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Designing moisture-swing CO2 sorbents through anion screening of polymeric ionic liquids Tao Wang, Kun Ge, Yusong Wu, Kexian Chen, Mengxiang Fang, and Zhongyang Luo Energy Fuels, Just Accepted Manuscript • DOI: 10.1021/acs.energyfuels.7b02200 • Publication Date (Web): 19 Sep 2017 Downloaded from http://pubs.acs.org on September 20, 2017
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Designing moisture-swing CO2 sorbents through anion screening of polymeric ionic liquids Tao Wang,*,† Kun Ge,† Yusong Wu,† Kexian Chen,*,‡ Mengxiang Fang,† Zhongyang Luo† †
State Key Laboratory of Clean Energy Utilization, Zhejiang University, Hangzhou, Zhejiang Province 310018, P.R. China. ‡
School of Food Science and Biotechnology, Zhejiang Gongshang University, Hangzhou, Zhejiang Province 310018, P.R. China.
Abstract: Polymeric ionic liquids (PILs) are promising CO2 sorbents as their behaviors are tunable by assembling ion pairs. This work aims to design CO2 sorbents with unique moisture-swing adsorption performance by assembling different anions on quaternary-ammonium-based PILs. Two aspects of the sorbent design were studied: the suitability of the CO2 affinity for different applications (e.g., direct air capture or flue gas capture) and capability for moisture-swing adsorption. Carbonate, fluoride and acetate were chosen as counter anions as they are representative anions with different basicity, valence and water affinity. CO2 affinity was found to positively correlate with the pKa value of the counter anion, except for fluoride, which has an intrinsic character of attracting protons. The moisture swing capacity is determined by the difference between the hydration energies of the reactant and product after CO2 adsorption and followed the order carbonate > fluoride > acetate. Further investigations revealed that the repulsion between the two quaternary ammonium cations could promote the dissociation of hydrated water, which results in the lowest activation energy for CO2 adsorption for the PIL with carbonate. Therefore, the PIL with carbonate is potentially a desirable candidate for air capture and moisture-swing regeneration, while the PIL with acetate is suitable for CO2 capture under high partial ACS Paragon Plus Environment
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pressure and regeneration through conventional approaches. This study provides a quantitative microscopic insight into the role of the anion in CO2 adsorption and paves the way toward the optimal PIL structure for CO2 capture under specific circumstances.
Among PILs, the quaternary-ammonium-
1. INTRODUCTION Carbon dioxide capture and storage (CCS) is regarded
as
one
of
the
most
effective
approaches to alleviating global warming.1 Among
the
developed
CO2
capture
technologies, adsorption based on a solid material is advantageous since sorbents have unique interfacial properties, such as porous
based PILs have been highlighted in the literature due to their higher stability and CO2 sorption capacity than those of imidazoliumbased
PILs.10
More
interestingly,
when
coordinated with relatively basic anions such as OH- and CO32-, these PILs show the unique property of moisture-swing adsorption (MSA).11
structures, modifiable functional groups2,3, and
During the moisture-swing cycle, the sorbents
low emissions to the environment4. Recently,
adsorb CO2 in a dry atmosphere and release
polymeric ionic liquids (PILs) have been developed as a family of promising CO2 sorbents,
as
they
possess
the
unique
characteristics of ionic liquids (ILs) and the feasibility of a macromolecular framework.5-7 Both the CO2 adsorption capacity and rate of PILs can be substantially higher than those of
CO2 in a humid atmosphere. For poly[4vinylbenzyltrimethylammonium
carbonate]
(P[VBTEA][CO32-]), the equilibrium partial pressure of CO2 under wet conditions is two orders of magnitude higher than that under dry conditions.11
This
moisture-induced
cycle
utilizes the free energy released by water
their corresponding ionic liquid monomers.8
evaporation, and thus, it can avoid the use of
Similar to the fine tunability of ILs9, these
high-grade heat for sorbent regeneration and is
properties of PILs can further be tuned by the choice of cations and anions.
also environmentally benign. Of particular interest in this work is the screening of anions for PIL materials with MSA
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ability for CO2. Previous studies have shown
confined space, Shi et al.19 found that the free
that the type of anion plays a key role in
energy of CO32- hydrolysis in nanopores
defining the PIL features.12 After introducing
decreases
CO32- or OH- anions into P[VBTEA], the
availability.
