ionic liquid-based composite thin-films for selective ion
Post on 05-Dec-2021
6 Views
Preview:
TRANSCRIPT
University of Mississippi University of Mississippi
eGrove eGrove
Electronic Theses and Dissertations Graduate School
2019
Ionic Liquid-Based Composite Thin-Films for Selective Ion Ionic Liquid-Based Composite Thin-Films for Selective Ion
Separations in Electrodialysis Separations in Electrodialysis
Saloumeh Kolahchyan University of Mississippi
Follow this and additional works at: https://egrove.olemiss.edu/etd
Part of the Chemical Engineering Commons
Recommended Citation Recommended Citation Kolahchyan, Saloumeh, "Ionic Liquid-Based Composite Thin-Films for Selective Ion Separations in Electrodialysis" (2019). Electronic Theses and Dissertations. 1619. https://egrove.olemiss.edu/etd/1619
This Thesis is brought to you for free and open access by the Graduate School at eGrove. It has been accepted for inclusion in Electronic Theses and Dissertations by an authorized administrator of eGrove. For more information, please contact egrove@olemiss.edu.
IONIC LIQUID-BASED COMPOSITE THIN-FILMS FOR SELECTIVE ION SEPARATIONS
IN ELECTRODIALYSIS
A Thesis
Presented for the Degree of
Master of Science in Engineering Science
Department of Chemical Engineering
The University of Mississippi
Saloumeh Kolahchyan
December 2018
Copyright © 2018 by Saloumeh Kolahchyan
All rights reserved
ii
ABSTRACT
The onset of climate change and rising global population has caused greater water scarcity,
a considerable problem which threatens our world. The demand for fresh water is pushing a fast
development of water purification technologies. Among these technologies, membrane-based
water desalination processes are playing an interesting role in both academia and industry.
Electrodialysis (ED) is an electro-membrane separation process aimed at water treatment through
ion removal, which is achieved through the selective control and transport of ionic species. ED is
a popular water treatment method; however, it is limited by membrane scaling, lack of ion
selectivity, and high energy consumption for high salinity feeds. This study is focused on the
synthesis of unique ionic liquid-based anion exchange membranes in order to obtain ion-selectivity
in Electrodialysis (ED) systems through the addition of a divalent ion repulsion layer. Thin films
of polymerizable ionic liquids were coated and cured on the anion exchange membranes in order
to enhance ion selectivity in (ED) system. The membrane characteristics were studied through
FTIR, SEM, AFM, contact angle measurement, and ED performance. Results suggest that while
imidazolium coatings were incompatible with ED system due to rapid degradation, phosphonium
coatings exhibited enhanced monovalent ion selectivity.
iii
DEDICATION
To my loving husband, Abolfazl, and my family for their unending support along the way.
iv
LIST OF ABBREVATIONS AND SYMBOLS
ED Electrodialysis
EDI Electrodionization
IL Ionic Liquid
PIL Poly/Polymerized Ionic Liquid
BMED Bipolar Membrane Electrodialysis
AEM Anion Exchange Membrane
CEM Cation Exchange Membrane
v
ACKNOWLEDGEMENTS
I would like to acknowledge my advisor, Dr. Alexander Lopez, for his support and
mentorship during my graduate career.
I would like to acknowledge my committee members Dr. Paul Scovazzo and Dr. Sasan
Nouranian for their support, guidance, and feedback throughout my graduate career.
I would like to acknowledge undergraduate students Matthew Edwards and Madelyn
Barber who I had the pleasure to mentor during their studies.
Special thanks to the University of Mississippi Graduate School for funding this degree.
vi
TABLE OF CONTENTS
ABSTRACT…………………………………………………………………………………… ii
DEDICATION………………………………………………………………………………… iii
LIST OF ABBREVIATIONS AND SYMBOLS……………………………………………… iv
ACKNOWLEDGMENTS…………………………………………………………………….... v
LIST OF TABLES…………………………………………………………………………...… vii
LIST OF FIGURES……………………………………………………………………………. viii
INTRODUCTION……………………………...………………………………………………… 1
BACKGROUND……………………………………………………………………...………….. 9
EXPERIMENTAL………………………………………………………………...……………. 23
RESULTS AND DISCUSSION………………………………………………………………… 29
SUMMARY AND CONCLUSION……………………………...…………………..…………. 36
FUTURE WORK ………………...……………………………...…………………………..…. 37
LIST OF REFERENCES……………………………………………………………………….. 38
APPENDIX ………………………………………...………………….……………………….. 48
VITA…………………………..…….………………….………………...…………………….. 51
vii
LIST OF TABLES
1. Table 1-1. Processes using IEMs………………….…………….…………………..…..…….. 5
2. Table 3-1. Detailed Specification of Ion Exchange membranes…………….…..…………… 24
3. Table 4-1. Contact Angle measurements of the membranes...…………………….….……… 32
4. Table 4-2. Transport number ratios for the membranes………….……………....................... 33
viii
LIST OF FIGURES
Figure 1-1. SEC comparison between ED, EDI and RO ................................................................ 3
Figure 1-2. Polymerization of ILs. .................................................................................................. 8
Figure 1-3. An AEM before and after the modification. ................................................................ 9
Figure 2-1. Electrodialysis configuration ..................................................................................... 11
Figure 2-2. Schematic of Electrodionization Configuration. ........................................................ 13
Figure 2-3. Bipolar Membrane Electrodialysis Configuration ..................................................... 14
Figure 2-4. Schematic of the concentration gradients adjacent to a single cationic membrane in an
ED stack ........................................................................................................................................ 17
Figure 2-5. Typical current-voltage curve for an IEM immersed in an electrolyte solution. ....... 17
Figure 3-1. Schematic of the 1-methyl-(4-vinylbenzyl) imidazolium bis (trifluoromethylsulfonyl)
imide synthesis .............................................................................................................................. 25
Figure 3-2 . Schematic of the Trioctyl-3-(4-vinylbenzyl)phosponium bis (trifluoromethylsulfonyl)
imide synthesis .............................................................................................................................. 26
Figure 4-1. Overlay of the IR spectra of IL and PIL.The change in C=C stretch 900-930 cm-1 in
polymer indicates the degree of polymerization which is 68% for [VBMIM][TF2N] and 75% for
[P888VB][TF2N]. ......................................................................................................................... 30
Figure 4-2 . Delamination of [VBMIM][TF2N] PIL from ASE membrane surface. .................... 31
Figure 4-3. SEM images of the a) pristine and b) [P888VB][TF2N] coated membranes ............ 31
ix
Figure 4-4. AFM images showing non-uniform coated layer of the [P888VB][TF2N] on the AEM
surface.. ......................................................................................................................................... 31
Figure 4-5. Comparing a) average selectivity, b) average transport number and c) average current
efficiency of the pristine and modified membrane. The average monovalent selectivity has been
increased by 23%, average transport number by 24% and average current efficiency by 30%. The
error bar is showing the standard deviation error. ........................................................................ 33
Figure 4-6. Conductivity reduction over time in ED. a) Imidazolium and phosphonium coated
membrane(20 µm) performance compared to pristine membrane b) Phosphonium coated (15 µm)
performance compared to pristine membrane ............................................................................... 35
1
CHAPTER I
INTRODUCTION
Motivation for Wastewater Treatment through Membrane Separations
The onset of climate change, rising population and urbanization has caused greater water
scarcity around the world. Currently, two-thirds of the global population live under severe water
shortage conditions during at least part of the year [1]. Increasing competition over water due to
increased demands for industrial and agricultural purposes, water pollution, economic growth and
population growth are the main factors affecting the global water resources [2]. In addition,
according to a WHO/UNICEF JMP (Joint Monitoring Programme) report in 2017, 844 million
people do not have access to the clean water which results in water-related illnesses and deaths.
Consequently, solving the water-related hygiene issues and finding unconventional sources of
fresh water is pushing a fast development of water production technologies.
Recently, there has been growing appeals for water treatment technologies in order to
reduce the use of natural water sources and provide a solution to the water contamination issue.
Recycling and reuse of water through efficient water treatment technology can be a great reduction
in water resources utilization [3]. Hence, a variety of water treatment methods such as Distillation,
Flocculation, Ion Exchange, Anaerobic Digestion, Reverse Osmosis (RO), Electrodialysis (ED),
Electrodionization (EDI) and Micro/Nano-filtration have been studied .Membrane-based
separation processes are capable of replacing traditional energy-intensive separation techniques,
such as evaporation and distillation. They are known as “Green” Technologies because of their
2
energy efficiency and environment friendly characteristics. It is also possible to achieve a higher
selectivity, recovery factor, improved water quality, and cost reduction through combination of
different membrane operations. These advantages along with water scarcity and high energy
consumption of traditional separation processes soothed the development and commercialization
of membrane-based water treatment methods during the last 40 years [4].
Membrane-based separation processes have played a leading role in both academia and industry
in terms of water treatment applications. In the field of brackish water desalination, RO holds 60%
to 90% of the global demand. In Gulf countries, multiple stage Distillation and Flash technologies
are still popular due to the large availability of the heat needed for powering the thermal
evaporative systems [5]. Electro-membrane processes, such as, ED and EDI have a small but stable
market, especially in low salinity desalination applications [6]. The specific applications of electro-
membrane processes are expanding by developing new IEMs and devices, which enlarges the
potential for the application of these flexible technologies.
