THEORETICAL STUDY OF CO<sub>2</sub>:N<sub>2</sub> ADSORPTION IN FAUJASITE IMPREGNATED WITH MONOETHANOLAMINE

Lima, A. E. O.; Gomes, V. A. M.; Lucena, S. M. P.

doi:10.1590/0104-6632.20150323s00003450

Abstract

Many efforts have been made to develop amine-based solid adsorbents for capture of CO₂ by adsorption. Compared with the traditional process of absorption in aqueous solutions of amines, the adsorbents with amine immobilized in solids generally result in processes with lower capital and energy costs. The literature contains some experimental studies of CO₂ adsorption in impregnated materials; however, few studies are devoted to the theoretical interpretation of this system in terms of CO₂ capture for post-combustion (N₂ mixture with a low partial pressure of CO₂). Therefore, this study investigates the adsorption of a CO₂:N₂ mixture on zeolite NaX impregnated with monoethanolamine (MEA), using molecular simulation. A model of NaX impregnated with MEA was proposed and the adsorption of a 15:85 (CO₂:N₂) mixture was investigated based on the Monte Carlo method. The simulation of the MEA impregnated zeolite at 25 ˚C predicted higher CO₂ selectivity and significant improvement in the heat of adsorption. Unfortunately, the adsorption heat improvement did not translate into corresponding increases in the amount of adsorbed CO₂. Moreover, MEA concentrations higher than 12 wt% hindered the adsorption of CO₂ molecules. An explanation for the results in terms of occupied volumes and interaction energies is presented.

Keywords:
Molecular simulation; CO₂ adsorption; Faujasite; Monoethanolamine

INTRODUCTION

Among the greenhouse gases, CO₂ emission can contribute significantly to global warming. CO₂ is currently the focus of several studies, where goals are directed towards enhancement of efficient processes for their capture. CO₂ absorption using amines is a mature technology and has proven efficient for CO₂ capture (Rochelle, 2009Rochelle, G. T., Amine scrubbing for CO2 capture. Science, 325, 1652-1654 (2009).), despite being limited by high cost and technical problems such as a high equipment corrosion rate (Knudsen et al., 2009Knudsen, J. N., Jensen, J. N., Vilhelmsen, P. J., Biede, O., Experience with CO2 capture from coal flue gas in pilot-scale: Testing of different amine solvents. Energy Procedia, 1, 783-790 (2009).). Thus, many capture processes have been studied; among these, adsorption is a very promising technology (Samantha et al., 2012Samantha, A., Zhao, A., Shimizu, G. K. H., Sarkar, P., Gupta, R., Post-combustion CO2 capture using solid sorbents: A review. Industrial & Engineering Chemistry Research, 51, 1438-1463 (2012).). In a post-combustion scenario, the technological challenge is to capture CO₂ at low pressure in flue gas (< 1 atm) and rich exhaust streams in N₂ (~ 85%). For this purpose, NaX zeolite is one of the best adsorbing material in the literature. However, it has poor performance for CO₂ capture via adsorption at higher temperatures, since the effect of physisorption is predominant. Recent studies have focused on chemical modifications of faujasites with the immobilization of amino groups to enhance adsorption capacity, especially at elevated temperatures (Sayari et al., 2011Sayari, A., Belmabkhout, Y., Serna-Guerrero, R., Flue gas treatment via CO2 adsorption. Chem. Eng. J., 171, 760-774 (2011).). This approach attempts to optimize the experimental conditions for impregnation in order to achieve higher levels of adsorption of CO₂ and CO₂:N₂ selectivity. Thus, the aim of this study is to perform a theoretical study of selective adsorption of CO₂ on plain NaX sieve and NaX impregnated with monoethanolamine (MEA) in operating conditions of pressure and concentrations similar to the post-combustion operation.

METHODOLOGY

Intermolecular Interactions

The interactions between the adsorbate molecules and the adsorbent (solid-fluid) and between molecules of adsorbate (fluid-fluid) were modeled with a Lennard-Jones 12-6 potential (LJ), which takes into account geometric (σ_ij) and energy (ε_ij) parameters. The contributions of electrostatic interactions are also accounted for in the calculation of the total energy of the system (U_ij), as shown in Equation (1).

where r_ij is the distance between two interacting species and q the partial charge of the atoms. The Lorenz-Berthelot simple mixing rules were used to calculate the interspecies parameters.

