CO<sub>2</sub> Adsorption from Biogas Using Amine-Functionalized MgO

Kasikamphaiboon, Preecha; Khunjan, Uraiwan

doi:https://doi.org/10.1155/2018/1706405

International Journal of Chemical Engineering

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Abstract Introduction Experimental Results and Discussion Conclusions Data Availability Conflicts of Interest Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2018 | Article ID 1706405 | https://doi.org/10.1155/2018/1706405

CO₂ Adsorption from Biogas Using Amine-Functionalized MgO

Preecha Kasikamphaiboon¹and Uraiwan Khunjan¹

Academic Editor: Bhaskar Kulkarni

Received17 Aug 2018

Revised18 Nov 2018

Accepted29 Nov 2018

Published13 Dec 2018

Abstract

Biogas is a renewable fuel source of methane (CH₄), and its utilization as a natural gas substitute or transport fuel has received much interest. However, apart from CH₄, biogas also contains carbon dioxide (CO₂) which is noncombustible, thus reducing the biogas heating value. Therefore, upgrading biogas by removing CO₂ is needed for most biogas applications. In this study, an amine-functionalized adsorbent for CO₂ capture from biogas was developed. Mesoporous MgO was synthesized and functionalized with different tetraethylenepentamine (TEPA) loadings by wet impregnation technique. The prepared adsorbents (MgO-TEPA) were characterized by X-ray diffraction (XRD) and N₂ adsorption-desorption. The CO₂ adsorption performance of the prepared MgO-TEPA was tested using simulated biogas as feed gas stream. The results show that the CO₂ adsorption capacities of the adsorbents increase with increasing TEPA loading. The optimum TEPA loading is 40 wt.%, which gives the highest CO₂ adsorption capacity of 4.98 mmol/g. A further increase in TEPA loading to 50 wt.% significantly reduces the CO₂ adsorption capacity. Furthermore, the stability and regenerability of the adsorbent with 40% TEPA loading (MgO-TEPA-40) were studied by performing ten adsorption-desorption cycles under simulated biogas and real biogas conditions. After ten adsorption-desorption cycles, MgO-TEPA-40 shows slight decreases of only 5.42 and 5.75% of CO₂ adsorption capacity for the simulated biogas and biogas, respectively. The results demonstrate that MgO-TEPA-40 possesses good stability and regenerability which are important for the potential application of this amine-based adsorbent.

1. Introduction

Due to rising fossil fuel prices, greenhouse gas emissions from fossil fuel combustion, and high energy demands, sustainable and renewable energy sources are needed [1, 2]. Biogas, considered to be one of the alternative sources of renewable energy, has the potential to supplement the current energy requirements. Biogas produced from anaerobic digestion processes is mainly composed of 50–70% of methane (CH₄) and 30–50% of carbon dioxide (CO₂) [3]. Apart from these two gases, biogas contains smaller amounts of hydrogen sulfide (H₂S) and trace amounts of ammonia (NH₃), nitrogen (N₂), hydrogen (H₂), carbon monoxide (CO), and oxygen (O₂) [4, 5]. The energy content in terms of calorific value of pure methane is 36 MJ/m³ (at STP conditions), whereas that of the biogas containing 60–65% CH₄ is approximately 20–25 MJ/m³ [3, 6]. Therefore, being noncombustible, CO₂ also causes a reduction in the heating value and energy density of biogas on volume basis. In addition, high CO₂ content increases energy demand for compression and transportation of biogas. Biogas can be upgraded to a higher fuel standard by increasing the energy density by reducing major noncombustible gas (CO₂) and other impurities. The final product consisting of 95–99% CH₄ and 1–5% CO₂ [7], which is called biomethane, can be used as a substitute for natural gas and a vehicle fuel. Therefore, upgrading biogas to biomethane is one of the technologies that receive much attention in the bioenergy industry.