Electrodialysis, a Mature Technology for Wastewater Treatment
ED is an electro-membrane separation technique in which charged membranes are used in
an alternate arrangement built on a plate and frame module. When an electrical potential is applied
to the system, ions migrate towards the electrodes through semi-permeable membranes. The
alternate pattern of the charged membranes, allows ions removal from one solution in to another
[7], [8]. Due to its wide range of application, Electrodialysis has been maturing with a wealth of
well-understood methods over the past 60 years. Reverse Electrodialysis (RED),
Electrodionization (EDI) and Bipolar Membrane Electrodialysis (BMED) are some modified
version of ED system, being invented due to the specific applications. RED is the use of natural
salinity gradients to create an electric current as opposed to using a current to create a salinity
3
gradient [9]. In EDI, ion exchange resins are used in the solution compartments in order to enhance
the solution conductivity and it is useful when ultrapure water or high ion removal is needed [10].
ED can be used in combination with bipolar membranes (BMED) for the production of acids and
bases from waste water containing salts [11]. In some specific industrial applications, the features
of ED (or EDI) are more favorable than RO; For instance:
1. In pharmaceutical and food industry for applications such as deacidification of fruit
juices, demineralization of whey protein, and removal of sodium from products
2. In electrical industry for ultra-pure water production [12]
3. Selective electrodialysis for selective salt separation from saline streams [13]
The popularity of ED in food and pharmaceutical industry stems from its ability to keep the health
and nutritious properties of the final product and not endangering it by for example adding
coagulants or regenerating agents. For separation at low salinities, ED and EDI are more suitable
Figure 1-1. SEC comparison between ED, EDI and RO. Reprinted from [14]
than RO. However, at high salinities, ED and EDI demonstrate high Specific Energy Consumption
(SEC) which makes them uncompetitive for use in water recovery. Therefore, ED and EDI are
4
practical options for brackish water production as long as feed salinities are below 9000 ppm.
[14][15]. Figure 1-1 shows the two regimes where the ideal separation process can be determined
from feed condition. As the feed salinity decreases, ED and EDI become more favorable. However
at moderate and high salinities RO is favored.
Ion Exchange Membranes (IEMs): Charged Polymer Films for Perm-selective
Separations
IEMs are dense polymeric membranes containing fixed charged groups in the polymer
backbone. Depending on the type of the charged groups attached to the polymer matrix, IEMs are
either Cation Exchange Membranes (CEMs) or Anion Exchange Membranes (AEMs). AEMs
consist of positively charged groups, such as –NH3+, –NRH2
+, –NR2H+, –NR3
+, –PR3 +, etc.,
attached to the membrane backbone. They allow the passage of anions but reject cations. While
CEMs consist of negatively charged groups, such as –SO3-, –COO-, –PO3
2−, –PO3H−, –C6H4O
−,
fixed to the membrane backbone and allow the passage of cations but reject anions [16][17]. When
IEMs contact an ionic solution, they exclude co-ions (ions of the same charge as the fixed ions in
the membrane) partially or completely from the membrane. Because of their perm-selectivity,
IEMs are utilized in several industrial applications. Table 1 shows different processes that employ
IEMs. Innovative research ideas has been developed by researchers on the characteristics of the
IEMs in terms of efficiency, cost, and application [16]. Ion selectivity of IEMs plays a key role in
expanding the application of these membranes and several industrial processes based on IEMs
exist. For instance, in processes such as microbial fuel cells, ion exchange membrane bioreactors,
diffusion dialysis, and flow batteries, high membrane perm-selectivity between counter-ions of
different valences is crucial for system efficiency [18]. In addition, in some applications of treated
5
water separation of monovalent ions, such as K+, Na+, NH4+, NO3−, and Cl− versus multivalent
ions Mg2+, Ca2+, PO43, and SO4
2- is also important [19].
Table 1-1. Processes using IEMs [12]
Process Application
Electrodialysis Water desalination, NaCl production
Flow batteries Energy storage and conversion
Electrodionization Water desalination
Reverse Electrodialysis Electricity Production
Microbial Fuel Cells Waste biomass treatment, energy conversion
Ion Exchange Membrane Bioreactor Water treatment
Seta et al. studied such monovalent ion selectivity in ED system through incorporation of
modified IEMs. In general, the mono/multivalent ion selectivity mechanisms are governed by
exclusion, size and electrostatic repulsion [20]. Consequently, various membrane surface
modification methods such as,
formation of a highly cross-linked layer,
introduction of a weakly basic anion exchange group layer on the membrane
surface and controlling the hydrophilicity of the membrane
formation of condensation-type polymer-aromatic amines and formaldehyde on
the membrane surface or in the membrane matrix,
have been studied in order to obtain monovalent ion selectivity in IEMs [21][22]. However, a
challenging problem which arises in this domain is that most of the materials used are either
expensive or hazardous. There is also a further problem with undesired membrane resistance that
can happen by introducing a highly cross-linked layer on the membrane. Therefore, there is a
6
demand to advance the development of mono/multivalent ion selective IEMs. In the present work,
we aim to achieve a monovalent ion selectivity in AEM through incorporation of ionic liquids in
electrodialysis system for water treatment applications.
Ionic Liquids; Room Temperature Molten Salts
Ionic Liquids (ILs) have been attracting researchers for decades due to the many unique
properties they possess. They present negligible vapor pressure, which makes them non-flammable
and are able to dissolve a large variety of organic and inorganic compounds (polar or non-polar).
They display good conductivity which is useful in electrodialytic separation applications. ILs are
molten salts at room temperature due to bulky cation and anion structures [23]. Previous studies
show that ionic liquids can provide a wide range of application in chemical industries, such as, a
good solvent for gas separation, extraction, and other separation processes as well as a liquid
electrolyte in a battery and electrolysis process for their good conductance and stability. The most
important factors building the relationship between properties and structures of ILs are melting
point, viscosity, and conductivity. Cations and anions play a key role in designing the suitable IL.
For instance, the viscosity of the ILs is significantly dependent on the nature of the anions [24],
(eg. ILs containing [TF2N]- anion have a lower viscosity compare to those containing [PF6]). This
is suggested to be related to the shape, size, molar mass and H-bond capability of the anion.
Smaller, lighter, and more symmetric anions present more viscous ILs. The low melting point of
ILs is related to the size, anisotropy, and internal flexibility of the ions. ILs with 4 to 10 N-alkyl
chains have a wide liquid range with low melting points [25]. The conductivity of ILs is mainly
important in electrochemical processes. Due to their salty structures, they have many charge
carriers per mole, which makes them amongst the most concentrated organic electrolytes.
7
Imidazolium-based ILs present high conductivity while quaternary ammonium ILs exhibit lower
conductivity. The conductivity of ILs has an inverse relationship with their viscosity [26].
The presence of water in ILs can considerably influence the viscosity, conductivity,
polarity and solubility of other materials in ILs. T.Welton et al found that anions are mainly
responsible for the solubility of water. For example, imidazolium-based ionic liquids demonstrate
different water solubility depending on the anion; [BF4]-, [NO3]
-, and [ClO4]- are more water
soluble, while [PF6]-, [SbF6]
-, [OSO2CF3]-, [OCOCF3]
-, and [TF2N]- have less water solubility [
25].
In some applications such as small electronics devices, where ILs features are extremely
favorable, film like electrolyte materials are required. Therefore, it is interesting to have ILs with
polymerizable groups [28]. Polymerized ionic liquids (PILs) are a relatively new class of IL-based
materials. They present a macromolecular structure which contains an ionic liquid (IL) monomer
in each repeating unit, connected through a polymeric backbone. The most common way of
polymerization is chain polymerization of IL monomers, which is described in Figure 2.
Depending on the desired poly ionic liquid architecture, the polymerizable unit can be located
either on the anion or cation. PILs are primarily used for gas separation membranes and ion
conductive mediums in fuel cells [29]. Some other applications of PILs include: absorbent,
precursor for carbon materials and porous polymers, powerful dispersant and stabilizer. The main
reasons of using PILs instead of ILs are further mechanical stability, durability, and enhanced
processability. Research reports that the ion mobility of PILs are at least two magnitudes lower
than the corresponding IL monomer. Because for example, the mobility of the cation species after
the polymerization of cations is negligible and the formed PIL can act as a single-ion conductor.
8
In this situation, the movement of the free anions is possible but limited to the free volume between
the polymeric chains, resulting in lower ion mobility and conductivity [30].
Figure 1-2. Polymerization of ILs [29]
Purpose and Hypothesis of the Research
The purpose of this research is to obtain a monovalent anion selectivity in ED system
via coating thin ionic liquid based composite thin-films on AEM surface. Selective removal of
target ions from feed solutions, is specifically important in producing high quality water to meet
water standards. Furthermore, monovalent selectivity can be of a great help to prevent scaling on
the membrane. For instance, calcium sulfate can cause serious scaling problems in ED system as
a scale. By making the AEMs impermeable to sulfate ion we can address this issue. The perm-
selectivity of specific anions in to the anion exchange membrane is essentially related to the
negative charge layer on the membrane surface [22]. Compare to monovalent anions, multivalent
anions are less prone to transport on to the membrane surface and according to the Coulomb’s law,
that is due to the higher electrostatic repulsion between a negatively charged surface potential and
multivalent anions compare to the electrostatic repulsion between monovalent anions and a
negatively charged surface potential. To our knowledge, no previous research has investigated the
application of PILs in water separations.
9
Figure 1-3. An AEM before and after the modification
We hypothesize that PIL modification of ion exchange membranes can increase the electrostatic
repulsion of the AEM surface, resulting in monovalent ion selectivity. The electrostatic repulsion
between multivalent anions and a negative surface potential is greater than that between
monovalent anions and a negative surface potential according to Coulomb’s law, which means that
multivalent anions are less likely to transport onto the membrane surface than monovalent anions.