Faujasite

The NaX model was based on the crystallographic data reported by Zhu and Seff (1999)Zhu, L., Seff, K., Reinvestigation of the crystal structure of dehydrated sodium zeolite X. Journal of Physical Chemistry, B, 103, 9512-9518 (1999).. NaX crystallizes in the cubic space group Fd3m with acell size parameter of 25.077 Å. The zeolite framework was built avoiding Al-O-Al connections in accordance with Lowenstein's rule. The positioning of the compensating Na⁺ cations was randomly distributed (32 in site I', 32 in site II and 28 in site III). Then, six cations were removed at random from site III to give a Si/Al ratio = 1.23. As done previously (Maurin et al., 2005Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).; Watanabe et al., 1995Watanabe, K., Austin, N. and Stapleton, M. R., Investigation of the air separation properties of zeolites types A, X and Y by Monte Carlo simulations. Molecular Simulation, 15, 197-221 (1995).; Garcia-Sanchez et al., 2009Garcıa-Sanchez, A., Ania, C. O., Parra, J. B., Dub-beldam, D., Vlugt, T. J. H., Krishna, R. and Calero, S., Transferable force field for carbon dioxide adsorption in zeolites. J. Phys. Chem. C, 113, 88148820 (2009).), the sodalite volume was blocked with large "dummy" atoms, preventing the adsorption in this region. The gas molecules adsorb only in the supercages that have a 12-ring window access with 7.4 Å of aperture. The sodalite unit can only be accessed by 6-rings windows of about 2.53 Å of diameter, which restricts the access of the gas molecules (Baerlocher et al. 2007Baerlocher, C., McCusker, L. B. and Olson, D. H., Atlas of Zeolites Framework Types. Sixth Revised Editon, Elsevier, Amsterdan (2007).). The NaX unit cell detailing cation positioning, supercage and sodalite cages is shown in Figure 1.

Figure 1
(a) NaX unit cell. (b) Hexagonal prism detailing supercage (S) and the sodalite cavity (sod). Atoms: Si - yellow, Al - pink, O- red. Cations colors: SI' and SII - Purple, SIII - Green. Big gray spheres dummy atom.

The distribution of partial charges was obtained by the electronegativity equalization method (Rappe and Goddard, 1991Rappe, A. K., Goddard, W. A. Charge equilibration for molecular dynamics simulations. J. Phys. Chem., 95, 3358-3363 (1991).). The simulation parameters were extracted from the Universal Force Field (Rappe et al., 1992Rappe, A. K., Casewit, C. J., Colwell, K. S., Goddard, W. A., Skiff, W. M., UFF, A Full Periodic-Table Force-Field for Molecular Mechanics and Molecular - Dynamics Simulations. Journal of the American Chemical Society, 114, 10024-10035 (1992).) and other parameters were adjusted empirically to best represent the experimental data. The parameters are shown in Table 1.

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Table 1
Force field parameters for the NaX zeolite.

Monoethanolamine

The model for MEA follows the molecular geometry and charges proposed by Alejandre et al. (2000)Alejandre, J., Rivera, J. L., Mora, M. A., Garza, V., Force field of monoethanolamine. Journal of Physical Chemistry B, 104, 1332-1337 (2000). with bond lengths and angles similar to experimental spectroscopic measurements. The force field developed by Button et al. (1996)Button, J. K., Gubbins, K. E., Tanaka, H., Nakanishi, K., Molecular dynamics simulation of hydrogen bonding in monoethanolamine. Fluid Phase Equilibria, 116, 320-325 (1996). was used (Table 2) to compute LJ parameters. To reduce the time for equilibrium calculations, the central hydrogen atoms were grouped together at the center of mass of the carbon atoms (CH₂-CH₂) as shown in Figure 2.

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Table 2
MEA force field parameters.

Figure 2
MEA molecule (H -white, N - blue, O - red, pseudo atom CH₂ - gray).

