+water and ethane+propane+decane+water systems as well. Two different experimental methods were used to verify the model predictions for the ethane+propane+water system.

KW - Data

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KW - Model

KW - Pseudo-retrograde

KW - Solid-fluid equilibria

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Pseudo-retrograde hydrate phenomena at low pressures

Abstract

Keywords

ASJC Scopus subject areas

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