Ionic Liquid/Metal–Organic Framework Composites for H₂S Removal from Natural Gas: A Computational Exploration

Abstract: The separation of H 2 S/CH 4 mixture was computationally examined in the composites of ionic liquids (ILs) supported on metal-organic frameworks (MOFs) at room temperature. Cu-TDPAT was selected as supporter for four types of ILs combined from identical cation [BMIM] + with different anions ([Cl] -, [Tf 2 N] -, [PF 6 ]and [BF 4 ] -). The results show that introducing ILs into Cu-TDPAT can greatly enhance the adsorption affinity towards H 2 S compared to the pristine MOF, and the strongest enhancement occurs in… Show more

“…This body of literature can be summarized by two main goals: (1) the measurement of the phase behavior of CO 2 dissolved in ILs; and (2) the quantitation of CO 2 solubility in a bulk phase IL. As an example, in one recent study the solubility of CO 2 gas in [C 9 -imidazolium][PF 6 ] was shown to increase by~22% over a [C 4 -imidazolium][PF 6 ], as estimated from the liquid phase volume increase on going from low to high pressure at 298 K [43]. The main conclusion from all of this work is that CO 2 is effectively captured in the bulk IL phase.…”

“…RTILs are also designer solvents in the sense that a wide variety of cations and anions can be combined to tailor ILs for task-specific processes or reactions [1,2]. RTILs have unique characteristics, such as low volatility, non-flammability and water miscibility, that make them candidates for use in many applications, and has given rise to their use as cosolvents [3][4][5][6] in numerous applications [1,[3][4][5][6][7][8][9][10][11][12][13] that include electrochemistry [14][15][16], organic synthesis [17,18], gas separation/SLM's [19,20] and catalysis [17,21]. The inherent polar and nonpolar nanodomains that form in ILs allow them to readily solvate polar and non-polar solutes, and this has given rise to a significant increase in their study over the last decade [8,14,15,17,[19][20][21][22].…”

Dissolution of Trihexyltetradecylphosphonium Chloride in Supercritical CO2

“…This body of literature can be summarized by two main goals: (1) the measurement of the phase behavior of CO 2 dissolved in ILs; and (2) the quantitation of CO 2 solubility in a bulk phase IL. As an example, in one recent study the solubility of CO 2 gas in [C 9 -imidazolium][PF 6 ] was shown to increase by~22% over a [C 4 -imidazolium][PF 6 ], as estimated from the liquid phase volume increase on going from low to high pressure at 298 K [43]. The main conclusion from all of this work is that CO 2 is effectively captured in the bulk IL phase.…”

“…RTILs are also designer solvents in the sense that a wide variety of cations and anions can be combined to tailor ILs for task-specific processes or reactions [1,2]. RTILs have unique characteristics, such as low volatility, non-flammability and water miscibility, that make them candidates for use in many applications, and has given rise to their use as cosolvents [3][4][5][6] in numerous applications [1,[3][4][5][6][7][8][9][10][11][12][13] that include electrochemistry [14][15][16], organic synthesis [17,18], gas separation/SLM's [19,20] and catalysis [17,21]. The inherent polar and nonpolar nanodomains that form in ILs allow them to readily solvate polar and non-polar solutes, and this has given rise to a significant increase in their study over the last decade [8,14,15,17,[19][20][21][22].…”

Dissolution of Trihexyltetradecylphosphonium Chloride in Supercritical CO2

“…The popularity of ILs has much to do with their interesting physicochemical properties, such as good solvents for a wide variety of organic and inorganic compounds, tunable solubility properties and negligible vapor pressure. Usually in MOFs synthesis, the ILs behave as solvents [154][155][156], reactants [157][158][159], structure directing agents [160][161][162][163][164], charge-compensating templates in anionic networks [165][166][167][168][169], functional inclusions [170][171][172][173][174][175][176], and as template. As mentioned in the previous section, a remarkable example of the MOF morphology controlled electrochemical synthesis in pure ionic liquid (IL) system was reported by Yang et al [143].…”

Multi-scale crystal engineering of metal organic frameworks

“…Hydrogen sulfide is present in high concentrations within most natural gases, 2 but also in biogas 3 and landfill gas. 4,5 Currently, the most commonly used solutions for the removal of hydrogen sulfide are activated carbon and the Claus process.…”

“…However, its production is very expensive and the used up activated carbon can hardly be regenerated, thus most activated carbon has to be treated as hazardous waste after being used for H 2 S filtering purposes. 3,6 The Claus process operates above 900 • C, partly oxidizing the gas to produce water and atomic sulfur via the two steps given in equations (1) and (2). 1,7,8 H 2 S + 3/2 O 2 → H 2 S + SO 2 (1)…”

Efficient new process for the desulfurization of mixtures of air and hydrogen sulfide via a dielectric barrier discharge plasma