Impregnation Model

The simulation cell of faujasite was impregnated with MEA at 0.05 kPa, and a temperature of 25 ºC (conditions near the saturation pressure of MEA) so we could determine the zeolite maximum adsorption capacity of MEA. These calculations were performed in the grand canonical ensemble with the Monte Carlo method. Near saturation, NaX can accommodate a maximum of 60 molecules inside the pores. To obtain the other impregnation models, MEA molecules were randomly removed to match with impregnated values of the experimental studies that use different impregnation concentrations. During the adsorption of CO₂ and N₂, the MEA molecules are considered to be fixed in their equilibrium position. Our model is an attempt to get first insight into a viable MEA impregnation model. A unit cell of NaX loaded with 18 molecules of MEA is shown in Figure 3.

Figure 3
Unit cell of an impregnation model of NaX with 18 molecules of MEA. Atoms: N -blue, H - white, CH₂ - gray, O- red. Cation color: SI' and SII - white, SIII - green.

Gas Molecules (CO₂ and N₂)

Carbon dioxide was represented by the EPM2 atom-atom model proposed by Harris and Yung (1995)Harris, J. G., Yung, K. H., Carbon dioxide's liquid-vapor coexistence curve and critical properties as predicted by a simple molecular model. Journal of Physical Chemistry, 99, 12021-12024 (1995). with bond distance (C-O) of 1.149 Å. For N₂, we used the model proposed by Murth et al. (1980)Murth, C. S., Singer, K., Klein, M. L., McDonald, I. R., Pairwise additive effective potentials for nitrogen. Molecular Physics, 41, 1387-1399 (1980)., where the bond length (N-N) is 1.094 Å and the quadrupole moment was modeled by a three-point charge (q). In Figure 4, a representation of the gas adsorbate molecules can be seen, and in Table 3, the LJ parameters.

Figure 4
Molecular models of a) CO₂ and b) N₂. (O - red; C - gray; N - blue; Dummy atom yellow).

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Table 3
CO₂ and N₂ force field parameters.

Simulation Details

Monte Carlo simulations were performed in the grand canonical ensemble (GCMC) using the Monte Carlo method. Apart from the classical Monte Carlo moves (rotation, translation, creation and destruction) an additional movement was implemented for mixtures. It was based on the change of identities between CO₂ and N₂ molecules. The simulation output is the absolute adsorbed quantity, which we used to chart the isotherms. All simulations were performed at 25 ºC, with 2x10⁶ equilibrium and 2x10⁶ production steps. The Ewald Sum method was used to calculate the electrostatic contributions. The Lennard-Jones cutoff distance was 12.5 Å without long range corrections. A low cut of 0.4 Å and precision of 0.001 kcal/mol was applied. As done previously (Watanabe et al., 1995Watanabe, K., Austin, N. and Stapleton, M. R., Investigation of the air separation properties of zeolites types A, X and Y by Monte Carlo simulations. Molecular Simulation, 15, 197-221 (1995).; Maurin et al., 2005Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).; Pillai et al., 2012Pillai, R. S., Peter, S. A., Jasra, R. V., CO2 and N2 adsorption in alkali metal ion exchanged X-Faujasite: Grand canonical Monte Carlo simulation and equilibrium studies. Micropor. Mesopor. Mat., 162, 143-151 (2012).), one symmetric faujasite unit cell was used as the simulation cell with periodic boundary conditions in all directions.

RESULTS AND DISCUSSION

Force Field Validation

The validation of the force field for the system zeolite/gases was first performed by comparing the computed monocomponent adsorption isotherm for CO₂ and N₂ and the experimental data reported by Walton et al. (2005)Walton, K. S., Abney, M. B. and LeVan, M. D., CO2adsorption in Y and X zeolites modified by alkali metal cation exchange. Micropor. Mesopor. Mat., 91, 78-84 (2006). and Maurin et al. (2005)Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005). on NaX crystals, respectively (Figure 5). The simulated nitrogen isotherm presented a better fit than carbon dioxide. However, our fit between CO₂ experimental and simulated isotherms was improved if compared with other CO₂ simulated data on NaX (Maurin et al., 2005Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).; García-Sanchez et al., 2009Garcıa-Sanchez, A., Ania, C. O., Parra, J. B., Dub-beldam, D., Vlugt, T. J. H., Krishna, R. and Calero, S., Transferable force field for carbon dioxide adsorption in zeolites. J. Phys. Chem. C, 113, 88148820 (2009).). Some factors that contribute to inaccuracies between simulated and experimental isotherms are: 1- experimental uncertainty regarding the cation positioning (particularly site III') and 2- the fact that simulations were performed considering a perfect and periodic crystal structure, which differs from experimental samples, where crystal imperfections may interfere in the adsorption profile. As stated in other studies (Maurin et al., 2005Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).) we also observed that, at low pressure, CO₂ occupies the supercage near the cations on site III'. As the pressure increases, the cations located in site II are populated.