10
CHAPTER II
BACKGROUND
Over the past 60 years, ED and ED-related processes have played an interesting role in
water treatment technologies in terms of flexibility and range of application. In fact, research and
developments on IEMs and ED system optimization are boosting the growth of this technology
globally. In this chapter, a brief background of the ED evolution will be presented.
Electrodialysis: From Early Steps to Commercialization
In 1890, Ostwald, Maigrot and Sabates proposed an Electrodialysis (ED) system for the
first time for the demineralization of the sugar syrup [31]. However, the actual ED was
hypothesized when Donnan presented his exclusion principle in 1911. The Donnan exclusion
principle helped pave the way for the development and manufacture of the first ion exchange
membranes. This advancement opened the way for development of the actual multi-compartment
ED. The first synthetic ion exchange membranes were produced in 1950 by W.Juda and W.A
McRay. Ionics (USA) used them to make the first ED desalination plant for Aramco in Saudi
Arabia [32][7]. Due to the lack of domestic salt sources, Japan has used ED system to concentrate
sea water and produce salt for human consumption. During the 1950s to 1960s, the formation of
scale on the ion exchange membrane surface was a severe problem. That was mainly occurring
due to the unidirectional mode of operation in ED system. In this mode, the polarity of the
electrodes and the position of the dilute and concentrated cells were fixed. Fixing this issue
11
required addition of anti-scaling chemicals to the feed water and pH adjustment. In early 1970s,
Ionics established a breakthrough in ED system design called electrodialysis polarity reversal
(EDR)[33][7]. In this design, the polarity of the DC power applied to the membrane electrodes and
thus, the desalted water and brine chambers are also reversed two to four times per hour. Switching
cells and reversing current direction resulted in scale flushing from the membrane before it can
precipitate and scale the membranes. [8]
Figure 2-1. Electrodialysis Configuration
Electrodionization (EDI)
ED has some limitations in terms of energy efficiency. When ions are depleted in a
solution, more power is needed to move current through that solution which results in larger power
requirements for solutions of low salt content. A solid conductive ion medium introduced into the
dilute compartment in the form of ion exchange resins eliminates this disadvantage. This reliable
technique to treat low electrolyte content solutions is Electrodionization [34]. In 1953, the first patent was
Cathode
CEM CEM AEM
Anode
Concentrate Diluate
Feed Feed
+ -
Na+
Na+
Cl-
SO4
2-
12
applied for an EDI device by a Dutch company which was granted in 1957. They described an
apparatus for the deionization of salt-containing liquids using an alternating pattern of anion and
cation resins. A patent was also granted to Kollsman describing a Continuous EDI (CEDI)
mechanism for the purification of acetone. Numerous patents were granted for various types of
EDI devices during 1957 to 1960 [35]. In addition, the design and operating conditions of
electrodeionization process has been extensively investigated by Glueckauf in the late 1950s and
early 1960s. His two-staged theory was based on the diffusive transfer of ions from flowing
solution to ion exchange resin beads and the transfer of ions along the chain of ion exchange beads
[36]. In the 1970s to 1980 Matejka and Shaposhnik extended the investigation of CEDI into the
the deionization of brackish or tap water to produce ultra-pure water [37] Finally, the first
commercially CEDI modules were introduced in 1987 under the trade name Ionpure, now sold by
U.S. Filter Corporation (“U.S. Filter”) [38]. The configuration of an EDI is similar to ED except the usage of
ion exchange resins or fibers in the diluate cell in order to increase the conductivity in the solvent-water and prevent
the occurrence of the concentration polarization phenomenon. The main application of this technology is the
production of ultrapure water for semiconductors and pharmaceutical manufacturing. Also, this technology may
facilitate the separation of toxic metallic ionic species that are present in industrial waste effluents
[33], [39]. Recently, Arora et al. and others developed ion exchange resin wafers that can enhance
electrical conductivity in solutions similar to EDI process [40]. The benefit of using a wafer is that
thinner electrode cells can be developed and resin regeneration can occur within the cell through
water splitting. Consequently, the overall resistance in the electrodialytic stack is lower. The main
difference of this technique is that a polymer is used to bond the ion exchange resins together.
13
Figure 2-2. Schematic of Electrodionization Configuration
Bipolar Membrane Electrodialysis (BMED): Applications of Electrodialysis in the
Food industry
Bipolar membranes are consist of an anion zone, a cation zone and the interphase area
where the two zones overlap. They can produce hydroxyl and hydrogen ions via water splitting.
When they are used in conjunction with IEMs in an ED system, they produce acid and bases from
salt. Bipolar membranes have been prepared by K.N.Mani et al. in the late 1970s [41]. The first
commercial application of bipolar membranes was for generating spent hydrofluoric/nitric acid
mixture used in stainless steel pickling, which was commercialized by AQUATECH systems in
1980 [42]. Attempts have been made by Strathmann et al. in order to improve the characteristics
of the bipolar membranes [43]. BMED is a promising alternative technique for the valorization
and treatment of industrial wastewaters of very different nature, such as, metal processing,
production of rubber, wood processing, beverage industry, and production of acetaldehyde [44]–
[48]. The key parameters in a bipolar membrane are high water dissociation rates, low electrical
+ -
CEM CEM AEM
Cathode Anode
Concentrate Diluate
Feed Feed
14
Figure 2-3. Bipolar Membrane Electrodialysis Configuration
resistance at high current density, high ion-selectivities, low co-ion transport rate and good
chemical and thermal stability in strong acids and bases. Application of this technology in food
industry has been extensively studied by Bazinet et al. [47]. For instance, milk protein production
[48], juice deacidification [49], acidification of Kraft black liquor [50] and etc. BMED has been
growing so fast recently due to its unique design and capability.
Theoretical Background: Transport in Ion Exchange Membranes
In separation processes using ion exchange membranes both electrical potential and
concentration gradients are as driving forces, it is usually easier to study them in terms of the
amount of charge transported than the amount of mass transported. Because both types of ion are
present, anions and cations move in opposite directions under an electric potential gradient. In ED,
-
Electrode Rinse
Cathode
BPM CEM AEM
Anode + -
BPM
H +
OH -
H +
OH -
Na +
Cl -
Electrode Rinse
Electrode Rinse
Electrode Rinse Recirculated acid (HCl)
Recirculated acid
(HCl)
Feed (Salt solution, NaCl)
Diluted salt
solution
Recirculated base
(NaOH)
Recirculated base
(NaOH)
15
for example, when an electrical potential difference is applied to a NaCl solution, Cl- will migrate
to the anode (positive electrode) and Na+ will migrate to the cathode (negative electrode). Negative
ions cannot pass the negatively charged membranes (anion exchange membrane) and positive ions
cannot pass the positively charged membranes (cation exchange membrane). This allows the
depletion of ions from a diluate or diluting solution and the concentration of ions in concentrate
solution. The total amount of charge transported per second across a plane of given area can be
measured using the following equation:
𝐼
𝐹 = c+ (u) (+e) + c- (-ν) (-e) = ce (u+ν) (2-1)
Where
c+ is the concentration of sodium cations,
c- is the concentration of chloride anions,
u is the velocity of the cations in an externally applied field of strength (cm/s),
-ν is the velocity of the anions measured in the same direction (cm/s),
+e and –e are protonic and electronic charge, respectively,
I is the current (A),
and F is the Faraday constant which converts the transport of electric charge to a current density
in amps (C/mol).
Equation 1 links the electric current with the transport of ions. The fraction of the total current
transported by an ion is known as the transport number of that ion. The relationship between the
transport number for the cations and anions is,
t+ + t- = 1 (2-2)
16
which means by combining the equation 1 and 2 the transport number for both cation and anion
can be calculated from Eq. (2-3) and (2-4), respectively:
t+ = c 𝑢𝑒
𝑐𝑒(𝑢+𝜈) =
𝑢
𝑢+𝜈 (2-3)
t- = 𝑢
𝑢+𝜈 (2-4)
Concentration Polarization in Electrodialysis
Concentration polarization is a well-known phenomenon in membrane separation
processes that occurs as a concentration gradient within the solution and perpendicular to the
membrane surface. In ED system, electrical current is carried by anions and cations migrating
through the solution in opposite direction. Conversely, current is carried mainly by counter-ions
inside the membrane, while co-ions are (ideally) rejected [31]. The resistance of the membrane is
often small compare to the resistance of the water-filled compartments, especially in the dilute
compartment where the amount of ions carrying the current is low. The formation of ion-depleted
regions next to the membrane in dilute compartments, places an additional limit on the flux of ions
through the membrane. Ion transport through this ion-depleted aqueous boundary layer controls
ED system performance. The thickness of this unstirred layer in ED system is 20-50 µm. Since
only one of the ionic species is transported through ion exchange membrane, the concentration
gradients will form in this layer [51].
Limiting Current Density in Electrodialysis
Due to the selective permeation of the ions in electrodialysis membranes, an immediate
decrease in the concentration of some ions in the solution adjacent to the membrane surface will
17
occur. Comparing to the bulk solution concentration, this reduction is significant, which reflects
that an increasing fraction of the voltage drop is being consumed to transport ions across the
boundary layer rather than through the membrane. Consequently, the energy consumption
associated with salt transportation increases dramatically [52]. The maximum transport rate of ions
in the boundary layer can be presented by a point at the membrane surface where the ion
concentration is zero. The limiting current density is the current through the membrane at this
point, which is, current per unit area of membrane (mA/cm2). Any further increase in voltage
difference across the membrane after reaching to the limiting current density, will not increase
current or ion transport through the membrane. This extra power usually causes side reactions such
as, water dissociation [31][6].
Figure 2-4. Schematic of the concentration gradients
adjacent to a single cationic membrane in an ED
stack. Reproduced from [31].
Figure 2-5. Typical current-voltage curve for an
IEM immersed in an electrolyte solution.
