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CO2 solubility measurement and thermodynamic modeling for 1-methylpiperazine/water/CO2

An accurate thermodynamic model is the primary element needed for the process simulation and optimization for CO2 absorption in aqueous amine solutions. In this work, the thermodynamic model was built in Aspen Plus, using the electrolyte nonrandom two-liquid (ENRTL) activity coefficient model to rep...

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Published in:	Fluid phase equilibria 2015-05, Vol.394, p.118-128
Main Authors:	Li, Han, Le Moullec, Yann, Lu, Jiahui, Chen, Jian, Valle Marcos, Jose Carlos, Chen, Guofei, Chopin, Fabrice
Format:	Article
Language:	English
Subjects:	1-Methylpiperazine Amines Carbon dioxide CO2 solubility Computer simulation Enthalpy Excess enthalpy Interaction parameters Mathematical models Solubility Thermodynamic model Thermodynamic models
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cited_by	cdi_FETCH-LOGICAL-c472t-9d7ea948c529fa23ab99506f39196f8fb0724a73fac0b431ab114c9354e1345f3
cites	cdi_FETCH-LOGICAL-c472t-9d7ea948c529fa23ab99506f39196f8fb0724a73fac0b431ab114c9354e1345f3
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creator	Li, Han Le Moullec, Yann Lu, Jiahui Chen, Jian Valle Marcos, Jose Carlos Chen, Guofei Chopin, Fabrice
description	An accurate thermodynamic model is the primary element needed for the process simulation and optimization for CO2 absorption in aqueous amine solutions. In this work, the thermodynamic model was built in Aspen Plus, using the electrolyte nonrandom two-liquid (ENRTL) activity coefficient model to represent vapor pressure and heat capacity data, simultaneously, for amine, vapor–liquid equilibrium (VLE), excess enthalpy (HE), and pKa data for amine/H2O, and CO2 solubility data for amine/CO2/H2O. The cyclic diamine 1-methylpiperazine (1MPZ) is a promising amine for CO2 capture. CO2 solubility was measured for 1MPZ aqueous solutions at three concentrations – 10wt%, 30wt%, and 40wt% and four temperatures – 313.15K, 343.15K, 373.15K, and 393.15K. The excess enthalpy for 1MPZ+H2O was obtained by the Setaram C80 calorimeter at 303.15K and 323.15K, within a whole mole-fraction range. The interaction parameters of nonrandom two-liquid model (NRTL) and ENRTL, along with the standard state properties of amine ions – protonated 1MPZ (1MPZH+, 1MPZH2+), 1MPZ carbamate (1MPZCOO−), and protonated 1MPZ carbamate (H1MPZCOO) – were regressed from data obtained from this work as well as literature, which agreed with the model calculation.
doi_str_mv	10.1016/j.fluid.2015.03.021
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In this work, the thermodynamic model was built in Aspen Plus, using the electrolyte nonrandom two-liquid (ENRTL) activity coefficient model to represent vapor pressure and heat capacity data, simultaneously, for amine, vapor–liquid equilibrium (VLE), excess enthalpy (HE), and pKa data for amine/H2O, and CO2 solubility data for amine/CO2/H2O. The cyclic diamine 1-methylpiperazine (1MPZ) is a promising amine for CO2 capture. CO2 solubility was measured for 1MPZ aqueous solutions at three concentrations – 10wt%, 30wt%, and 40wt% and four temperatures – 313.15K, 343.15K, 373.15K, and 393.15K. The excess enthalpy for 1MPZ+H2O was obtained by the Setaram C80 calorimeter at 303.15K and 323.15K, within a whole mole-fraction range. 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source	ScienceDirect Freedom Collection 2022-2024
subjects	1-Methylpiperazine Amines Carbon dioxide CO2 solubility Computer simulation Enthalpy Excess enthalpy Interaction parameters Mathematical models Solubility Thermodynamic model Thermodynamic models
title	CO2 solubility measurement and thermodynamic modeling for 1-methylpiperazine/water/CO2
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