Figure 5
Simulated and experimental monocomponent adsorption isotherms of CO₂ and N₂ on NaX. Simulated and CO₂ experimental isotherms (Walton et al., 2005Walton, K. S., Abney, M. B. and LeVan, M. D., CO2adsorption in Y and X zeolites modified by alkali metal cation exchange. Micropor. Mesopor. Mat., 91, 78-84 (2006).) were performed at 25 ºC. N₂ experimental isotherm (Maurin et al., 2005Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).) was performed at 27 ºC.

Other parameters for validation that can be used are: adsorption heat and CO₂:N₂ selectivity. Our simulated adsorption heat of -8.15 kcal/mol is consistent with the experimental data of 10 kcal/mol reported by Maurin et al. (2005)Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).. Our simulated CO₂:N₂ selectivity (Equation (2)) for an equimolecular mixture was -12.1 (100 kPa and 25 ºC) versus -13.8 (101.3 kPa and 30 ºC) obtained experimentally by Pillai et al. (2012)Pillai, R. S., Peter, S. A., Jasra, R. V., CO2 and N2 adsorption in alkali metal ion exchanged X-Faujasite: Grand canonical Monte Carlo simulation and equilibrium studies. Micropor. Mesopor. Mat., 162, 143-151 (2012)..

Impregnation Impact in Adsorption

As noted previously, we estimated that faujasite adsorbed a maximum of 60 molecules of MEA (21.45% wt). We then randomly deleted MEA molecules to obtain new impregnated models with 6, 18 and 30 immobilized molecules, representing a range of concentrations of 2.66, 7.57 and 12.01% by weight of the MEA inside the zeolite pores. This range of concentrations is found in experimental studies of impregnation (Jadhav et al., 2007Jadhav, P. D., Chatti, R. V., Biniwale, R. B., Labhsetwar, N. K., Devotta, S., Rayalu, S. S., Monoethanol amine modified zeolite 13X for CO2 adsorption at different temperatures. Energy & Fuels, 21, 3555-3559 (2007).; Silva et al., 2012Silva, F. W. M., Soares-Maia, D. A., Oliveira, R. S., Moreno-Pirajan, J. C., Sapag, K., Cavalcante Jr., C. L., Zgrablich, G., Azevedo, D. C. S., Adsorption microcalorimetry applied to the characterisation of adsorbents for CO2 capture. The Canadian Journal of Chemical Engineering, 90, 1372-1380 (2012).).

First we verified how MEA modified the heat of adsorption (Figure 6). NaX without impregnation provides an average value of -8.15 kcal/mol and this value grows with the amount of amine impregnated, showing median values of -8.8 kcal/mol, -9.5 kcal/mol, -10.4 kcal/mol until reaching a maximum value of -12.4 kcal/mol for the models with 2.66, 7.57, 12.01 and 21:45 wt% MEA, respectively. This means that the presence of molecules of MEA effectively creates stronger adsorption sites. However, the simulated 15:85 (CO₂:N₂) mixture isotherms in the impregnation models show that the increase in heat of adsorption did not translate into a corresponding increase of CO₂ adsorption. This was particularly true for the models with a high loading of immobilized MEA (Figure 7).

Figure 6
Energy histograms of CO₂ adsorption on zeolite NaX and in the impregnation models. Median values are: -8.15 kcal/mol, -8.8 kcal/mol, -9.5 kcal/mol, -10.4 kcal/mol and -12.4 kcal/mol for the models with 0, 2.66, 7.57, 12.01 and 21:45 wt% of MEA.