Reproduced from [11]
18
Electrodialysis Performance
The overall efficiency of an ED process is the energy consumption of the system to perform
the desired separation which can be calculated from equation (2-5),
E = I2 R (2-5)
where E is the power consumption in Kilowatts, I is the current through the stack and R is the
resistance of the stack. Current efficiency is another important key factor determining the
performance of ED system, which can be measured using equation (2-6),
η = 𝑍 𝑉 𝐹 (𝐶𝑖−𝐶𝑓 )
𝑁𝐼𝑡 (2-6)
where Z is the ion valence, V is the system volume, F is Faraday’s constant, Ci and Cf are the
initial and final ion concentration, respectively, I is the system current, and t is the operation time.
In general, at low current densities the current efficiency is highest, while this results in low
productivity. Since high productivity is often favorable, current densities are raised up to the point
where power consumption can be justified by the economics of the process. In addition, further
increase in current density above the limiting current density will cause water splitting rather than
ionic movement [53].
Monovalent Ion Selectivity in Electrodialysis
Brackish water and sea water mainly consist of monovalent and multivalent ions such as
sodium, chloride, calcium, magnesium, and sulfate. The separation of monovalent ions can be
beneficial where the existence of a specific ion can cause issues in terms of either processing or
final application. For instance, selective removal of sodium over calcium and magnesium is
19
important in agricultural applications. Because irrigation water with high sodium concentration
can decrease water infiltration and permeability of soil, which results in reducing crop yield [19].
Another example is the formation of undesired precipitates by calcium, magnesium and sulfate
(e.g. CaSO4) which can clog parts of seawater desalination process equipment [54]. Also, in some
countries, the concentration of nitrate in groundwater is increasing significantly due to excessive
use of artificial fertilizers. Nitrate ion is harmful to human health and it needs to be removed when
treating ground water [55]. Separation of ions with the same sign and valence is difficult and
important in both industrial requirements and academia. ED system is one of the most promising
methods for selective separation of monovalent ions over multivalent ions by using monovalent
perm-selective IEMs. The perm-selectivity of ions through IEMs is governed by their specific
transport rate in membranes and affinity of ions with membranes. Several theories have been
proposed to clarify the perm-selectivity mechanism of specific ions. These studies are mainly
classified as, a) control of the same charge ions perm-selectivity based on their hydrated ion size;
b) particular interactions between the IEM’s functional groups and the mobile ions; c) rejection of
specific ions by a thin surface layer on the IEM which has the same charge as ions [24–30]. Xu
et.al developed a monovalent CEM by coating a polyethyleneimine layer on the membrane surface
[19]. Mulyati et al. found the effect of a strong negative charge on the monovalent selectivity and
anti-fouling properties of AEMs through layer-by-layer assembly of oppositely charged
polyelectrolytes on the membrane [62]. Composite membranes composed of AEMs and
Polypyrrole present a lower transport number ratio compare to those of membranes without
polypyrrole layer [63]. Introducing anionic polyelectrolyte layers by immersing the AEMs in the
electrolyte solution and providing ionic cross-linking on the membrane surface can also cause
perm-selectivity in the AEM’s [59]. Monovalent perm-selective IEMs have been industrially used
20
X
Cl
to increase the efficiency of ED system. However, the current perm-selective membranes in
industry are either costly, hazardous and/or have high potential for fouling and scaling. There is
an urgent need to develop robust cost-effective monovalent perm-selective membranes.
Ionic Liquid-based Composite Thin-films for Perm-selectivity in AEMs
In AEMs, perm-selectivity can be discussed in terms of a transport number ratio between
a target anion and a standard anion, which is usually chloride ion. Thus the perm-selectivity
between anion X and chloride is defined as,
P = 𝑡𝑥
𝑡𝑐𝑙⁄
𝐶𝑥𝐶𝑐𝑙⁄
(2-7)
where, tx and tCl are transport number of anion X and chloride in the membrane, respectively, and
Cx and CCl are the concentrations of X and chloride in the diluate during ED process. PClX is also
called the transport number of anion X relative to chloride ion [58] . It has been suggested that the
transport number of sulfate ions relative to chloride ions in ED is dependent on the preparation
methods of AEMs. For instance, MPDA anion exchange membranes which are made of the
condensation of m-phenylenediamine, phenol and formaldehyde have extremely low PClSO4 while
an AEM prepared by the condensation of tetraethylenepentamine, phenol and formaldehyde,
permeates almost the same amount of sulfate ions as that of chloride [22]. AEMs made from 2-
oxy-benzyldimethylamine, phenol and formaldehyde present higher permeation of sulfate ions
compare to MPDA membrane [54]. Another way of membrane surface modification by the
purpose of specific ion perm-selectivity is decreasing hydrophilicity of AEMs by introducing
specific anion exchange groups in the membranes [61][22]. In this concept, the permeation of
anions through the membranes becomes difficult with increasing the hydrophobicity of the
membrane. Since for example, sulfate ions are bulky and hydrophilic compared with chloride ions,
21
it is reasonable that the hydrophilic ions are difficult to permeate through the hydrophobic
membrane.
As far as we know, no previous research has investigated the usage of ILs to develop perm-
selective AEMs for aqueous solutions in ED system. However, the application of these ILs in
membrane-based gas separation processes has been investigated by researchers extensively The
earliest story about ionic liquids was in 1914, when Paul Walden was investigating salts and he
found [EtNH3][NO3], with a melting point of 12°C [64]. After that several individual groups were
working on molten salts without being aware of each other. In 1951, Hurley and Weir discovered
1-ethylpyridinium bromide-aluminum chloride ([C2py]Br-AlCl3) which was liquid in 2:1 M ratio
mixture at room temperature [65]. Later, Bob Osteryoung’s group found 1-butylpyridinium
chloride-aluminium chloride ([C4py]-AlCl3) being liquid at room temperature while they were
studying the electrochemistry of two iron (II) diimine complexes ferrocene and
hexamethylbenzene at room temperature [66]. Other low-melting systems with organic cations
such as [Et4N][GeCl3], [Et4N][SnCl3], and [Et3NH][CuCl2] being studied by scientists as solvents
for catalysts [16]. Finally, in 1980s, with new researchers such as Ken Seddon, Tom Welton and
Charles L. Hussey interest in ionic liquids began to slowly spread [68]. Due to their ability to
change the anion and cation components of the liquid, ionic liquids are considered as ‘designer
solvents’; which makes them suitable for a broad range of application. Recent studies indicate that
ionic liquids can be used as membranes in various separation processes. The initial use of ILs as
membranes was as a supported IL membrane, in which their negligible vapor pressure solves one
of the limitations of traditional liquid membranes [69]. Gelled structures are also a new
morphology advancement of ILs that provides improved mechanical features compare to the liquid
while keeping the diffusion properties of the liquid phase [70]. The utilization of ILs in
22
Electrodialysis system has been mostly conducted for ILs synthesis and purification. For example,
Himmler et al. designed new ionic liquids through isolating an ionic liquid cation in BPED [53].
ED has been used by Haerens et al. in order to produce low concentrations of the ionic liquid
choline dicyanamide from salt solutions [40].
Containing big charged groups, ILs are capable of having specific interactions with ions.
In this work, we synthesized two ionic liquids, [VBMIM][TF2N] and [P888VB][TF2N], and
studied the characterization and performance of the AEM after polymerization of the IL on the
surface of the membrane. ILs containing [TF2N]- show low water solubility and are suitable options
when working with aqueous solutions. The hypothesis is that by polymerizing the ionic liquid on
the surface of the AEM, the electrostatic repulsion between sulfate anions and the negative surface
potential made by [TF2N], is greater than that between chloride anions and the negative surface
potential according to Coulomb’s law, which means that multivalent anions are less likely to
transport onto the membrane surface than monovalent anions. This can be observed by a change
in the transport number of sulfate ions relative to chloride ions when comparing neat and PIL
coated AEMs results.
23
CHAPTER III
EXPERIMENTAL
Materials and Instrumentation
Experiments were conducted using a PCCell 64-4 (PCCell GmbH Co, Heusweiler,
Germany) for ED experiments. The characteristics of the membranes used in this study are listed
in Table 2. The Neosepta ASE (ASTOM Corporation, Tokyo, Japan) membrane is a standard AEM
with no specific selectivity towards monovalent anions. All starting materials for ionic liquid
synthesis have been purchased from Sigma-Aldrich Company except Acetonitrile. It was
purchased from VWR Company. Sodium chloride (MW 58.44 g/mole, VWR International, LLC,
USA) and sodium sulfate (MW 142.04 g/mole, VWR International, LLC, USA) were utilized for
most of the membrane properties measurements. Nuclear Magnetic Resonance (NMR) spectra was
performed using a 400 MHz Bruker Avance III HDTM NMR spectrometer. Fourier- transform
infrared (FTIR) spectra were obtained using an Agilent Technologies Cary 630 FTIR spectrometer
in attenuated total reflectance (ATR) mode. Surface characterization of both pristine and coated
membranes was examined using SEM (JSM-5600 Scanning Electron Microscope, JEOL, USA
Inc. Peabody, MS). Atomic Force Microscopy (AFM) was performed using a Bruker NanoScope
V microscope. Contact Angle was measured using a Biolin Scientific Attention Theta instrument.
24
Table 3-1. Detailed Specification of Ion Exchange membranes
Title
Anion Exchange Membrane
Standard grade
ASE
Type Strong Base (Cl type)
Characteristics High mechanical strength
Electric resistance (Ὠ.cm2) 2.6
Burst strength (MPa) ≥ 0.35
Thickness (mm) 0.15
Temperature (°C) ≤60
PH 0-14
Ionic Liquids Synthesis
1-methyl-(4-vinylbenzyl) imidazolium bis(trifluoromethylsulfonyl)imide
4-vinylbenzyle Chloride (17.16 mL) was added drop wise to a stirred solution of 1-
methylimidazole (9.708 mL) in acetonitrile (30 mL) at 70 °C under an atmosphere of nitrogen.
