Tuning the Ionic and Dielectric Properties of Electrospun Nanocomposite Fibers for Supercapacitor Applications

A. Jabbarnia. Int. Journal of Engineering Research and Application www.ijera.com
ISSN : 2248-9622, Vol. 6, Issue 6, ( Part -1) June 2016, pp.65-73
www.ijera.com 65 | P a g e
Tuning the Ionic and Dielectric Properties of Electrospun
Nanocomposite Fibers for Supercapacitor Applications
A. Jabbarnia1
*, W. S. Khan2
, A. Ghazinezami1
and R. Asmatulu1
*
1
Department of Mechanical Engineering, Wichita State University, 1845 Fairmount, Wichita, KS 67260-0133
2
Department of Mechanical and Industrial Engineering, Majmaah University, Majmaah, P.O. Box. 66, Saudi
Arabia
ABSTRACT
This study reports the fabrication and characterization of electrospun polyvinylidene fluoride (PVdF)and
polyvinylpyrrolidone (PVP) nanofiber separators embedded with carbon black nanoparticles. Different weight
percentages (0, 0.25, 0.5, 1, 2, and 4wt%) of carbon black nanoparticles were dispersed in N, N-
dimethylacetamide (DMAC) and ethanol using sonication and high-speed agitations, and then PVdF and PVP
polymers were added to the dispersions prior to the mixing and electrospinning processes. The morphological,
dielectric constant, ionic conductivity, and surface hydrophobic properties of the PVdF/PVP nanofiber
separators were analyzed using various techniques. SEM micrograms showed that the fiber diameter was
around 100-200 nm. The ionic conductivity test clearly revealed a significant increase in conductivity valueof
4.28 x 10-4
S/cm for 4 wt. % carbon black loading. However, the contact angle values were decreased with
increasing weight percent of carbon black particles. The dielectric constant was increased with the carbon black
loading. As can be seen, overall physical properties of the nanocomposite separators were significantly
enhanced as a function of carbon black inclusions, which may be useful for supercapacitor separators and other
energy storage devices.
Keywords: Carbon Black Nanopowders, Electrospun Nanofibers,Ionic Conductivity, Supercapacitor Separators.
I. Introduction
1.1. General Background
Supercapacitors or electrochemical
capacitors have been considered as alternative
energy storage devices. They can be utilized as
backup source devices due to their high power
levels, large specific surface area, low electrical
resistivity, high charging-discharging rate, and
long cyclic lives compared to conventional
capacitors and conventional batteries. They have
demonstrated great potential in a wide range of
applications such as power backup for mobile
phones or laptops, and a power source for hybrid
vehicles[1-8].Research on novel energy storage
devices has attracted substantial attention recently.
Traditional batteries have slow discharge rates and
a high energy density; therefore, it is important to
develop storage devices having high energy
density and high power density. Electrochemical
supercapacitors possess high power density and
reasonably good energy density. Currently,
researchers have focused their attention on
increasing the energy density of supercapacitors by
finding suitable materials for the
separator/electrode and lowering the overall cost
[9]. Many researchers have fabricated
separators/electrodes for supercapacitors using a
wide variety of materials, such as metal-
based oxides, graphene, carbon nanotubes,
carbonized wood, etc. Some researchers have used
carbonaceous compositions and metal oxides, and
incorporated them with various polymers for
separator applications [3-12]. Carbon-based
nanocomposites with conducting polymers have
high capacitance values and better cyclic
performance in supercapacitors. They also possess
high capacitance values due to their functional
groups containing phosphorus, nitrogen, and
oxygen, which are referred to as
thepseudocapacitance effect [13].