sorbents exhibited such strong CO2 affinity that
structures, especially the types of anion, of
they were proposed for directly capturing CO2
quaternary-ammonium-based PILs would affect
from the ambient air (400 ppm).11,13-16 For
the
quaternary-ammonium-based salt hydrates with
capture remains unknown. Therefore, extensive
F- or acetate (Ac-), the CO2 absorption capacity
work is required to reveal the relationship
was observed to be affected by the hydration
between the structural and physicochemical
state17, which is similar to the MSA. The CO2
properties
adsorption isotherms indicate that they are
theoretical approaches.
with
the
decrease
However,
moisture-swing
of
the
chemical
performance
PILs,
for
especially
microscopic
MSA, several theoretical studies have been
physicochemical
conducted
on
reaction
ammonium-based PILs during CO2 adsorption.
pathways
and
Density
Quaternary-ammonium-based
energy.
insights
aim
through
sources (15-100 kPa).17 To gain insight into the
hydration
we
CO2
In
interactions,
work,
water
suitable for gas separation from concentrated
ionic
this
how
in
into
properties
to
the of
provide structure-
quaternary-
PILs
with
functional theory (DFT) calculations by Wang
different counter anions for CO2 capture are
et al.18 demonstrated the reaction pathways of
systematically
proton transfer for the PIL with the anion CO32-.
calculations. The counter anion should come
The results showed that the hydrated water acts
from weak acid, which have the ability of
as both a reactant and a catalyst during CO2
bonding hydrogen in water to show some
adsorption. By building a molecular dynamic
basicity
model for ion pairs of the quaternary-
Carbonate, fluoride and acetate are chosen as
ammonium cation (N(CH3)4+) and CO32- in a
counter anions because they are representative
to
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investigated
react
with
through
CO2
DFT
chemically.
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anions with different basicity, valence and water
layered
affinity. The free energy of CO2 adsorption,
molecular mechanics) method22 was employed,
hydration energy and reaction pathways are
wherein the model compounds were separated
highlighted to evaluate the effect of the anions
into three layers with different calculation
on the CO2 adsorption performance of PILs.
methodologies (Figure 1). The high layer
These findings could pave the way toward
included anions, CO2 and hydrated water, which
determining
a
are the most active sites for CO2 adsorption18.
moisture-swing sorbent with specific adsorption
The medium layer included the quaternary
thermodynamics and kinetics.
ammonium cation, which directly interacts with
the
optimal
structure
of
integrated
molecular
orbital
and
the components of the high layer. The low layer
2. METHODS refers to the backbone of the PILs, which is The finite oligomer method20,21 was employed to calculate the electronic structure of the PILs. The sorbent material studied in this work is a polymer whose repeating unit is shown in Figure 1. The backbone of the PILs is polystyrene, and the quaternary ammonium cation is connected to it by a covalent bond. The counter anions interact with the cation through ionic bonds. Carbonate, fluoride and acetate were chosen as counter anions. Bicarbonate, bifluoride and hydroxide were also studied as
common polystyrene. The DFT-D3 method23 was employed for the high-layer calculations, which could take the long-range dispersion energy into account. The MP2 method was employed
CO2
adsorption.
To
reduce
the
single-point
energy
calculation of the high layer, because it was considered to be similarly accurate to the CCSD method.24,25 All the calculations in this work were carried out using the Gaussian09 software package.26 All calculation details can be found in the Supporting Information.
counter anions, as they are possible products after
for
the
computational cost, the ONIOM (our own n-
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can be disturbed by hydrated water, which is bonded to anions through hydrogen bonding (Figure 2). And parts of negative charges of the anions (qH2O) are transferred to the hydrated water. On the other hand, the hydrated water has a high dissociation potential owing to its strong Figure 1. Chemical structures of the model
hydrogen bond29,30, which would change the
compound
quaternary-ammonium-based
chemical properties of the ion pairs. Fluoride
PILs along with the definitions of the different
has the strongest hydrogen bond with hydrated
layers used in the ONIOM method.
water among the three anions, as it has
of
relatively large negative charges and three lone electron
3. RESULTS AND DISCUSSION
pairs.