The reaction mixture was stirred at 70 °C for 24h. The resulting mixture was washed several times
with diethyl ether. Rotary evaporation of the diethyl ether followed by evaporation in vacuum
provided the clear liquid. The [VBMIM][TF2N] monomers were synthesized via anion-exchange
of [VBMIM][Cl]. Lithium bis(trifluoromethylsulfonyl)imide was added to a solution of
[VBMIM][Cl] in water (150 mL), and the resulting mixture was stirred for 48h at room
temperature. Dichloromethane (150 mL) was then added, and the dichloromethane layer was
washed with water (150 mL) until no halide was detected by the silver nitrate test. Rotary
evaporation of the dichloromethane layer, followed by evaporation in vacuum, provided the
product as a clear liquid.
25
Figure 3-1. Schematic of the 1-methyl-(4-vinylbenzyl) imidazolium bis(trifluoromethylsulfonyl)imide synthesis
Trioctyl-3-(4-vinylbenzyl) phosphonium bis(trifluoromethylsulfonyl)imide
4-vinylbenzyle Chloride (7.6 mL) was added drop wise to a stirred solution of
Trioctylphosphine (24 mL) in acetonitrile (30 mL) at 70 °C under an atmosphere of nitrogen. The
reaction mixture was stirred at 70 °C for 24h. The resulting mixture was washed several times with
diethyl ether. Rotary evaporation of the diethyl ether followed by evaporation in vacuum provided
the clear liquid. The [P888VB][TF2N] monomers were synthesized via anion-exchange of
[P888VB][Cl]. Lithium bis(trifluoromethylsulfonyl)imide was added to a solution of
[VBMIM][Cl] in water (150 mL), and the resulting mixture was stirred for 48h at room
temperature. Dichloromethane (150 mL) was then added, and the dichloromethane layer was
washed with water (150 mL) until no halide was detected by the silver nitrate test. Rotary
evaporation of the dichloromethane layer, followed by evaporation in vacuum, provided the
product as a clear liquid.
26
Figure 3-2. Schematic of the Trioctyl-3-(4-vinylbenzyl) phosphonium bis(trifluoromethylsulfonyl)imide synthesis
Surface Modification of AEMs
PILs coated AEMS were prepared via both solvent casting and sandwiching using the
following general procedures: the [X][Tf2N] (X indicates either [VBMIM] or [P888VB])
monomers and 1 wt% 2-hydroxy-2-methylpropiophenone (radical photo-initiator) were combined
and vortexed for 1 min. The mixture was then casted onto the AEM on a quartz plate coated with
Rain-X and then sandwiched with a second quartz plate. The membrane was then irradiated with
365 nm light for 4 h. In solvent casting procedure acetonitrile was added to the mixture, coated the
membrane and then left under the hood for 12h. The membrane was then irradiated with 365 nm
light for 8h. Only one side of the membrane surface was modified and the thickness was measured
using an electronic digital micrometer (Midland Scientific Inc, USA). Then the membranes were
soaked in DI water for 24h before utilization in ED system.
Electrochemical Properties Characterizations
Transport numbers
The monovalent-ion selectivity of the AEMs is investigated by the transport number ratio
between monovalent chloride and divalent sulfate ions. To get the bulk transport numbers, the
27
ionic fluxes of Cl- and SO42- through the membranes with time elapsed were measured in a four-
cell testing module including two CEMs and one AEM. A mixture of 0.05 M NaCl and 0.05 M
Na2SO4 was used as the testing solution, and 0.2 M Na2SO4 was used as the solution for electrodes.
The voltage applied was held constant at 5 volt with the effective membrane area of 64 cm2. 2 mL
of testing solutions were taken from compartments every 30 min. The concentration of Cl- was
analyzed by a Thermo Scientific Chloride Electrode. The concentration of SO42- was calculated
from conductivity versus concentration plot and conductivity was measured using a Thermo Fisher
ion conductive probe. The corresponding ion flux of Cl- and SO42- passing through the membrane
(Ji) is calculated based on the ions concentration change with time (dCi/dt) in the dilute
compartment as follows:
𝐽𝑖 =𝑉 (𝑑𝐶𝑖
𝑑𝑡)
𝐴 (3-1)
where V is the volume of the circulated testing solution (cm3) and A is the effective membrane
area (cm2). To evaluate the improvement of monovalent-ion selectivity of the membranes after
modification, the transport number ratio between Cl- and SO42- was determined based on Eq.(3-2)
(3-2)
where tCl - and tSO4
2- are transport numbers of Cl- and SO42- ions, respectively; CCl
- and CSO42- are
the average concentrations of Cl- and SO42- ions in the dilute solution, respectively. The transport
number of ion (i), ti is defined by Eq. (3-3),
ti = 𝐽𝑖
∑ 𝐽𝑠⁄ (3-3)
P
Cl-
SO4
=
𝒕𝑪𝒍−𝒕 𝒔𝒐𝟒
−⁄
𝑪 𝑪𝒍−𝑪𝒔𝒐𝟒
−⁄
28
where ∑ Js denotes the total ion flux through the membrane. The flux used in Eq. (3-3) is the
absolute value. The transport of cations i.e. Na+ was not considered in the present work.
Limiting Current Density and Resistance of the Membranes
To investigate limiting current density of the membranes, chronopotentiometry was
conducted with a 0.17 M (10 g per L) NaCl solution under direct current conditions to yield
current-voltage (I-V) curve in the same four- compartment modules. A 0.2 M (30 g per L) Na2SO4
solution was used as the electrolyte. The solutions in each cell were circulated individually by a
Masterflex L/S peristaltic pump (Cole-Parmar Instrument Company, USA). The applied voltage
was raised step by step every 10s (i.e. 0, 0.5, 1,…, 10 V) and was provided by a power supply
(Model GPS-3030DD DC power supply, GW Instek, Fotronic Corporation). The I-V curve was
plotted by current density versus voltage across the membrane. Electrochemical impedance
spectroscopy (EIS) measurement was applied to analyze the membrane conductivity using a
Princeton Applied Research potentiostat/galvanostat model 263A.
29
CHAPTER IV
RESULTS AND DISCUSSION
Fourier-Transform Infrared (FTIR) Spectroscopy
Figures 4-1 shows selected IR spectra for the PIL/IL prepared from radical
photopolymerization of both imidazolium and phosphonium-based IL monomers. For
[P888VB][TF2N] the C=C stretch at 828-926 cm-1 was used as the vinyl peak of interest and the
integral of the area between 1142-1206 cm-1 was used as the reference peak. Integration of the IL
and neat curable PIL signals was used to estimate the C=C bond conversion using Eq. (4-1) shown
below. For [VBMIM][TF2N] the C=C stretch as 900-930 cm-1 was used as the vinyl peak of
interest and the integral of the area between 1000-1100 cm-1 was used as the reference peak. The
conversion percent for imidazolium and phosphonium-based PIL was 68 and 75 percent,
respectively.
Polymerization Degree = (
𝐴𝑟𝑒𝑎 𝑣𝑖𝑛𝑦𝑙 𝑝𝑒𝑎𝑘
𝐴𝑟𝑒𝑎 𝑟𝑒𝑓𝑒𝑟𝑒𝑛𝑐𝑒 𝑝𝑒𝑎𝑘)𝐼𝐿
(𝐴𝑟𝑒𝑎 𝑣𝑖𝑛𝑦𝑙 𝑝𝑒𝑎𝑘
𝐴𝑟𝑒𝑎 𝑟𝑒𝑓𝑒𝑟𝑒𝑛𝑐𝑒 𝑝𝑒𝑎𝑘)𝑃𝐼𝐿
(4-1)
30
Membrane surface Characterization
As mentioned in previous chapters, [VBMIM][TF2N] coated ASE membrane did not have
mechanical stability in water. After soaking the coated membrane in DI water for 24 hours, the
coating layer started to delaminate from the membrane surface. Fig. 4-2 indicates the delamination
of the coating layer after utilization in the ED system. The next chosen IL was [P888VB][TF2N].
Fig. 4-3 shows the surface SEM images of the pristine and [P888VB][TF2N] coated ASE
membrane. Incomplete membrane coating has been occurring through the knife casting technique
using 2 quartz plates. Then, in order to achieve a thinner PIL layer on the membrane, solvent
casting technique has been used. The detectable thickness of coated films ranged from 8 µm to 35
µm. This inconsistency in the membrane thickness might be caused by the high compression of
the 2 plates or the membrane surface tension. ASE and ILs have a yellow color, which makes the
defects observation difficult. Fig. 4-4 implies the non-uniform coating layer through AFM images.
Figure 4-1. Overlay of the IR spectra of IL and PIL.The change in C=C stretch 900-930 cm-1
in polymer
indicates the degree of polymerization which is 68% for [VBMIM][TF2N] and 75% for [P888VB][TF2N].
31
Figure 4-2. Delamination of [VBMIM][TF2N] PIL from ASE membrane surface.
a b
Figure 4-3. SEM images of the a) pristine and b) [P888VB][TF2N] coated membranes
Figure 4-4. AFM images showing non-uniform coated layer of the [P888VB][TF2N] on the AEM surface.