Electrospinning is a promising technique
used to fabricate nano/micro membrane separators
in a very short period of time with minimum
investment. Polymeric separators fabricated by the
electrospinning possess a unique texture with
micro and/or nanosize fiber arrangements,
flexibility, and high surface area and porosity. This
can be a promising material for various types of
separators.The main focus here is the fabrication of
a separator with high ionic conductivity and
electrochemical stability. Among many polymers,
PVdF has presented better results due to its high
electrochemical stability and particularly excellent
electrical properties, which can be useful in
supercapacitor applications,although the flexibility
of PVdF is not sufficient due to its high crystalline
structure and may eventually cause some
difficulties [14].
Electrospun polymer such as PVdF and its
derivatives, can be used as nanofiber mats in
RESEARCH ARTICLE OPEN ACCESS

separators of Li-ion batteries, due to its nanoporous
structure leading to increased ionic conductivity
[15]. Uniform electrospun PVdF membrane
thickness and fiber diameter can be obtained by
using high polymer concentrations and
electrospinning at relatively high spinning voltage.
This improves mechanical strength and provides
the PVdF separator with charge and discharge
capacities that generally exceed commercial
polypropylene separators, while resulting in little
capacity loss [15].
Karabelli et al. [16] prepared PVdF
separators for supercapacitor applications, and
studied the different properties of PVdF separator
such as thermal, mechanical and ionic conductivity.
Polymeric materials are widely used as separators
and as electrodes in batteries and in ultracapacitors.
PVdF contains various phases, the most common
being the α-phase. The pyroelectric and
piezoelectric features of the β-phase of PVdF
provide better material properties [17]. The
purpose of this study was to fabricate separators
for supercapacitors using the electrospinning
technique and investigate their ionic, dielectric,
and surface properties.
1.2. Electrospinning
Electrospinning is an effective method to
produce woven and non-woven micro/nanoscale
fibers from a polymeric solution. The process
parameters can be optimized to prepare separators
having extraordinary properties. The resultant
fibers generally have a large surface area,
flexibility, and uniform porosity [18, 19]. Some
conventional fiber-spinning methods, such as melt
spinning, dry spinning, and gel spinning, are
capable of producing fibers with diameters in the
range of micrometers, but the electrospinning
technique produces non-woven polymeric fibers in
the micro to nanometer range. It also presents a
high surface area compared to conventional fiber-
forming methods [20].
In electrospinning, a high-voltage or high-
electric field is used to overcome the surface
tension of the polymeric solution. When the
intensity of the electric field is increased beyond a
certain limit, called threshold intensity, the
hemispherical surface of the polymer solution at
the tip of the capillary tube begins to elongate into
a structure known as the Taylor cone.Electrospun
fibers form from the plastic stretching of a
polymeric solution jet while the solvent evaporates,
and the polymer solidifies at micro and nanolevels.
In this technique, a polymer solution is transferred
into a syringe, and a continuous filament is drawn
from the nozzle to the collector by utilizing a high
electrostatic field. A charged polymer jet is ejected
from the nozzle due to electrostatic repulsion.
Afterward, the filaments are deposited on the
collector surface, which is located some distance
from the capillary tube [20].
Lewandowski et al. [21] studied the
electrochemical performance of a totally solid state
electric double – layer capacitor using a polymer
electrolyte and an activated carbon powder as
electrode material in which polymer electrolyte
serves as separator as well as electrode material.
Sivaraman et al. [22] reported all-solid-
supercapacitor based on chemically synthesized
polyaniline (PANI) and sulfonated polymers
having fluorinated ethylene propylene copolymer
grafted with acrylic acid and sulfonated (FEP-g-
AA-SO3H) membrane (separator). Electrospun
polymers such as polyvinylidene fluoride (PVdF)
and polyacrylonitrile (PAN) and many other, can
be used as nanofiber mats in separator applications
in electronic devices [15]. These separators
provide nanoporous structure leading to increased
ionic conductivity of membrane soaked with liquid
electrolyte [15]. A separator should be
mechanically, chemically, and thermally stable and
should allow ions to transfer, but prevent electrical
short circuit. However, a separator has two main
functions: the first one is to provide electronic
insulation between electrodes of opposite
polarization and the second one is to allow ionic
conduction from one electrode to another.