To remove acid gases such as CO₂ and H₂S from gas streams, several technologies have been developed, including physical absorption, chemical absorption, adsorption, membrane separation, and cryogenic separation [8]. Among these technologies, the chemical absorption using liquid amine absorbents is one of the most widely used technologies for separating CO₂ from gas streams [9, 10]. However, amine scrubbing processes have some disadvantages such as high energy consumption for solvent regeneration, high equipment corrosion rate, solvent degradation, and fouling of the process equipment [11–13]. As a result, adsorption-based technologies, usually involving solid CO₂ adsorbents, are suggested and studied to overcome those problems [14]. Adsorbents for CO₂ capture are mainly porous materials, such as activated carbon [15, 16], mesoporous silica [17], zeolites [18, 19], and metal-organic frameworks (MOFs) [20, 21], which usually have a large surface area in mesopores and micropores. Compared to liquid amine absorption, the solid adsorbents possess significant advantages for energy efficiency. However, there are some existing problems such as low CO₂ adsorption capacities and selectivity. Therefore, modification or functionalization of the solid adsorbents by introducing amines into their porous structure for CO₂ adsorption has also attracted great interest [22]. The amine-functionalized adsorbents combine the high CO₂ affinity of amines and porous materials (large pore volume and large surface area) which exhibit advantageous properties such as high CO₂ adsorption rate and high thermal stability. These adsorbents not only have the potential to reduce the energy consumption compared to the large amount of energy required to heat bulk water for the regeneration of absorbent in the aqueous amine absorbent process but also have high CO₂ adsorption capacity and the ability to reduce the corrosion of equipment caused by high concentrated aqueous amine absorbent [10, 23]. Several research groups have studied and reported the performances of mesoporous materials functionalized with amines for CO₂ removal. These materials can be grouped together depending on the preparation methods which are grafting and impregnation with diverse amine species such as aminosilanes, polyethylenimine (PEI), tetraethylenepentamine (TEPA), and diethanolamine (DEA) [24–31]. The adsorbents obtained by chemical grafting of amine onto the support are relatively more stable than those obtained by physical impregnation. However, the amount of grafted amine is limited, resulting in a relatively lower amine loading which leads to lower CO₂ adsorption capacity. Unlike the grafting method, the impregnation method possesses several advantages such as easier preparation, higher amine loading, and lower cost [32].

Apart from the solid adsorbents mentioned above, magnesium oxide (MgO) has been widely studied for CO₂ capture and has been reported as a potential adsorbent for CO₂ adsorption [33–35]. However, pure MgO exhibits fairly small CO₂ adsorption capacity [36]. To the best of our knowledge, introducing amines into the porous structure of MgO to form a composite with high CO₂ adsorption capacity has not been reported. Therefore, in the present study, a new adsorbent for CO₂ removal from biogas was developed. MgO with mesoporous structure was synthesized and functionalized with tetraethylenepentamine (TEPA) via an impregnation process. The prepared adsorbents with different amine loadings were investigated for CO₂ adsorption capacity. Multiple adsorption-desorption cyclic stability of the adsorbents was also tested by using simulated biogas and biogas as feed gas streams.

2. Experimental

2.1. Synthesis of Mesoporous MgO

Mesoporous MgO was synthesized using the sol-gel method as reported in the literature [37]. Magnesium nitrate hexahydrate (Mg(NO₃)₂·6H₂O) and oxalic acid ((COOH)₂·2H₂O), purchased from Sigma-Aldrich, in the molar ratio of 1 : 1, were first dissolved separately in ethanol and used for the synthesis of MgO. These solutions were then mixed together with vigorous magnetic stirring to yield a thick white gel and kept stirred for 12 h. Subsequently, the gel product was dried at 100°C for 24 h. The dried mixture was ground and calcined under atmospheric pressure at 600°C for 2 h. The chemical reactions in the sol-gel and calcination step can be expressed by equations (1) and (2), respectively [37]:

2.2. Preparation of Amine-Functionalized Adsorbents

In this study, the amine-functionalized adsorbents were prepared by the wet impregnation method described by Xu et al. [38] with some modification. The desired amount of tetraethylenepentamine (TEPA), obtained from Sigma-Aldrich, was dissolved in 25 ml of methanol under stirring for 15 min. Then, 5 g of the synthesized MgO was added to the TEPA-methanol solution, and the resultant slurry was stirred continuously for approximately 30 min. The slurry was then dried at 70°C for 2 h. The adsorbents impregnated with TEPA were designated as MgO-TEPA-x, where x represents the weight percentage of TEPA in the adsorbents.

2.3. Characterization of the Adsorbents

The crystal structures of the prepared adsorbents were analyzed by powder X-ray diffraction (PXRD) by using a Philips X’Pert MPD diffractometer with Cu-Kα radiation. The N₂ adsorption-desorption isotherms were measured at −196°C using a Micromeritics ASAP2060 volumetric analyzer. The isotherms were used for calculating the surface area, pore volume, and average pore diameter of the adsorbents via the Brunauer–Emmett–Teller (BET) method and the Barrett–Joyner–Halenda (BJH) method.

2.4. CO₂ Adsorption

The CO₂ adsorption-desorption tests were performed in a fixed-bed reactor of which a simplified flow diagram is given in Figure 1. The reactor was a stainless-steel adsorption column with an inner diameter of 15 mm and a length of 160 mm. Typically, 5 g of the adsorbent was packed into the adsorption column and supported by quartz wool from both sides. Before each experimental run, the sample was heated to 100°C in a N₂ (99.99% purity) stream at the flow rate of 40 mL/min for 60 min. After cooling to the adsorption temperature (30°C), the adsorption tests began by introducing simulated biogas into the adsorption column at a flow rate of 40 mL/min. The simulated biogas was produced by mixing CO₂ (99.99% purity) and N₂ (99.99% purity) from gas cylinders at the desired flow rates to obtain a concentration of 40% CO₂ and 60% N₂. The adsorbent-bed temperature was measured by thermocouples and controlled by a temperature controller. After completing the adsorption process, desorption of the adsorbed CO₂ was performed by heating the sample to 150°C in a N₂ gas stream for 60 min. In order to test the regenerability of the adsorbent, ten cycles of adsorption-desorption were performed on the same sample. In this study, biogas produced from a local swine farm was also used as feed gas to test the CO₂ adsorption performance of the prepared adsorbent using the same experimental procedure. The biogas consists of 38.4% CO₂ and 61.5% CH₄, which are in the range of the typical biogas compositions found in the literature [39]. The concentrations of CO₂ in the feed and treated gas streams were determined by a gas chromatograph equipped with a TCD detector.

The breakthrough curve data obtained from the CO₂ adsorption tests were used for calculating the equilibrium capacity of the adsorbents according to equations (3) and (4) [40]:where is the mean residence time (min), and are the inlet and outlet concentrations of CO₂ (vol.%), respectively, is the equilibrium adsorption capacity of CO₂ (mmol/g), is the adsorption time (min), is the feed volumetric flow rate (ml/min) at standard temperature and pressure (STP), and is the mass of the adsorbent (g).

3. Results and Discussion

3.1. Characterization

Figure 2 shows the XRD patterns of the prepared MgO with different TEPA loadings. The pristine MgO exhibits five well-resolved diffraction peaks at 36.9°, 42.9°, 62.3°, 74.7°, and 78.6°. These are characteristic peaks of MgO, which are consistent with the results of previous reports [35, 41, 42]. This confirms a high degree of purity and suggests that the obtained MgO samples are highly crystalline. From comparing the diffraction pattern of MgO with those of MgO-TEPA-x with different TEPA loadings; the diffraction angles are nearly identical, indicating that the structure of MgO is preserved after loading the TEPA. However, the diffraction intensity of MgO decreases with increasing TEPA loadings. It has been reported that diffraction intensities are relative to the degrees of pore filling [43]. Therefore, the incorporation of amine into the pore channels of the support possibly causes the loss of intensity [28]. This indicates that TEPA is loaded into the pore of the MgO support, which is similar to that observed in MCM-41 loaded with polyethylenimine (PEI) [38].