Figure 7
Simulated adsorption isotherms of CO₂:N₂ (15:85) at 25 °C in NaX zeolite.

Only the model with 7.57 wt % of MEA showed a significant increase of the CO₂ adsorbed amount. This increase occured in a limited range of pressure that goes from 1 to 40 kPa. The models with 2.66 and 12.01 wt % had a modest increase and, finally, the model with 21.45 wt %, which has the highest heat of adsorption, showed a drastic decrease in its adsorption capacity. No improvement was observed for N₂. With the exception of the 2.55 wt% model, the N₂ loading decreased for all impregnation models tested (Figure 7).

Our simulated results for the impregnated material (isotherms and adsorption heat) are similar to several experimental studies. For example, Silva et al. (2012)Silva, F. W. M., Soares-Maia, D. A., Oliveira, R. S., Moreno-Pirajan, J. C., Sapag, K., Cavalcante Jr., C. L., Zgrablich, G., Azevedo, D. C. S., Adsorption microcalorimetry applied to the characterisation of adsorbents for CO2 capture. The Canadian Journal of Chemical Engineering, 90, 1372-1380 (2012). did CO₂ microcalorimetric measurements on NaX impregnated with MEA and found a strong peak of adsorption heat at low coverage, but the experimental isotherms with the impregnated material showed decreasing adsorption capacities with increasing concentration of MEA. Also, Jadhav et al. (2007)Jadhav, P. D., Chatti, R. V., Biniwale, R. B., Labhsetwar, N. K., Devotta, S., Rayalu, S. S., Monoethanol amine modified zeolite 13X for CO2 adsorption at different temperatures. Energy & Fuels, 21, 3555-3559 (2007). reported, via CO₂ breakthrough curves, decreasing CO₂ adsorption capacity in NaX with increased MEA impregnation.

The reason for the small enhancement of adsorption capacity, despite the increase in the heat of adsorption, is related to the drastic reduction of the NaX micropore volume as the MEA molecules are introduced into the pores (Table 4). With 30 molecules of MEA (12.1 wt%) the useful volume of the faujasite is reduced by almost half (43.25%). The adsorption is completely impaired for the impregnation model with 60 MEA molecules (21.45 wt%) with the available volume reduced by 90.73%. A view of the CO₂ and N₂ population in the 18 MEA (7.57 wt%) model at 10 and 100 kPa is depicted in Figure 8.

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Table 4
Micropore volume decrease with impregnation. Theoretical volume calculated by the Connoly method (Connoly, 1983Connolly, M. L., Solvent-accessible surfaces of proteins and nucleic acids. Science, 221, 709-13 (1983).) using a spherical probe with 1.8 Å radius.

Figure 8
Snapshots of the adsorption of the 15:85 (CO₂:N₂) mixture in the 18 MEA (5.75 wt%) impregnation model at 25 ºC and 10 kPa (a) and 100 kPa (b). H-white, N-blue, O-red, pseudo atom CH₂ and C-gray. Na+: SI' and SII - white, SIII - green.

Having foreseen satisfactory results for adsorption only for the 18 MEA (7.57 wt%) impregnation model, we turned to examine whether the introduction of MEA could improve the selectivity. Based on the adsorbed values of the isotherms of Figure 7, we calculated CO₂:N₂ selectivity using Equation (2):

where X_i and Y_i are the mole fractions of CO₂ and N₂ in the adsorbed (i=1) and gas phases (i=2), respectively. The selectivity calculations showed that the impregnated MEA causes an increase in selectivity (Table 5). The material without impregnation has selectivity of 44.2 that increases until a maximum value of 738.1 for the model with the higher degree of impregnation (60 MEA molecules).

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Table 5
Theoretical selectivity of CO₂:N₂ in NaX and impregnated models.

Our results make it clear that there exists a trade-off between the creation of stronger sites with addition of MEA molecules and the decrease of free pore volume for adsorption inside the NaX cavities. After inserted 18 MEA molecules, the effect of reduced volume available for adsorption of CO₂ molecules prevails, decreasing substantially the amount adsorbed.

