CO2 Capture in Ionic Liquids Based on Amino Acid Anions With Protic Side Chains: a Computational Assessment of Kinetically Efficient Reaction Mechanisms
Abstract:Absorption and capture of CO 2 directly from sources represents one of the major tools to reduce its emission in the troposphere. One of the possibilities is to incorporate CO 2 inside a liquid exploiting its propensity to react with amino groups to yield carbamic acid or carbamates. A particular class of ionic liquids, based on amino acids, appear to represent a possible efficient medium for CO 2 capture because, at difference with current industrial setups, they have the appeal of a biocompat-ible and enviro… Show more
“…The computational model has been previously verified as accurate enough when compared to CBS-QB3 and G4MP2 composite methods. 32 The Gaussian16 49 package was used for all the ab initio calculations. We have included the zero-point-energies in all of the energetic values reported in the rest of the paper.…”
Section: Methodsmentioning
confidence: 99%
“…In principle, the kinetics of the reaction is therefore determined by the energy barrier along the PT step, but we have recently shown that, depending on the nature of the AA, there exist reactive pathways with null or negligible activation barriers. 32 …”
Section: Introductionmentioning
confidence: 99%
“…First of all, in the framework of ab initio calculations, we are unable to account for the presence of an explicit surrounding liquid. In ref ( 32 ), we have taken into account the environmental effects using the polarizable continuum model (PCM) approximation using the parametrization for a solvent with a medium dielectric constant. 35 The results indicate that the presence of such environment does not alter significantly the overall reaction profiles with only minor variations of the PT barrier.…”
CO
2
capture
at the production site represents one of
the accessible ways to reduce
its emission in the atmosphere. In this context, CO
2
chemisorption
is particularly advantageous and is often based on exploiting a liquid
containing amino groups that can trap CO
2
due to their
propensity to react with it to yield carbamic derivatives. A well-known
class of ionic liquids based on amino acid anions might represent
an ideal medium for CO
2
capture because, at difference
with present implementations, they are known to be fully biocompatible.
One of the problems is however the relatively low molar ratio of CO
2
absorption. Increasing this ratio turns out to be possible
by choosing appropriate anions. We present here a set of accurate
computations to elucidate the possible reaction paths that allow the
anion to absorb two CO
2
molecules, thus effectively doubling
the overall intake. An extensive exploration of some reaction mechanisms
suggests that some of them might be quite efficient even under mild
conditions.
“…The computational model has been previously verified as accurate enough when compared to CBS-QB3 and G4MP2 composite methods. 32 The Gaussian16 49 package was used for all the ab initio calculations. We have included the zero-point-energies in all of the energetic values reported in the rest of the paper.…”
Section: Methodsmentioning
confidence: 99%
“…In principle, the kinetics of the reaction is therefore determined by the energy barrier along the PT step, but we have recently shown that, depending on the nature of the AA, there exist reactive pathways with null or negligible activation barriers. 32 …”
Section: Introductionmentioning
confidence: 99%
“…First of all, in the framework of ab initio calculations, we are unable to account for the presence of an explicit surrounding liquid. In ref ( 32 ), we have taken into account the environmental effects using the polarizable continuum model (PCM) approximation using the parametrization for a solvent with a medium dielectric constant. 35 The results indicate that the presence of such environment does not alter significantly the overall reaction profiles with only minor variations of the PT barrier.…”
CO
2
capture
at the production site represents one of
the accessible ways to reduce
its emission in the atmosphere. In this context, CO
2
chemisorption
is particularly advantageous and is often based on exploiting a liquid
containing amino groups that can trap CO
2
due to their
propensity to react with it to yield carbamic derivatives. A well-known
class of ionic liquids based on amino acid anions might represent
an ideal medium for CO
2
capture because, at difference
with present implementations, they are known to be fully biocompatible.
One of the problems is however the relatively low molar ratio of CO
2
absorption. Increasing this ratio turns out to be possible
by choosing appropriate anions. We present here a set of accurate
computations to elucidate the possible reaction paths that allow the
anion to absorb two CO
2
molecules, thus effectively doubling
the overall intake. An extensive exploration of some reaction mechanisms
suggests that some of them might be quite efficient even under mild
conditions.
“…Shaikh et al ( 2016 , 2020 ) showed the existence of barriers associated with the proton transfer step that leads the pre-reaction zwitterion to the final carbamate. Mercy et al ( 2016 ) and Onofri et al ( 2020 ) have found that the proton transfer step in [Ch][AA] can occur via two possible reaction pathways that differ by the size of the ring that is formed in the transition state as shown in Scheme 3 . The mechanism based on a 4-member ring is highly disfavored due to very high barriers, while the one with a 5-member ring has a low activation energy of only few kcal/mol.…”
Section: Chaail As Candidates For Co
2
Absorptionmentioning
confidence: 99%
“…Water seems to play a two-faced role since it works by reducing viscosity and hydrogen bonding, thus increasing the diffusion of CO 2 , as well as removing phenomena that render the reaction site less available, but it may also act as a catalyst for the overall CO 2 absorption reaction by assisting a more efficient PT. When a single water molecule was included in the transition state computational evaluation, it effectively lowered the kinetic barriers of this step (Li et al 2018 ; Shaikh et al 2020 ; Onofri et al 2020 ) by reducing the strain on the transition state cycle as shown in Scheme 4 . Scheme 4 Possible mechanisms of the proton transfer step with a 6-member ring or a 7-member ring in the transition state when including a water molecule …”
Section: Chaail As Candidates For Co
2
Absorptionmentioning
Boosted by the simplicity of their synthesis and low toxicity, cholinium and amino acid-based ionic liquids have attracted the attention of researchers in many different fields ranging from computational chemistry to electrochemistry and medicine. Among the uncountable IL variations, these substances occupy a space on their own due to their exceptional biocompatibility that stems from being entirely made by metabolic molecular components. These substances have undergone a rather intensive research activity because of the possibility of using them as greener replacements for traditional ionic liquids. We present here a short review in the attempt to provide a compendium of the state-of-the-art scientific research about this special class of ionic liquids based on the combination of amino acid anions and cholinium cations.
Bio‐compatible ionic liquids (Bio‐ILs) represent a class of solvents with peculiar properties and exhibit huge potential for their applications in different fields of chemistry. Ever since they were discovered, researchers have used bio‐ILs in diverse fields such as biomass dissolution, CO2 sequestration, and biodegradation of pesticides. This review highlights the ongoing research studies focused on elucidating the microscopic structure of bio‐ILs based on cholinium cation ([Ch]+) and amino acid ([AA]−) anions using the state‐of‐the‐art
and classical molecular dynamics (MD) simulations. The microscopic structure associated with these green ILs guides their suitability for specific applications. ILs of this class differ in the side chain of the amino acid anions, and varying the side chain significantly affects the structure of these ILs and thus helps in tuning the efficiency of biomass dissolution. This review demonstrates the central role of the side chain on the morphology of choline amino acid ([Ch][AA]) bio‐ILs. The seemingly matured field of bio‐ILs and their employment in various applications still holds significant potential, and the insights on their microscopic structure would steer the field of target specific application of these green ILs.
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