Acetate
has
the
weakest
hydrogen bond because of the small negative 3.1. Optimized structures of hydrated PILs charges remaining for its oxygen atom. The optimized structures of PILs with different anions and hydrated water are shown in Figure 2. The consistency between the characteristic peaks of the functional groups in the calculated values of the model compounds and the experimental values of the corresponding PILs verifies the reliability of the model compounds and our computational methods (see Figure S1). Strong interactions are found between anions and the cation, which are mainly attributed to the
electrostatic
interaction
of
the
ionic
Figure 2. The optimized structures of the model compounds of PILs with hydrated water. The dashed line represents the hydrogen bond between the anions and hydrated water. The red arrow shows the direction of the movement of the proton in hydrated water due to the
bond27,28. The symmetric structures of ion pairs ACS Paragon Plus Environment
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hydrogen bond. qH2O represents the negative
mechanism of a Brønsted base can be expressed
charges transferred to the hydrated water from
as Reaction (1-3)17,18,34,35: N+CO32-N+·H2O + CO2 = 2N+HCO3-
the anion.
N+F-·H2O + CO2 + N+F- = N+HCO3- + N+F2H3.2. Hydrated PILs break the relationship
N+CH3COO-·H2O + CO2 = N+HCO3- + CH3COOH The
between pKa and CO2 affinity.
thermodynamic
properties
of
CO2
Anions should be the most chemically active
adsorption under the two different mechanisms
sites for CO2 adsorption by quaternary-
are shown in Table 1. The calculated results
ammonium-based PILs, as indicated by the
show that the Brønsted base mechanism is
frontier molecular orbitals of the optimized
qualitatively
structures (Figure S3). The anion could react
experimental values. Under the Brønsted base
with CO2 due to its properties as a Lewis base31
mechanism, water would have a distinct effect
or a Brønsted base32. In the case of a Lewis
on CO2 adsorption, as can be seen from the
base, the anion has lone pairs of electrons and
relationship between the standard Gibbs free
can react directly with CO2, as shown in Figure
energy change (∆G0) and pKa. Generally, the
S4, which is the reaction mechanism of CO2
values of ∆G0 and pKa are positively related.36
adsorption by monoamines33. In the case of a
However, fluoride has the smallest pKa value,
Brønsted base, the anion could accept a proton
but its CO2 affinity is moderately strong as a
from hydrated water through a hydrogen bond.
counter anion for PIL. The pKa value is an index
This could transform PILs into an intermediate
to express the basicity of an anion in aqueous
state with a hydroxide anion, which has strong
solution. For PILs with a low hydration state,
basicity and would easily react with CO2 to
this ion could demonstrate unique hydration
produce a bicarbonate anion. The overall
properties37, e.g., sharply decreased permittivity
reactions between PILs and CO2 under the
and increased hydration energy with decreased
consistent
with
the
reported
hydration number38. Compared with acetate, the
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three lone pairs of electrons of fluoride could
which indicates a potential application for CO2
strongly attract the proton of hydrated water,
capture from a dilute source, e.g., air. The PILs
which could lead to a stronger Brønsted base
with fluoride and acetate as the counter anions
effect and stronger CO2 affinity. Based on the
adsorb CO2 with a relatively weak affinity,
value of ∆G0 under the Brønsted base
which consequently could be applied to an
mechanism, the CO2 partial pressures at
environment with a relatively higher CO2
equilibrium (PCO2) were calculated. For the PIL
concentration, e.g., flue gas.
with carbonate, the PCO2 is tens of pascals,
Table 1. Thermodynamic properties of CO2 adsorption by PILs Counter Anion
∆G10 a (kJ/mol)
∆G20 b (kJ/mol)
∆Gexp (kJ/mol)
pKa c
PCO2 d
CO32-
0.51
-23.92
-17.05 e
10.33
24 Pa
F-
-1.22
-12.37
-10.31 f
3.18
3.88 kPa
Ac-
2.37
1.53
2.12 f
4.76
1.77 MPa
a
∆G0 via Lewis base mechanism obtained from theoretical calculations. b ∆G0 via Brønsted base mechanism obtained from theoretical calculations. c The pKa values of the anions in aqueous solution are taken from ref. 39. d Partial pressure of CO2 when 90% of available adsorption sites are covered under standard reference conditions. Langmuir adsorption is assumed; see the Supporting Information for details. e Experimental value taken from ref. 40. f The values are calculated using experimental results of the CO2 adsorption capacity and equilibrium partial pressure taken from ref. 17.