To investigate the porous structure of the prepared samples, N₂ adsorption-desorption isotherms were measured. Figure 3 shows the N₂ adsorption-desorption isotherms of the prepared MgO with different TEPA loadings. According to the International Union of Pure and Applied Chemistry (IUPAC) classification [44], all of the samples display type IV isotherms with the hysteresis loop. The hysteresis loop present in the isotherm is due to the capillary condensation taking place in mesopores. The pristine MgO exhibits a large hysteresis loop compared with the other four TEPA-functionalized samples, indicating the presence of highly porous structure. In addition, it can be seen that the N₂ uptake decreases with increasing TEPA loading. As the TEPA loading increases from 20 to 50 wt.%, the mesopores of MgO are almost completely filled with TEPA molecules at 50 wt.% which results in restricting the access of N₂ into the pores, thus causing MgO-TEPA-50 to become a nonporous material [45].

From the N₂ adsorption-desorption isotherms, the surface area, pore volume, and average pore diameter of the MgO samples were calculated according to the BET and BJH method and are listed in Table 1. Loading TEPA onto MgO significantly reduces the surface area and pore volume. For example, when the TEPA loading is 20 wt.%, the surface area and the pore volume decrease from 207 to 118 m²/g and from 0.81 to 0.53 cm³/g, respectively. A further increase in TEPA loading to 50 wt.% causes a great decrease in the surface area and the pore volume. This is because, when the TEPA loading reaches 50 wt.% or higher, excessive amount of TEPA blocks most of the pores and covers the surface of the adsorbent [46, 47]. The same trend as the surface area and pore volume is observed for the pore size of the samples.

3.2. CO₂ Adsorption Behaviors

The effect of TEPA loading on the CO₂ adsorption performance of MgO-TEPA was investigated using simulated biogas as the feed gas. Figures 4 and 5 show the breakthrough curves and the adsorption capacities (mmol of CO₂/g of adsorbent), respectively. As can be seen, the CO₂ adsorption of the pristine MgO reaches the saturation point within only 12 min, resulting in a low adsorption capacity of 0.95 mmol/g. Increasing TEPA loading within a suitable range increases the breakthrough time and adsorption capacity of the adsorbents, which is consistent with the results of previous reports [48, 49]. This is because, as the loading increases, more amine active sites for CO₂ adsorption are provided. When the TEPA loading increases to 40 wt.% (MgO-TEPA-40), the adsorbent shows the maximum breakthrough time and adsorption capacity of 34 min and 4.98 mmol/g, respectively. However, as the TEPA loading increases from 40 to 50 wt.%, the breakthrough time and the adsorption capacity significantly drop from 34 to 28 min and from 4.98 to 4.26 mmol/g, respectively. Too high loadings may cause the TEPA molecules to aggregate in the pore or coat the surface of the adsorbent, which hinder the diffusion of CO₂ to react with the active sites in the pores [48, 50]. The above results suggest that the optimum TEPA loading for MgO modification is 40 wt.%.