A uniform electrospun PVdF membrane
thickness can be achieved by using high polymer
concentration and carrying out electrospinning at
high voltage. This provides mechanical strength
and also results in charge and discharge capacities
that exceed many commercially available
separators [15]. High crystallinity of PVdF
generally impedes conductivity. Therefore, PVP
was added in polymeric solution in order to
account for conductivity limitation caused by
PVdF high crystallinity and also it increases
electrospinnability of polymeric solution.PVP is
ahydrophobicizer and stabilizer, and it can greatly
improve membrane oxidative stability and
chemical stability [23, 24].Qiao et al. [23]
determined the chemical stability of PVA/PVP
membrane by immersing it in different
concentration of KOH at elevated temperature, in
order to test the tolerance of the membrane at
elevated temperature in KOH solution.
Conventional capacitor technology has
focused on minimizing the area of electrode plates
and then combining these plates with thin layers of
insulating separator having high dielectric constant
possibly resulting in high capacitance values [25].
This methodology has certain limits, as separator
film can be of minimum thickness before it fails
and there are also limits on the dielectric constant
of film material [25]. Usingthe electrospun PVdF

and PVP membranes incorporated with carbon
black not only increase the surface area of
separator and wettability, but also provide the
mechanical stability to the separator and increase
the dielectric constant values of separators, as well.
Figure 1 shows a schematic illustration of an
electrospinning process. Fibers produced by this
method can be used for many industrial
applications, such as sensors, filters, biomedical
purposes, compositereinforcement, solar cells, fuel
cells, batteries, supercapacitors, and membrane
technology [20, 26].
II. Experimental Procedure
2.1. Materials
PVdF and PVP with molecular weights of
180,000 g/mole and 130,000 g/mole, respectively,
were purchased from Sigma-Aldrich and used
without any modification or purification. Carbon
black (ELFTEX8) was purchased from the Cabot
Company and used as reinforcement nanoparticles
(15–60 nm). N, N-dimethylacetamide (DMAC)
and acetone, were purchased from Fisher Scientific
and used as solvents. Figure 2 shows SEM images
of the carbon black powder. As can be seen, the
particles are mainly aggregated and need to be
dispersed prior to the electrospinning process.
2.2. Methods
2.2.1. Fabrication of Nanocomposite Fibers
Different weight percentages (0, 0.25, 0.5,
1, 2, and 4 wt%) of carbon black nanopowders
were dispersed in the DMAC/acetone solvent and
sonicated for 90 minutes; then PVdF and 2 wt%of
PVP were added separately to the dispersions. The
weight ratio was 80 wt. % solvents (including
DMAC and acetone, were 70/30 in weight
proportions respectively) and 20 wt. % of polymers
(including 18 wt. % PVdF and 2 wt. % PVP). The
solution was constantly stirred at 550 rpm and
60C for five hours before the electrospinning
process. Special care was taken to ensure a
homogeneous blend of the mixture. The dispersed
solution was transferred to a 10 ml plastic syringe
connected to a capillary needle having an inside
diameter of 0.5 mm. The electrospinning
parameters of voltage, distance between tip and
collector, and syringe pump speed were 25 kV DC,
25 cm, and 2 ml/hr, respectively. The theoretical
density of polymeric solution with 4 wt. % of
carbon black was calculated as 1.069 g/cm3
, based
on rule of mixtures. Electrospun fibers were then
collected on an aluminum screen and dried in an
oven at 60C for eight hours to remove all residual
solvents.The theoretical density of electrospun
fibers with 4 wt. % of carbon black was calculated
as 1.72 g/cm3
, based on rule of mixtures. PVP is a
very good adhesive agent and it is used in batteries
as a special additive. PVP is used to glue the
membrane together for efficient electrochemical
performance of supercapacitors. The reason for
using PVdF is that it generally performs
significantly better in many applications where
strength, resistance to solvents and heat are
required. PVdF is also used as insulator on
electrical wires due to its combination of low
weight, low thermal conductivity and high thermal
and chemical resistance. Additionally, PVdF is a
binder material usually used in the production of
composite electrodes in lithium ion batteries.