3.3. Hydration energy of PILs determines the
the PIL is considered to react with CO2 as a
capacity of moisture-swing adsorption.
hydrate18, as shown in Reaction (4):
To evaluate PILs as a MSA sorbent, an important indicator is the capacity of moisture
N+R-·aH2O + CO2 = N+P-·bH2O + (a-b-1)H2O where
N+
represents
the
quaternary
swing, which can be measured by the variation
ammonium cation and the backbone covalently
in the equilibrium partial pressure of CO2 when
linked to it; R- denotes the anion before
the humidity changes. Under a certain humidity,
adsorption; P- represents the anion after the
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reaction; and a and b are the hydration numbers.
illustrated in Figure 3. According to Hess’s
The reactant anion and product anion usually
Law, the CO2 adsorption under a given
have different water affinities, which result in
humidity could be divided into three elementary
releasing or adsorbing gaseous water during
reactions, i.e., the dehydration of the reactant
CO2 adsorption. By assuming a Langmuir-type
(Reaction A in Figure 3(a)), CO2 adsorption
adsorption, the equilibrium partial pressure of
under a base hydration state (Reaction B) and
CO2 can be derived from ∆G0.
hydration
of
the
product
(Reaction
C).
The calculated energies and capabilities for
Therefore, the difference in ∆G0, i.e., (∆Gw0-
moisture swing of the PILs in this work are
∆Gd0), is equivalent to the sum of the free
shown in Table 2, which demonstrates the
energy changes of the reactant dehydration (-
significant difference between the swing size of
∆Gr-h) and that of the product hydration (∆Gp-h)
the PILs. Under the same coverage fraction, the
between the dry and wet states. As listed in
CO2 partial pressure over the PIL with carbonate
Table 2, the difference in ∆G0 for the PIL with
increases from 0.15 kPa to 15 kPa when the
carbonate anions is dominated by the free
humidity
evident
energy change of the reactant dehydration (-
moisture swing is observed in the case of
∆Gr-h). In the case of fluoride, both ∆Gr-h and
acetate. Intuitively, the capability for moisture
are ∆Gp-h are relatively large, which results in a
swing arises from the difference between ∆G0
moderate moisture swing size. In the case of
for the dry (∆Gd0) and wet states (∆Gw0). The
acetate, ∆Gr-h and ∆Gp-h are similar, and thus,
hydration process of PILs suggests several
no evident moisture swing would be observed.
changes.
However,
no
thermodynamic pathways for reaction (4), as
Table 2. Properties of the moisture swing of PILs with different counter anions
Counter Anions
∆G0 (kJ/mol)
a
PCO2 (kPa)
b
∆Gr-h c ∆Gp-h d Swing Size e (kJ/mol) (kJ/mol)
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CO3
-
F
-
Ac
2-
Dry f
-21.64
0.15
Wet g
-10.21
15.01
Dry f
-11.27
9.82
Wet g
-9.02
24.19
Dry f
1.536
1667
Wet g
1.543
1672
-19.17
-7.74
100.01
-21.60
-19.35
2.46
-7.75
-7.74
1.003
a
∆G0 obtained from theoretical calculations; see the Supporting Information for details. b Partial pressure of CO2 when 90% of available adsorption sites are covered under standard reference conditions. c Free energy change of reactant hydration from dry to wet. d Free energy change of product hydration from dry to wet. e The swing size is defined as the ratio between the equilibrium CO2 partial pressures under the wet and dry conditions. f The dry condition refers to a relative humidity (RH) of 1% at a temperature of 25 °C. g The wet condition denotes a RH of 100% at a temperature of 25 °C. moisture swing. The difference in ∆G0, i.e., (∆Gw0-∆Gd0), is equivalent to the sum of the free energy changes of the reactant dehydration (-∆Gr-h) and that of the product hydration (∆Gph)
between the dry and wet states. (b) Calculated
standard Gibbs free energy change of hydration reactions for PILs with different anions as a (a)
function of the number of hydrated water
0
molecules. ∆ G (kJ/mol)
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-10
The
hydration
properties
are
completely different for PILs with different counter anions.
PIL-Carbonate PIL-Fluoride PIL-Acetate PIL-Bicarbonate PIL-Bifluoride
-20
In screening CO2 sorbents with large
-30 0
1
2 3 4 5 Number of hydrated water (b)
6
7
Figure 3. (a) Thermodynamic cycles to show that the difference of the hydration properties between reactant and product is the origin of
moisture swing capability, the potential PIL candidate should possess a high absolute value of ∆Gr-h and a low absolute value of ∆Gp-h. As shown in Figure 3(b), for PILs with carbonate
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and fluoride, the water affinity of these reactants
In the Type I distribution, each hydrated
is strong and decreases sharply as the number of
water molecule directly interacts with a counter
hydrated water molecules increases, which
anion, which results in a high hydration energy.