32
To determine the resultant changes on hydrophilic property of the membrane after surface
modification, water contact angle measurements were conducted for both [VBMIM][TF2N] and
[P888VB][TF2N] coated AEMs. Due to the hydrophobic nature of the [TF2N], it was expected to
see an increase in the hydrophobicity of the AEMs. However, this can be justified as long as the
membrane is still hydrophilic. Table 3 shows the contact angle of the pristine and coated
membranes. The [P888VB][TF2N] coated AEM is more hydrophobic compare to
[VBMIM][TF2N] coated AEM, which is resulted from hydrophobicity of the both cation and
anion in IL [71].
Table 4-1. Contact Angle measurements of the membranes
Membrane Contact Angle
Pristine AEM 19.2 ± 1
[VBMIM][TF2N] Coated AEM 66.2 ± 1
[P888VB][TF2N] 88.5 ± 1
Electrochemical Properties Characterization
Electrical impedance spectroscopy (EIS) was conducted to investigate the material
resistance. The applied voltage during testing was 10 mV with frequency range between 1 MHz
and 1 Hz. The material resistance was obtained from locating the x-intercept of the generated
Nyquist plot [72][73]. The ion conductivity was then calculated using Eq. (4-2) below,
σ = 𝐿
𝑅𝐴 (4-2)
where L is the thickness of the membrane, R is the membrane resistance and A is the membrane
surface area. The conductivity of the modified membrane with thickness of 20 µm has been
33
Cl-
SO4
2-
P
reduced by 43%. However, providing thinner coating layer might improve the conductivity.
Monovalent-ion selectivity of the membranes was investigated based on transport number ratio,
which was calculated from Eq. (9). The larger value is indicating the better monovalent
ion selectivity [58]. As listed in Table 4, the modified AEMs have decreased sulfate flux and larger
values has been obtained. Since the repulsive force produced by a negatively charged
surface against sulfate is stronger than that against Cl− the negatively charged coated layers on the
surface rejected SO4 2− more intensively than Cl− [21]. The impacts on the apparent perm-
selectivity and Cl− flux suggest that the negatively charged surface introduced by PIL exerted a
weak repulsive force on Cl-. Also, perm-selectivity of the membranes have been obtained from the
slope of the concentration versus time plot. Results indicates a 23% improve in the perm-selectivity
of the coated membrane compare to the pristine membrane.
Table 4-2. Transport number ratios for the membranes
a b
Membranes JCl- (10 -6
mole/cm2min)
JSO4 2- (10 -6
mole/cm2min)
tCl- tSO4
2- PCl-SO4
2-
Pristine ASE 1.83 2.63 0.44 0.55 1.29
[P888VB][TF2N]
coated ASE
2.48 2.55 0.49 0.50 1.61
Cl-
SO4
2-
P
0
0.5
1
1.5
2
neat coated
Average Transport Number
0
0.2
0.4
0.6
0.8
1
1.2
1.4
neat coated
Average Monovalent Selectivity
34
c
current efficiency of the pristine and modified membrane was calculated based on Eq. (4-3) below,
η = 𝑍𝑉𝐹(𝐶𝑖−𝐶𝑓)
𝑁𝐼𝑡 Eq.(4-3)
where z is the ion valence, V is the volume of the solution in diluate, F is the Faraday’s constant,
Ci and Cf are initial and finial concentration, respectively, N is the number of stacks in ED system,
I is the average current density and t is the time of experiment. The current efficiency of the
modified membrane was about 30% higher than the pristine membrane. This might be due to the
faster ion depletion and the reduction in the time of experiment. Figure 16 indicates the the
conductivity reduction in diluate compartment versus time. Figure 16a shows the delamination of
Imidazolium coating due to solubility of water within cured film. Phosphonium coating is stable
and working properly. However, it is not as efficient as neat membrane to reduce the concentration
of ion and reduce the conductivity. Figure 16b indicates faster conductivity reduction in coated
membrane compared to pristine membrane. This is because of thinner coating layers.
Figure 4-5. Comparing a) average selectivity, b)
average transport number and c) average current
efficiency of the pristine and modified membrane.
The average monovalent selectivity has been
increased by 23%, average transport number by
24% and average current efficiency by 30%. The
error bar is showing the standard deviation error.
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
neat coated
Average Current Efficiency
35
a b
Figure 4-6. Conductivity reduction over time in ED. a) Imidazolium and phosphonium coated membrane(20 µm)
performance compared to pristine membrane b) Phosphonium coated (15 µm) performance compared to pristine
membrane.
0
2
4
6
8
10
12
14
0 50 100 150 200
Dil
uat
e C
ond
uct
ivit
y (
mS
/cm
)
ED Operation Time (min)
Neat Membrane
Phosphonium Membrane
Imidazolium Membrane
0
1
2
3
4
5
6
7
8
9
10
0 100 200 300
Dil
uat
e C
ond
uct
ivit
y (
mS
/cm
)
ED Operation Time (min)
Coated. Exp 1
Coated. Exp 2
Coated. Exp 3
Neat. Exp 1
Neat. Exp 2
Neat. Exp 3
36
SUMMARY AND CONCLUSION
In this work, the surface of the standard AEM (ASE) was modified with PILs.
[VBMIM][TF2N] and [P888VB][TF2N] were synthesized and coated on the AEMs. The surface
characteristics and electrochemical properties of the membranes were determined. After surface
modification, [VBMIM][TF2N] coated membranes were delaminated immediately after using in
ED system due to solubility of water within cured film. However, [P888VB][TF2N] modified
membranes indicated a slight improvement in monovalent - anion selectivity. This enhancement
might be attributed to the strong negatively charged surface potential achieved by the PIL layer.
The coated membrane with [P888VB][TF2N] PIL showed monovalent-anion selectivity
comparable to that of the commercial ASE membranes. Also, there has been about 30% increase
in current efficiency. Although the preliminary results suggests an improvement in the current
efficiency and monovalent selectivity of the modified ASE membrane, more experiments need to
be performed to prove the concept. On the other hand, the spacers stick to the modified membranes
which clogged the water pathways on the spacer and after each trial cleaning procedure is needed.
This is happening due to the sticky nature of the PILs and might be improved by a thinner PIL
layer or coating a very thin layer of a non-sticky material on the PIL layer. It can also be related to
the polymerization degree which might be enhanced by increasing the time of radiation or the
amount of initiator needed for the polymerization reaction.
37
FUTURE WORK
Although preliminary data shows an improvement in the monovalent selectivity of the
modified membranes in ED system, more experiments are needed to perform and prove the
concept. Other coating procedures and materials such as, spin coating might be considered. More
ILs such as, [HMIM][TF2N] and [EMIM][TF2N] might be tried to see if higher monovalent
selectivity can be achieved. In order to achieve a thin, uniform coating layer on the membrane
surface the surface tension of the pristine AEM might be studied. Also, applying more PIL layers
on the membrane surface might be considered.
38
LIST OF REFERENCES
39
[1] M. M. Mekonnen and Y. A. Hoekstra, “Four Billion People Experience Water Scarcity,”
Sci. Adv., vol. 2, no. 2, pp. 1–7, 2016.
[2] A. E. Ercin and A. Y. Hoekstra, “Water footprint scenarios for 2050: A global analysis,”
Environ. Int., vol. 64, pp. 71–82, 2014.
[3] M. A. Shannon, P. W. Bohn, M. Elimelech, J. G. Georgiadis, B. J. Marĩas, and A. M.
Mayes, “Science and technology for water purification in the coming decades,” Nature,
vol. 452, no. 7185, pp. 301–310, 2008.
[4] P. Taylor and R. Singh, “Analysis of energy usage at membrane water treatment plants,”
Desalin. Water Treat., vol. 29, no. 1–3, pp. 63–72, 2011.
[5] “IDA, Desalination YearBook 2016-2017, Water Desalination Report,” 2017.
[6] A. Campione, L. Gurreri, M. Ciofalo, G. Micale, A. Tamburini, and A. Cipollina,
“Electrodialysis : a critical assessment an overview of recent developments on process
fundamentals , models and applications,” Desalination, vol. 434, no. October, pp. 121–
160, 2018.
[7] K. Yamaguchi, “Theory and Applications,” Self-Consistent F., p. 727, 1990.
[8] S. H:, “Electrodialysis,” a Matur. Technol. With a Multitude New Appl., vol. 264, pp. 1–
17, 2010.
[9] D. A. Vermaas, M. Saakes, and K. Nijmeijer, “Power generation using profiled
membranes in reverse electrodialysis,” J. Memb. Sci., vol. 385–386, no. 1, pp. 234–242,
2011.
[10] L. Alvarado and A. Chen, “Electrodeionization: Principles, strategies and applications,”
Electrochim. Acta, vol. 132, pp. 583–597, 2014.
40
[11] H. Strathmann, “Electrodialysis, a mature technology with a multitude of new
applications,” Desalination, vol. 264, no. 3, pp. 268–288, 2010.
[12] T. Luo, S. Abdu, and M. Wessling, “Selectivity of ion exchange membranes: A review,”
Journal of Membrane Science. 2018.
[13] M. Reig, C. Valderrama, O. Gibert, and J. L. Cortina, “Selectrodialysis and bipolar
membrane electrodialysis combination for industrial process brines treatment:
Monovalent-divalent ions separation and acid and base production,” Desalination, vol.
399, pp. 88–95, 2016.
[14] A. M. Lopez et al., “Potential of electrodialytic techniques in brackish desalination and
recovery of industrial process water for reuse,” Desalination, vol. 409, pp. 108–114, 2017.
[15] A. E. E. Fatima, M. Elazhar, M. Hafsi, “Performances of electrodialysis process in
desalination of brackish waters at various salinities and voltage,” Int. J. Adv. Chem., vol.
2, no. 2, 2014.
[16] T. Xu, “Ion exchange membranes: State of their development and perspective,” J. Memb.