CONCLUSIONS

We applied a validated force field, able to reproduce experimental monocomponent adsorption isotherms of CO₂ and N₂ in faujasite NaX, to investigate the influence of MEA impregnated FAU zeolite on a CO₂:N₂ mixture. Four impregnation models with increasing MEA concentration were designed. We performed adsorption theoretical studies for a binary mixture of CO₂:N₂ (15:85) at low CO₂ partial pressure, similar to the scenario of post-combustion. We found that NaX impregnated with concentrations up to 12 wt% should be more efficient in CO₂ capture due to the best compromise between increase in heat of adsorption and reduction of available volume by the addition of molecules of MEA. It is also observed that the adsorbents impregnated with a high concentration of monoethanolamine exhibit significant loss of adsorption capacity due to the effect of free volume reduction. The impregnation of NaX at concentrations above 12 wt% of MEA, under the investigated conditions, is not recommended to increase the capture of CO₂.

ACKNOWLEDGMENT

The authors wish to acknowledge the financial support received from CNPq and CAPES.

Alejandre, J., Rivera, J. L., Mora, M. A., Garza, V., Force field of monoethanolamine. Journal of Physical Chemistry B, 104, 1332-1337 (2000).
Baerlocher, C., McCusker, L. B. and Olson, D. H., Atlas of Zeolites Framework Types. Sixth Revised Editon, Elsevier, Amsterdan (2007).
Button, J. K., Gubbins, K. E., Tanaka, H., Nakanishi, K., Molecular dynamics simulation of hydrogen bonding in monoethanolamine. Fluid Phase Equilibria, 116, 320-325 (1996).
Cavenati, S., Grande, C. A., Rodrigues, A. E., Adsorption equilibrium of methane, carbon dioxide, and nitrogen on zeolite 13X at high pressures. Journal of Chemical & Engineering Data, 49, 10951101 (2004).
Connolly, M. L., Solvent-accessible surfaces of proteins and nucleic acids. Science, 221, 709-13 (1983).
Garcıa-Sanchez, A., Ania, C. O., Parra, J. B., Dub-beldam, D., Vlugt, T. J. H., Krishna, R. and Calero, S., Transferable force field for carbon dioxide adsorption in zeolites. J. Phys. Chem. C, 113, 88148820 (2009).
Harris, J. G., Yung, K. H., Carbon dioxide's liquid-vapor coexistence curve and critical properties as predicted by a simple molecular model. Journal of Physical Chemistry, 99, 12021-12024 (1995).
Jadhav, P. D., Chatti, R. V., Biniwale, R. B., Labhsetwar, N. K., Devotta, S., Rayalu, S. S., Monoethanol amine modified zeolite 13X for CO₂ adsorption at different temperatures. Energy & Fuels, 21, 3555-3559 (2007).
Knudsen, J. N., Jensen, J. N., Vilhelmsen, P. J., Biede, O., Experience with CO₂ capture from coal flue gas in pilot-scale: Testing of different amine solvents. Energy Procedia, 1, 783-790 (2009).
Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).
Murth, C. S., Singer, K., Klein, M. L., McDonald, I. R., Pairwise additive effective potentials for nitrogen. Molecular Physics, 41, 1387-1399 (1980).
Pillai, R. S., Peter, S. A., Jasra, R. V., CO₂ and N₂ adsorption in alkali metal ion exchanged X-Faujasite: Grand canonical Monte Carlo simulation and equilibrium studies. Micropor. Mesopor. Mat., 162, 143-151 (2012).
Rappe, A. K., Casewit, C. J., Colwell, K. S., Goddard, W. A., Skiff, W. M., UFF, A Full Periodic-Table Force-Field for Molecular Mechanics and Molecular - Dynamics Simulations. Journal of the American Chemical Society, 114, 10024-10035 (1992).
Rappe, A. K., Goddard, W. A. Charge equilibration for molecular dynamics simulations. J. Phys. Chem., 95, 3358-3363 (1991).
Rochelle, G. T., Amine scrubbing for CO₂ capture. Science, 325, 1652-1654 (2009).
Samantha, A., Zhao, A., Shimizu, G. K. H., Sarkar, P., Gupta, R., Post-combustion CO₂ capture using solid sorbents: A review. Industrial & Engineering Chemistry Research, 51, 1438-1463 (2012).
Sayari, A., Belmabkhout, Y., Serna-Guerrero, R., Flue gas treatment via CO₂ adsorption. Chem. Eng. J., 171, 760-774 (2011).
Silva, F. W. M., Soares-Maia, D. A., Oliveira, R. S., Moreno-Pirajan, J. C., Sapag, K., Cavalcante Jr., C. L., Zgrablich, G., Azevedo, D. C. S., Adsorption microcalorimetry applied to the characterisation of adsorbents for CO₂ capture. The Canadian Journal of Chemical Engineering, 90, 1372-1380 (2012).
Walton, K. S., Abney, M. B. and LeVan, M. D., CO₂adsorption in Y and X zeolites modified by alkali metal cation exchange. Micropor. Mesopor. Mat., 91, 78-84 (2006).
Watanabe, K., Austin, N. and Stapleton, M. R., Investigation of the air separation properties of zeolites types A, X and Y by Monte Carlo simulations. Molecular Simulation, 15, 197-221 (1995).
Zhu, L., Seff, K., Reinvestigation of the crystal structure of dehydrated sodium zeolite X. Journal of Physical Chemistry, B, 103, 9512-9518 (1999).