generates a high value of ∆Gr-h. In addition, the
The PIL with carbonate as the counter anion has
hydration energy of their product is relatively
the strongest affinity to water because of the
small and decreases slightly as the number of
large negative charges on the anion. The
hydrated water molecules increases, which
hydration energy of the PIL with carbonate
generates a low value of ∆Gp-h. The above
decreases sharply as the number of hydrated
phenomenon indicates that the hydrophilic
water molecules increases, since the carbonate
property of PILs changes significantly during
anion interacts with two quaternary ammonium
CO2 adsorption.
cations, and remaining free sites that can
To further elucidate the mechanism of this
interact with hydrated water are limited. The
hydrophilic property change, the optimized
PIL with fluoride as the counter anion has the
structures of PILs with three hydrated water
second strongest water affinity because of the
molecules are shown in Figure 4. According to
intrinsic strong potential of fluoride to attract
the relative positions between the hydrated
protons44. The hydration energy of the PIL with
water and counter anions, two types of hydrated
fluoride decreases moderately owing to the
water distribution are highlighted. For PILs with
three lone pairs of electrons on fluoride and
carbonate, fluoride and bifluoride as counter
sufficient free space around the fluoride ion.
anions, the hydrated water is uniformly located
The PIL with bifluoride has a moderately strong
around the anion (Type I). In contrast, in the
water affinity due to the strong intramolecular
cases of acetate and bicarbonate, the hydrated
hydrogen bond formed between the two fluoride
water forms hydrogen bonds between other
ions. The hydration energy of the PIL with
water
bifluoride decreases slowest with the increase in
molecules,
which
association41-43 (Type II).
is
called
self-
the number of hydrated water molecules
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because the two fluorine atoms in the anion could serve as active sites to interact with the hydrated water. The hydrated water tends to form a Type II distribution because the negative charges on the anions are small, and the affinity of the anions to hydrated water is weak. The intermolecular hydrogen bonds formed during self-association could partly offset the decrease in the hydration energy when the number of hydrated water molecules increases. Therefore, the hydration energy of the PILs with bicarbonate and acetate decreases gently. An ideal MSA sorbent should possess a Type I distribution for the reactant and a Type II distribution for the product. Note that the hydrophilic property of PILs can be tuned by
Figure 4. Optimized structures of PILs with three hydrated water molecules. The hydrated water molecules self-associate or form clusters in PILs with acetate or bicarbonate, while the hydrated water molecules locate around the anion uniformly in the cases of carbonate, fluoride and bifluoride.
screening not only anions but also other factors,
3.4. Two-step reaction pathways of the
e.g., cations and the polymer backbone45.
Brønsted base mechanism. As discussed in Section 3.2, PILs with basic counter anions adsorb CO2 through the Brønsted base mechanism, wherein one proton of the hydrated water is transferred to the anion, and a strongly basic hydroxide anion is produced.18 However, the hydration properties and reaction pathways
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of
CO2
adsorption
can
differ
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dramatically for PILs with different anions46,
instead of one step (Figure 6; detailed
which
information on the structural parameters is listed
could
result
in
different
kinetic
performance.
in Table S3), which would significantly lower
Figure 5 shows the reaction pathways and
the activation energy47. On the other hand, a
the corresponding potential energy profiles for
two-step
CO2 adsorption by PILs with different anions.
quaternary ammonium cations are involved in
For the PILs with fluoride and carbonate, CO2 is
the reaction pathways. The repulsion between
adsorbed through a two-step mechanism. In this
these two cations could promote the dissociation
mechanism, a steady intermediate (IM) with a
of hydrated water.48,49
mechanism
implies
that
two
high energy is produced before adsorbing CO2,
As shown in Figure 6, the PIL with fluoride
and two quaternary ammonium cations are
also has the potential to adsorb CO2 through a
required
one-step mechanism, similarly to acetate (see
to
adsorb
one
CO2
molecule.
Meanwhile, in the case of acetate, CO2 is
Figure
absorbed in one step, wherein the dissociation
geometries), since both fluoride and acetate
of hydrated water coincides with the production
anions have a maximum of one negative charge.
of bicarbonate, and no IM is found in this
However, the activation energy of the one-step
mechanism.
is
reaction pathway for the PIL with fluoride is
advantageous for CO2 adsorption, because only
14.61 kJ/mol higher than that of the two-step
one acetate anion is required to adsorb one CO2
reaction pathway, which indicates that the two-
molecule. However, the activation energy of
step
this mechanism is higher than that of the two-
feasibility of the two-step mechanism could be
step mechanism, which is a disadvantage.
attributed to the intrinsic proton-attraction
Through the two-step mechanism, the huge
property of fluoride44, which will result in a
structural variations due to CO2 adsorption are
reaction between the hydrofluoric acid molecule
accomplished with two small successive steps
thus formed and fluoride to generate a
This
one-step
mechanism
S6
for
mechanism
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its
optimized
reaction
is more favorable.