Sci., vol. 263, no. 1–2, pp. 1–29, 2005.
[17] F. Karas, J. Hnát, M. Paidar, J. Schauer, and K. Bouzek, “Determination of the ion-
exchange capacity of anion-selective membranes,” Int. J. Hydrogen Energy, vol. 39, no.
10, pp. 5054–5062, 2014.
[18] S. Zhang, C. Yin, D. Xing, D. Yang, and X. Jian, “Preparation of
chloromethylated/quaternized poly(phthalazinone ether ketone) anion exchange
membrane materials for vanadium redox flow battery applications,” J. Memb. Sci., vol.
363, no. 1–2, pp. 243–249, 2010.
[19] X. Xu, Q. He, G. Ma, H. Wang, N. Nirmalakhandan, and P. Xu, “Selective separation of
41
mono- and di-valent cations in electrodialysis during brackish water desalination: Bench
and pilot-scale studies,” Desalination, vol. 428, no. June 2017, pp. 146–160, 2018.
[20] B. Tansel, “Significance of thermodynamic and physical characteristics on permeation of
ions during membrane separation: Hydrated radius, hydration free energy and viscous
effects,” Sep. Purif. Technol., vol. 86, pp. 119–126, 2012.
[21] H. Gao, B. Zhang, X. Tong, and Y. Chen, “Monovalent-anion Selective and Antifouling
Polyelectrolytes Multilayer Anion Exchange Membrane for Reverse Electrodialysis,” J.
Memb. Sci., 2018.
[22] T. Sata, “Studies on anion exchange membranes having permselectivity for specific
anions in electrodialysis - Effect of hydrophilicity of anion exchange membranes on
permselectivity of anions,” J. Memb. Sci., vol. 167, no. 1, pp. 1–31, 2000.
[23] K. N. Marsh, J. A. Boxall, and R. Lichtenthaler, “Room temperature ionic liquids and
their mixtures - A review,” Fluid Phase Equilib., vol. 219, no. 1, pp. 93–98, 2004.
[24] P. Bonhôte, A.-P. Dias, N. Papageorgiou, K. Kalyanasundaram, and M. Grätzel,
“Hydrophobic, Highly Conductive Ambient-Temperature Molten Salts †,” Inorg. Chem.,
vol. 35, no. 5, pp. 1168–1178, 1996.
[25] C. P. Fredlake, J. M. Crosthwaite, D. G. Hert, S. N. V. K. Aki, and J. F. Brennecke,
“Thermophysical Properties of Imidazolium-Based Ionic Liquids,” J. Chem. Eng. Data,
vol. 49, no. 4, pp. 954–964, 2004.
[26] D. R. McFarlane, J. Sun, J. Golding, P. Meakin, and M. Forsyth, “High conductivity
molten salts based on the imide ion,” Electrochim. Acta, vol. 45, no. 8, pp. 1271–1278,
2000.
[27] J. Zhang,S. Wang, Structure and interactions of Ionic Liquids. 2014.
42
[28] H. Ohno, M. Yoshizawa, and W. Ogihara, “Development of new class of ion conductive
polymers based on ionic liquids,” Electrochim. Acta, vol. 50, no. 2–3 SPEC. ISS., pp.
255–261, 2004.
[29] J. Yuan, D. Mecerreyes, and M. Antonietti, “Poly(ionic liquid)s: An update,” Prog.
Polym. Sci., vol. 38, no. 7, pp. 1009–1036, 2013.
[30] J. Yuan and M. Antonietti, “Poly(ionic liquid)s: Polymers expanding classical property
profiles,” Polymer (Guildf)., vol. 52, no. 7, pp. 1469–1482, 2011.
[31] R. W. Baker, Ion Exchange Membrane Processes – Electrodialysis. 2012.
[32] V. D. Grebenyuk and O. V. Grebenyuk, “Electrodialysis: From an idea to realization,”
Russ. J. Electrochem., vol. 38, no. 8, pp. 806–809, 2002.
[33] A. Bard and L. Faulkner, Electrochemical Methods Fundamentals and Applications. 1944.
[34] L. Alvarado and A. Chen, “Electrodeionization: Principles, strategies and applications,”
Electrochim. Acta, vol. 132, pp. 583–597, 2014.
[35] Kollsman.P, “No Title,” 2,815,320, 1957.
[36] E. Glueckauf, “Electro-dionisation Through a Packed Bed,” Br. Chem. Eng., pp. 646–651,
1959.
[37] Z. Mateka, “Continuous production of high-puriy water by electrodeionisation,” J. Appl.
Chem., vol. 21, pp. 117–120, 1971.
[38] F. DiMascio, J. Wood, and J. M. Fenton, “Continuous Electrodeionization. Production of
High-Purity Water without Regeneration Chemicals,” Electrochem. Soc. Interface, no. 4,
pp. 26–29, 1998.
[39] J. Wang, S. Wang, and M. Jin, “A study of the electrodeionization process high-purity
water production with a RO/EDI system,” Desalination, vol. 132, no. 1–3, pp. 349–352,
43
2000.
[40] Ö. Arar, Ü. Yüksel, N. Kabay, and M. Yüksel, “Various applications of
electrodeionization (EDI) method for water treatment-A short review,” Desalination, vol.
342, pp. 16–22, 2014.
[41] K. Nagasubramanian, F. . Chalanda, and K. . Liu, “No Title,” J. Memb. Sci., no. 109,
1977.
[42] G. . Trivedi, B. . Shah, S. . Adsikary, V. . Indusekhar, and R. Rangarajan, “Studies on
bipolar membranes,” React. Funct. Polym., pp. 243–251, 1996.
[43] H. Strathmann, H. . Rapp, B. Bauer, and C. . Bell, “No Title,” Desalination, vol. 90, 1993.
[44] X. Tongwen, “Electrodialysis processes with bipolar membranes (EDBM) in
environmental protection - A review,” Resour. Conserv. Recycl., vol. 37, no. 1, pp. 1–22,
2002.
[45] C. Fernandez-Gonzalez, A. Dominguez-Ramos, R. Ibañez, and A. Irabien,
“Electrodialysis with Bipolar Membranes for Valorization of Brines,” Sep. Purif. Rev.,
vol. 45, no. 4, pp. 275–287, 2016.
[46] X. Tongwen and Y. Weihua, “Effect of cell configurations on the performance of citric
acid production by a bipolar membrane electrodialysis,” J. Memb. Sci., vol. 203, no. 1–2,
pp. 145–153, 2002.
[47] L. Bazinet, F. Lamarche, and D. Ippersiel, “Bipolar-membrane electrodialysis:
Applications of electrodialysis in the food industry,” Trends Food Sci. Technol., vol. 9,
no. 3, pp. 107–113, 1998.
[48] S. Mikhaylin, L. Patouillard, M. Margni, and L. Bazinet, “Milk protein production by a
more environmentally sustainable process: Bipolar membrane electrodialysis coupled with
44
ultrafiltration,” Green Chem., vol. 20, no. 2, pp. 449–456, 2018.
[49] E. Vera, J. Ruales, M. Dornier, J. Sandeaux, R. Sandeaux, and G. Pourcelly,
“Deacidification of clarified passion fruit juice using different configurations of
electrodialysis,” J. Chem. Technol. Biotechnol., vol. 78, no. 8, pp. 918–925, 2003.
[50] M. Haddad, L. Bazinet, O. Savadogo, and J. Paris, “A feasibility study of a novel electro-
membrane based process to acidify Kraft black liquor and extract lignin,” Process Saf.
Environ. Prot., vol. 106, pp. 68–75, 2017.
[51] A. Campione, L. Gurreri, M. Ciofalo, G. Micale, A. Tamburini, and A. Cipollina,
“Electrodialysis for water desalination: A critical assessment of recent developments on
process fundamentals, models and applications,” Desalination, vol. 434, no. October
2017, pp. 121–160, 2018.
[52] M. Sadrzadeh and T. Mohammadi, “Treatment of sea water using electrodialysis: Current
efficiency evaluation,” Desalination, vol. 249, no. 1, pp. 279–285, 2009.
[53] V. Geraldes and M. D. Afonso, “Limiting current density in the electrodialysis of multi-
ionic solutions,” J. Memb. Sci., vol. 360, no. 1–2, pp. 499–508, 2010.
[54] A. H. Galama, G. Daubaras, O. S. Burheim, H. H. M. Rijnaarts, and J. W. Post, “Seawater
electrodialysis with preferential removal of divalent ions,” J. Memb. Sci., vol. 452, pp.
219–228, 2014.
[55] T. Kikhavani, S. N. Ashrafizadeh, and B. Van Der Bruggen, “Nitrate Selectivity and
Transport Properties of a Novel Anion Exchange Membrane in Electrodialysis,”
Electrochim. Acta, vol. 144, pp. 341–351, 2014.
[56] Y. Zhang, S. Paepen, L. Pinoy, B. Meesschaert, and B. Van Der Bruggen,
“Selectrodialysis: Fractionation of divalent ions from monovalent ions in a novel
45
electrodialysis stack,” Sep. Purif. Technol., vol. 88, pp. 191–201, 2012.
[57] M. Vaselbehagh, H. Karkhanechi, R. Takagi, and H. Matsuyama, “Surface modification
of an anion exchange membrane to improve the selectivity for monovalent anions in
electrodialysis - experimental verification of theoretical predictions,” J. Memb. Sci., vol.
490, pp. 301–310, 2015.
[58] T. Sata, R. Izuo, Y. Mizutani, and R. Yamane, “Transport properties of ion-exchange
membranes in the presence of surface active agents,” J. Colloid Interface Sci., vol. 40, no.
3, pp. 317–328, 1972.
