Ammonia absorption at haber process conditions

Mark S. Huberty; Andrew L. Wagner; Alon Mccormick; Edward Cussler

doi:10.1002/aic.13744

Ammonia absorption at haber process conditions

Mark S. Huberty, Andrew L. Wagner, Alon Mccormick, Edward Cussler

Chemical Engineering and Materials Science

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Abstract

The kinetics of ammonia absorption into magnesium chloride is measured as ammonia pressure change in the temperature range 170-430 ^°C. The actual pressure minus that at equilibrium drops quickly, with a half life of less than a minute. It varies with the square-root of time, suggesting diffusion limited absorption. The diffusion coefficient of ammonia in solid magnesium chloride inferred from these data is on the order 10 ^-11-10 ^-13 cm ²/s, considerably faster than many solid-phase diffusivities. While optical microscopy and BET surface area experiments indicate recrystallization and agglomeration of the absorbent at ammonia synthesis temperatures, the absorption rate remains high. The dependence of absorption rate on temperature, particle size and the presence of a silica support is also investigated. The results suggest both improved ammonia separation and ways to develop high-conversion, small-scale, multifunctional ammonia synthesis reactors. © 2012 American Institute of Chemical Engineers AIChE J, 2012

Original language	English (US)
Pages (from-to)	3526-3532
Number of pages	7
Journal	AIChE Journal
Volume	58
Issue number	11
DOIs	https://doi.org/10.1002/aic.13744
State	Published - Nov 2012

Keywords

Absorption
Diffusion

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title = "Ammonia absorption at haber process conditions",

abstract = "The kinetics of ammonia absorption into magnesium chloride is measured as ammonia pressure change in the temperature range 170-430 °C. The actual pressure minus that at equilibrium drops quickly, with a half life of less than a minute. It varies with the square-root of time, suggesting diffusion limited absorption. The diffusion coefficient of ammonia in solid magnesium chloride inferred from these data is on the order 10 -11-10 -13 cm 2/s, considerably faster than many solid-phase diffusivities. While optical microscopy and BET surface area experiments indicate recrystallization and agglomeration of the absorbent at ammonia synthesis temperatures, the absorption rate remains high. The dependence of absorption rate on temperature, particle size and the presence of a silica support is also investigated. The results suggest both improved ammonia separation and ways to develop high-conversion, small-scale, multifunctional ammonia synthesis reactors. {\textcopyright} 2012 American Institute of Chemical Engineers AIChE J, 2012",

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AU - Huberty, Mark S.

AU - Wagner, Andrew L.

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AU - Cussler, Edward

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N2 - The kinetics of ammonia absorption into magnesium chloride is measured as ammonia pressure change in the temperature range 170-430 °C. The actual pressure minus that at equilibrium drops quickly, with a half life of less than a minute. It varies with the square-root of time, suggesting diffusion limited absorption. The diffusion coefficient of ammonia in solid magnesium chloride inferred from these data is on the order 10 -11-10 -13 cm 2/s, considerably faster than many solid-phase diffusivities. While optical microscopy and BET surface area experiments indicate recrystallization and agglomeration of the absorbent at ammonia synthesis temperatures, the absorption rate remains high. The dependence of absorption rate on temperature, particle size and the presence of a silica support is also investigated. The results suggest both improved ammonia separation and ways to develop high-conversion, small-scale, multifunctional ammonia synthesis reactors. © 2012 American Institute of Chemical Engineers AIChE J, 2012

AB - The kinetics of ammonia absorption into magnesium chloride is measured as ammonia pressure change in the temperature range 170-430 °C. The actual pressure minus that at equilibrium drops quickly, with a half life of less than a minute. It varies with the square-root of time, suggesting diffusion limited absorption. The diffusion coefficient of ammonia in solid magnesium chloride inferred from these data is on the order 10 -11-10 -13 cm 2/s, considerably faster than many solid-phase diffusivities. While optical microscopy and BET surface area experiments indicate recrystallization and agglomeration of the absorbent at ammonia synthesis temperatures, the absorption rate remains high. The dependence of absorption rate on temperature, particle size and the presence of a silica support is also investigated. The results suggest both improved ammonia separation and ways to develop high-conversion, small-scale, multifunctional ammonia synthesis reactors. © 2012 American Institute of Chemical Engineers AIChE J, 2012

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KW - Diffusion

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Ammonia absorption at haber process conditions

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