The
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Reaction
pathways
and
the
bifluoride anion. The PIL with acetate would
Figure
not easily adsorb CO2 through the two-step
corresponding potential energy profiles for CO2
mechanism, because the steric hindrance of
adsorption by PILs with different anions. RC,
acetate anion50,51 would prevent the formed
TS, IM and PC are abbreviations for reactant
acetic acid molecule from bonding with another
complex, transition state, intermediate state and
acetate anion.
product complex, respectively. The PILs with
5.
carbonate or fluoride adsorb CO2 via two steps with an intermediate state, while the PIL with acetate adsorbs CO2 via one step with a high activation energy. Energy values were corrected by ZPVE.
Figure 6. Optimized reaction geometries of two different reaction pathways for CO2 adsorption by the PILs with fluoride. The arrows and values under the panels show the variations in the key structural
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parameters during CO2 adsorption. The structural variation of the one-step mechanism is larger than that of the two-step mechanism, which results in the higher activation energy. suitable for capturing CO2 at a high partial pressure because of its large capacity and its
4. CONCLUSIONS Quaternary-ammonium-based
PILs
are
promising sorbents for CO2 capture. In this work, theoretical studies were performed to systematically investigate the effect of varying the counter anion on CO2 adsorption. Our results showed that the PIL with carbonate as the counter anion has the lowest activation energy, strongest CO2 affinity and largest swing size, and it functions through a two-step mechanism, which indicates that it is a better candidate as a sorbent to capture CO2 from ultra-low concentration mixtures, such as that of air. The PIL with fluoride as the counter anion has a low activation energy, strong CO2 affinity, medium-to-large swing size, and it adsorbs CO2 through a two-step mechanism, owing to the
feasibility
to
be
regenerated
through
conventional approaches. Further investigations revealed that the repulsion between the two quaternary ammonium cations, which interact with the carbonate anion or two fluoride anions, could promote the dissociation of hydrated water and lower the activation energy of the CO2 adsorption. The two-step reaction pathways also exhibit low activation energy owing to the relatively small structural changes of each step. Our findings could provide a fundamental understanding of CO2 capture by quaternaryammonium-based PILs and pave the way toward determining the optimal structure of a PIL to be used for CO2 capture in specific circumstances.
unique ability of fluoride to strongly attract
ASSOCIATED CONTENT
protons. The PIL with acetate as the counter
SUPPORTING INFORMATION.
This material is available free of charge via the anion has a high activation energy, weak CO2 Internet at http://pubs.acs.org. affinity and small swing size, and functions with a one-step mechanism, which indicates that it is ACS Paragon Plus Environment
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Computational
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details,
calculation
of
equilibrium parameters and number of hydrated water molecules, Figure S1-S7, Table S1-S3.
Report of the Intergovernmental Panel on Climate Change, 2014. (2) Wang, J.; Huang, L.; Yang, R.; Zhang, Z.;
AUTHOR INFORMATION
Wu, J.; Gao, Y.; Wang, Q.; O'Hare, D.; Zhong,
Corresponding Author
Z., Recent advances in solid sorbents for CO2
*
[email protected] capture and new development trends. Energy Environ. Sci. 2014, 7, 3478-3518.
*
[email protected] (3) Cogswell, C. F.; Jiang, H.; Ramberger, J.;
Notes The authors declare no competing financial
Accetta, D.; Willey, R. J.; Choi, S., Effect of Pore
interest.
Structure
on
CO2
Adsorption
Characteristics of Aminopolymer Impregnated ACKNOWLEDGMENT
MCM-36. Langmuir 2015, 15, 4534-4541.
This study is supported by the National Natural Science Foundation of China (No.
(4) Wang, Q.; Luo, J.; Zhong, Z.; Borgna, A.,
51676169) and the Fundamental Research
CO2 capture by solid adsorbents and their
Funds for the Central Universities.
applications: current status and new trends. Energy Environ. Sci. 2011, 4, 42-55.
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