[59] T. Sata, T. Yamaguchi, and K. Matsusaki, “Interaction between anionic polyelectrolytes
and anion exchange membranes and change in membrane properties,” J. Memb. Sci., vol.
100, no. 3, pp. 229–238, 1995.
[60] S. Mulyati, R. Takagi, A. Fujii, Y. Ohmukai, and H. Matsuyama, “Simultaneous
improvement of the monovalent anion selectivity and antifouling properties of an anion
exchange membrane in an electrodialysis process, using polyelectrolyte multilayer
deposition,” J. Memb. Sci., vol. 431, pp. 113–120, 2013.
[61] T. Sata, T. Yamaguchi, and K. Matsusaki, “Effect of hydrophobicity of ion exchange
groups of anion exchange membranes on permselectivity between two anions,” J. Phys.
Chem., vol. 99, no. 34, pp. 12875–12882, 1995.
[62] S. Mulyati, R. Takagi, A. Fujii, Y. Ohmukai, T. Maruyama, and H. Matsuyama,
“Improvement of the antifouling potential of an anion exchange membrane by surface
modification with a polyelectrolyte for an electrodialysis process,” J. Memb. Sci., vol.
417–418, pp. 137–143, 2012.
[63] S. S. Madaeni, “Preparation and properties of composite membranes composed of non-
46
conductive membranes and polypyrrole,” Indian J. Chem. Technol., vol. 13, no. 1, pp. 65–
70, 2006.
[64] T. Welton, “Ionic liquids: a brief history,” Biophys. Rev., vol. 10, no. 3, pp. 691–706,
2018.
[65] F. Hurley and T. P. Wler Jr, “Electrodeposition of Metals from Fused Quaternary
Ammonium Salts,” J. Electrochem. Soc., vol. 98, no. 5, pp. 203–206, 1951.
[66] H. L. Chum, V. R. Koch, L. L. Miller, and R. A. Osteryoung, “Electrochemical scrutiny of
organometallic iron complexes and hexamethylbenzene in a room temperature molten
salt,” J. Am. Chem. Soc., vol. 97, no. 11, pp. 3264–3265, 1975.
[67] G. W. Parshall, “Catalysis in molten salt media,” J. Am. Chem. Soc., vol. 94, no. 25, pp.
8716–8719, 1972.
[68] C. L. Hussey, “Room temperature haloaluminate ionic liquids. Novel solvents for
transition metal solution chemistry,” Pure Appl. Chem., vol. 60, no. 12, pp. 1763–1772,
1988.
[69] R. D. Noble and D. L. Gin, “Perspective on ionic liquids and ionic liquid membranes,” J.
Memb. Sci., vol. 369, no. 1–2, pp. 1–4, 2011.
[70] B. A. Voss, J. E. Bara, D. L. Gin, and R. D. Noble, “Physically gelled ionic liquids: Solid
membrane materials with liquidlike CO 2 gas transport,” Chem. Mater., vol. 21, no. 14,
pp. 3027–3029, 2009.
[71] K. J. Fraser and D. R. MacFarlane, “Phosphonium-based ionic liquids: An overview,”
Aust. J. Chem., vol. 62, no. 4, pp. 309–321, 2009.
[72] A. M. Lopez, M. G. Cowan, D. L. Gin, and R. D. Noble, “Phosphonium-Based Poly(ionic
liquid)/Ionic Liquid Ion Gel Membranes: Influence of Structure and Ionic Liquid Loading
47
on Ion Conductivity and Light Gas Separation Performance,” J. Chem. Eng. Data, vol. 63,
no. 5, pp. 1154–1162, 2018.
[73] P. K. Sow, S. Sant, and A. Shukla, “EIS studies on electro-electrodialysis cell for
concentration of hydriodic acid,” Int. J. Hydrogen Energy, vol. 35, no. 17, pp. 8868–8875,
2010.
48
APPENDIX
49
Calculation of Sulfate Concentration:
Chloride concentration was calculated by a chloride probe. To calculate the sulfate concentration,
the conductivity versus concentration data for both chloride and sulfate is needed. After measuring
the concentration of the chloride ion by chloride probe we measured the total conductivity of the
diluate compartment by a conductive probe. Sodium chloride conductivity was found from the
conductivity versus concentration plot. This plot can be obtained by measuring the conductivity of
the sodium chloride in the experiment concentration range. Then sodium sulfate conductivity was
obtained by subtracting sodium chloride conductivity from total conductivity. The sulfate
concentration was then calculated based on the sodium sulfate conductivity versus concentration
plot.
a b
Conductivity versus concentration. a) NaCl b) Na2SO4
y = 0.0007xR² = 0.8327
0
1
2
3
4
5
6
7
8
0 2000 4000 6000 8000 10000 12000
Co
nd
uct
ivit
y (m
S/cm
2)
Na2SO4 Concentration (ppm)
Na2SO4 Conductivity Vs. Concentration
y = 0.001xR² = 0.7787
0
2
4
6
8
10
12
0 5000 10000 15000
Co
nd
uct
ivit
y (m
S/C
m2)
Nacl Concentration (ppm)
NaCl Conductivity Vs. Concentration
50
Monovalent Selectivity Results:
Pristine Membrane Modified membrane Improvement
Average Transport Number Ratio 1.29 1.61 24%
St Err 0.25 0.29
Average Selectivity 0.85 1.05 23%
St Err 0.155 0.21
Current Efficiency 0.458 0.60 30%
St Err 0.043 0.12
51
VITA
Saloumeh Kolahchyan
Education
2017 - 2018 M.S. in Chemical Engineering, University of Mississippi, MS, USA
2009 - 2014 B.S. in Polymer Engineering, Tehran’s Science and Research University,
Tehran, Iran
Academic Appointments
2017-Present Research and Teaching Assistant. Department of Chemical Engineering,
University of Mississippi, Oxford, MS
Research Project: Design and synthesize of Imidazolium and
Phosphonium-based ionic liquid composite thin-films for selective ion
separations in electrodialysis for water treatment applications.
TA Courses: Process Fluid Dynamics and Heat Transfer-Plant Design
Work Experience
May 2018-Aug 2018 Thermoplastics R&D Intern. Carlisle Construction Materials, Carlisle,
PA, USA.
Did research on raw material formulation and conducted laboratory tests
on roofing membranes.
Analyzed tests results for cost saving developments.
52
Sep 2014-Dec 2016 R&D Polymer Engineer. Shahin Plastic Company, Tehran, Iran.
Did research on raw material formulations and new products designs
with PVC and PU
Troubleshot and resolved production-related issues in PVC plant
(Spread coating, Calendar, Extruder)
Developed a novel 3 layer PVC foam for sport floorings
Supervised product testing and quality control
Sep 2013-Aug 2014 Research Engineer. Shahin Plastic Company, Tehran, Iran.
Provided technical support to new application.
Recommended new technologies and materials to increase
productivity of the plant.
Jun 2013-Sep 2013 Polymer Engineering Intern. Shahin Plastic Company, Tehran, Iran.
Provided technical support to process optimization
Skills
Instruments
Spread Coating Machine
Polymer Calendaring Machine
Plastic Extruders
Electrodialysis System
Contact Angle
Fourier Transform Infrared (FTIR)
Tensile Strength Test Instrument
53
Nuclear Magnetic Resonance (NMR)
Scanning Electron Microscope (SEM)
Atomic Force Microscopic (AFM)
Differential Scanning Calorimetry (DSC)
Thermal Gravimetric Analysis (TGA)
Programming
Python, Mathcad, Microsoft Office, State-ease
Conference Presentations
1. Kolahchyan, S., Lopez, A. “Ionic Liquid-based Composite Thin-films for Selective Ion
Separations in Electrodialysis for Water Treatment Applications”. Annual Meeting of the
American Institute of Chemical Engineers (AIChE), Pittsburg, PA, U.S.A. October 27 -
November 2 (2018).
2. Kolahchyan, S., Lopez, A. “Design and synthesize of Phosphonium-based ionic liquid
composite thin-films for selective ion separations in electrodialysis for water treatment
applications”. The 8th Annual Research Symposium, University of Mississippi, Oxford,
MS, U.S.A. March 21- (2018).
3. Kolahchyan, S., Lopez, A. “Development of robust, ion-selective anion exchange
membranes through incorporation of ionic liquids for water purification via
electrodialysis” Annual Meeting of the American Institute of Chemical Engineers
(AIChE), Minneapolis, MN, U.S.A. October 29 - November 3 (2017).
4. Kolahchyan, S., Lopez, A. “Imidazolium based anion exchange membranes for water
54
purification via electrodialysis.” The 3rd Annual UM/UMMC Research Day, University of
Mississippi, Oxford, MS, U.S.A. April 13- (2017).
Publication
Kaviani, S, Kolahchyan, S, Hickenbottom, K, Lopez, A, “Enhanced Solubility of Carbon
Dioxide for Encapsulated Ionic Liquids in Polymeric Materials” Chemical Engineering
Journal (2018)
DOI: 10.1016/j.cej.2018.08.086
Honors and Activities
Won the First Prize in the STEM poster session at the 8th Annual Research Symposium
organized by the UM Graduate Student Council, University of Mississippi, Oxford, MS,
USA. March 21-(2018).
Scholarship for graduate studies, University of Mississippi, Oxford, Mississippi, USA (Jan
2017-Present).
Treasurer of the Iranian Student Association of the University of Mississippi (Apr 2017-
Apr 2018).
The President of Polymer Engineering Association, Tehran’s Science and Research
University, (2011-2014).
Scored 100/100 in Chemistry in University Entrance Exam.
High GPA in High School Diploma in Physics and Mathematics. GPA: 4/4
top related