The most common mechanism for CO₂ capture in supported amines under dry conditions involves the formation of carbamates between two amine groups [51, 52]. Two types of these amine groups exist within TEPA including primary (R₁-NH₂) and secondary (R₁-NH-R₂) amines. The reactions of CO₂ with the primary and secondary amines in TEPA can be represented as in equations (5)–(7) [52]:

In order to explore the degree of utilization of amine groups in TEPA by CO₂, the amine efficiency was defined as the molar ratio of the adsorbed CO₂ to all amine groups present in the adsorbents [48]. The number of amine groups was calculated from the molar amount of nitrogen atoms in TEPA. The molecular weight of TEPA is 189.3 g/mol, and each TEPA molecule contains 5 amine groups. Therefore, the amine efficiency was calculated and is presented in Figure 5. It can be seen that the amine efficiency decreases with an increase in TEPA loading. The highest amine efficiency of 0.54 is obtained at 20 wt.% TEPA loading, suggesting that two moles of amine groups reacts with one mole of CO₂. At low TEPA loading, the amine chains are more dispersible, making the adsorption sites easily available. However, as the amine loading increases, amines would begin to conglomerate within the pores. This leads to poor distribution of amine sites, resulting in a reduction in the number of the accessible amine sites for CO₂ sorption, although the potential amine sites are more for higher TEPA loading. With a further increase in TEPA loading to 50 wt.%, the amine efficiency decreases significantly to 0.32, indicating that some of amine sites are unoccupied.

The CO₂ adsorption capacities of MgO and MgO-TEPA-40 in this study and those of amine-impregnated adsorbents reported in the literature are compared in Table 2. As can be seen, various supports and amines are used for adsorbent preparation. The comparison shows that the CO₂ adsorption capacity of MgO-TEPA-40 is higher than those previously reported in the literature.

3.3. Regenerability of the Adsorbents

In industrial applications, the stability and regenerability of CO₂ adsorbents are critical parameters for long-term operation. In this study, the cyclic CO₂ adsorption capacity of MgO-TEPA-40 was investigated by performing ten CO₂ adsorption-desorption cycles using simulated biogas and real biogas as feed gas streams. Figure 6 shows the cyclic CO₂ adsorption capacities of the adsorbent in ten consecutive runs. For the simulated biogas, the CO₂ adsorption capacity decreases slightly with increasing number of adsorption-desorption cycle. After ten cycles, the CO₂ adsorption capacity decreases from 4.98 to 4.71 mmol/g, which is a decrease of only 5.42%. The CO₂ adsorption capacity for the biogas exhibits the same trend, decreasing from 4.87 to 4.59 mmol/g after ten cycles, meaning the capacity loss of only 5.75%. These capacity drops are lower than those of some amine-based adsorbents reported in the literature [49, 65]. The loss of adsorption capacity during the adsorption-desorption cycles could be due to the volatilization of the impregnated TEPA [51, 66].

4. Conclusions

Mesoporous MgO was synthesized and functionalized by impregnation with different tetraethylenepentamine (TEPA) loadings. The prepared MgO-TEPA was used as an adsorbent for CO₂ separation from simulated biogas. The CO₂ adsorption capacity of the adsorbents was found to increase with increasing TEPA loading. MgO-TEPA-40 with 40 wt.% TEPA exhibits the best CO₂ adsorption performance, with the CO₂ adsorption capacity of 4.98 mmol/g. However, a further increase in TEPA loading to 50 wt.% causes a significant reduction of CO₂ adsorption capacity. The stability and regenerability of MgO-TEPA-40 were examined by performing ten consecutive CO₂ adsorption-desorption runs under simulated biogas and real biogas conditions. MgO-TEPA-40 shows slight decreases of only 5.42 and 5.75% of CO₂ adsorption capacity for the simulated biogas and biogas, respectively, after ten cycles. These results indicate that MgO-TEPA-40 has a stable CO₂ adsorption capacity and good regenerability both in simulated biogas and biogas, which are beneficial properties for practical applications as CO₂ adsorbent.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that there are no conflicts of interest regarding the publication of this paper.

Acknowledgments

The authors gratefully acknowledge the Faculty of Science and Technology, Prince of Songkla University, for the instruments and facilities used in this study.

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Copyright © 2018 Preecha Kasikamphaiboon and Uraiwan Khunjan. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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