Publication Dates

Publication in this collection
Sept 2015

History

Received
14 Apr 2014
Reviewed
29 Nov 2014
Accepted
05 Dec 2014

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License which permits unrestricted non-commercial use, distribution, and reproduction in any medium provided the original work is properly cited.

[1] Alejandre, J., Rivera, J. L., Mora, M. A., Garza, V., Force field of monoethanolamine. Journal of Physical Chemistry B, 104, 1332-1337 (2000).

[2] Baerlocher, C., McCusker, L. B. and Olson, D. H., Atlas of Zeolites Framework Types. Sixth Revised Editon, Elsevier, Amsterdan (2007).

[3] Button, J. K., Gubbins, K. E., Tanaka, H., Nakanishi, K., Molecular dynamics simulation of hydrogen bonding in monoethanolamine. Fluid Phase Equilibria, 116, 320-325 (1996).

[4] Cavenati, S., Grande, C. A., Rodrigues, A. E., Adsorption equilibrium of methane, carbon dioxide, and nitrogen on zeolite 13X at high pressures. Journal of Chemical & Engineering Data, 49, 10951101 (2004).

[5] Connolly, M. L., Solvent-accessible surfaces of proteins and nucleic acids. Science, 221, 709-13 (1983).

[6] Garcıa-Sanchez, A., Ania, C. O., Parra, J. B., Dub-beldam, D., Vlugt, T. J. H., Krishna, R. and Calero, S., Transferable force field for carbon dioxide adsorption in zeolites. J. Phys. Chem. C, 113, 88148820 (2009).

[7] Harris, J. G., Yung, K. H., Carbon dioxide's liquid-vapor coexistence curve and critical properties as predicted by a simple molecular model. Journal of Physical Chemistry, 99, 12021-12024 (1995).

[8] Jadhav, P. D., Chatti, R. V., Biniwale, R. B., Labhsetwar, N. K., Devotta, S., Rayalu, S. S., Monoethanol amine modified zeolite 13X for CO₂ adsorption at different temperatures. Energy & Fuels, 21, 3555-3559 (2007).

[9] Knudsen, J. N., Jensen, J. N., Vilhelmsen, P. J., Biede, O., Experience with CO₂ capture from coal flue gas in pilot-scale: Testing of different amine solvents. Energy Procedia, 1, 783-790 (2009).

[10] Maurin, G., Llewellyn, P. L. and Bell, R. G., Adsorption mechanism of carbon dioxide in faujasites: Grand Canonical Monte Carlo simulations and microcalorimetry measurements. Journal of Physical Chemistry, B, 109, 16084-16091 (2005).

[11] Murth, C. S., Singer, K., Klein, M. L., McDonald, I. R., Pairwise additive effective potentials for nitrogen. Molecular Physics, 41, 1387-1399 (1980).

[12] Pillai, R. S., Peter, S. A., Jasra, R. V., CO₂ and N₂ adsorption in alkali metal ion exchanged X-Faujasite: Grand canonical Monte Carlo simulation and equilibrium studies. Micropor. Mesopor. Mat., 162, 143-151 (2012).

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Atom	σ_ss (Å)	ε_ss (kcal/mol)	q (e)
Si	3.827^a a - Universal Force Field;	0.092^b (CO₂) 0.170^b b - This study. (N₂)	+ 1.208
Al	4.008^a a - Universal Force Field;	0.111^b b - This study. (CO₂) 0.215^b b - This study. (N₂)	+ 1.200
O	3.118^a a - Universal Force Field;	0.070^b b - This study.	-0.765
Na (site I', II)	2.658^a a - Universal Force Field;	0.030^a a - Universal Force Field;	+0.768
Na (site III)	2.658^a a - Universal Force Field;	0.030^a a - Universal Force Field;	+0.610

Site	σ_ff (Å)	ε_ff (kcal/mol)	q (e)
HN	-	-	+0.347^b b Alejandre et al. (2000).
N	3.250^a a Button et al. (1996)	0.169^a a Button et al. (1996)	-0.938^b b Alejandre et al. (2000).
CH₂	3.905^a a Button et al. (1996)	0.118^a a Button et al. (1996)	+0.257^b b Alejandre et al. (2000).
O_MEA	3.070^a a Button et al. (1996)	0.169^a a Button et al. (1996)	-0.644^b b Alejandre et al. (2000).
HO	-	-	+0.374^b b Alejandre et al. (2000).

Atom	σ_ff (Å)	ε_ff (kcal/mol)	q (e)
C	2.757^a a Harris e Yung (1995);	0.055^a a Harris e Yung (1995);	+0.6512^a a Harris e Yung (1995);
O	3.033^a a Harris e Yung (1995);	0.159^a a Harris e Yung (1995);	-0.3256^a a Harris e Yung (1995);
N	3.320^b b Murth et al. (1980).	0.072^b b Murth et al. (1980).	-0.4050^a a Harris e Yung (1995);
*Dummy*	-	-	+0.8100^a a Harris e Yung (1995);

Property	Model of immobilized faujasite
Property	6 MEA (2.66 wt%)	18 MEA (7.57 wt%)	30 MEA (12.01 wt%)	60 MEA (21.45 wt%)
Free volume (Å³)	5449.86	4460.44	3349.04	546.87
Reduction (%)	7.66	24.42	43.25	90.73

Adsorbent model	Simulated adsorption capacity (mol/kg) at 25 ºC and 50 kPa		Selectivity (CO₂:N₂)
Adsorbent model	Carbon dioxide	Nitrogen	Selectivity (CO₂:N₂)
NaX (0 wt%)	1.677	0.215	44.2
6 MEA (2.66 wt%)	1.799	0.206	49.5
18 MEA (7.57 wt%)	1.696	0.141	68.3
30 MEA (12.01 wt%)	1.653	0.115	81.5
60 MEA (21.45 wt%)	0.521	0.004	738.1

Brasil

Brasil

THEORETICAL STUDY OF CO₂:N₂ ADSORPTION IN FAUJASITE IMPREGNATED WITH MONOETHANOLAMINE

Abstract

INTRODUCTION

METHODOLOGY

Intermolecular Interactions

Faujasite

Monoethanolamine

Impregnation Model

Gas Molecules (CO₂ and N₂)

Simulation Details

RESULTS AND DISCUSSION

Force Field Validation

Impregnation Impact in Adsorption

CONCLUSIONS

ACKNOWLEDGMENT

Publication Dates

History

Brasil

Brasil

THEORETICAL STUDY OF CO2:N2 ADSORPTION IN FAUJASITE IMPREGNATED WITH MONOETHANOLAMINE

Abstract

INTRODUCTION

METHODOLOGY

Intermolecular Interactions

Faujasite

Monoethanolamine

Impregnation Model

Gas Molecules (CO2 and N2)

Simulation Details

RESULTS AND DISCUSSION

Force Field Validation

Impregnation Impact in Adsorption

CONCLUSIONS

ACKNOWLEDGMENT

Publication Dates

History

THEORETICAL STUDY OF CO₂:N₂ ADSORPTION IN FAUJASITE IMPREGNATED WITH MONOETHANOLAMINE

Gas Molecules (CO₂ and N₂)