Figure 3 shows the SEM images of PVdF/PVP
nanofibers incorporated with carbon black
nanopowders, indicating that most of PVdF
nanofibers are in nanosize(100 and 200 nm).
However, some beads were formed during the
electrospinning of 4 wt% carbon black, as shown
in Figure 3(f), which may have been due to the
mixture’s high carbon content. A good
combination of PVdF/PVP and carbon black
nanopowders is observed in all samples.A
membrane thickness of 0.5 mm was used in this
experiment. As can be seen in all SEM images
(Figure 3), there was no pronounced difference in
the fiber diameter as the weight % of carbon black
increased. In electrospinning, the fiber diameter
depends on the viscosity of the polymeric solution
and the distance between the capillary tube and
collector screen distance. The viscosity generally
depends on the molecular weight of the polymers
and solvent types used for dissolution. In the
present study, a constant distance of 25 cm was
maintained between the capillary tube and
collector screen throughout the experiment. A
higher distance will lower the intensity of the
electrostatic field. There could be some shrinkage
during the heat treatment at 60C for eight hours to
remove all residual solvents and polymer change
alignments. However, this shrinkage is very minute,
so fibers retained their shape and morphology after
the heat treatment. The average diameter of fibers
was observed to be between 100 and 200 nm in all
the cases.
2.2.2. Capacitance Measurements
The dielectric constant values of the
PVdF/ PVP nanocomposite fibers as a function of
carbon black were calculated using a parallel-plate
capacitor. An Andeen Hagerling 2550A Ultra
Precision capacitance bridge was used to measure
the capacitance of the parallel-plate capacitor.
Figure 4 represents a schematic of the dielectric
constant measurement following the ASTM D 150
test. The dielectric constant r can be obtained
from the measured capacitance C with the help of
electrodes of a known cross-section area A, layer
thickness d, and vacuum dielectric constant o

(8.85 x 10-12
pF/m), using the following equation
[18]:
0
.
r
C d
A


 (1)
The metal parallel-plate capacitor was
composed of 0.5-cm-thick aluminum. PVdF/PVP
nanocomposite fibers samples containing different
weight percent of carbon black were placed
between the aluminum conductor plates, which
were tightly held together by hard and rigid plastic
clips to ensure a complete contact between them
and the fiber samples. After the setup was
completed, the conductor plates were connected to
the capacitance bridge, which also served as a DC
power supply. As the current flowed, the
aluminum plates connected to the positive and
negative electrodes of the capacitance bridges were
negatively and positively charged, respectively,
creating a potential difference between the plates.
2.2.3. Water Contact Angle Measurements
The water contact angle values of the
PVdF/PVP samples as a function of carbon black
concentration were determined with an optical
contact angle goniometer, purchased from KSV
Instruments Ltd. (Model #CAM 100). This
compact, video-based instrument is used to
measure contact angles between 1 and 180 with
an accuracy of ±1. Computer software provided
by KSV Instruments Ltd. precisely measured and
also took pictures of the contact angles. Samples
were cleaned with deionized water and dried in a
vacuum overnight. Then they were placed on the
goniometer stage, and a droplet of water was
gently dropped on the sample from a syringe
attached to the goniometer.
2.2.4. Ionic Conductivity Measurements
Electrochemical impedance spectroscopy
(EIS) is an important tool for defining the electrical
properties of materials. A Gamry instrument
(Reference 600, Potentiostat/Galvanostat/ZRA)
was utilized to characterize the ionic conductivity
of the PVdF and PVP electrospun nanofibers. An
aqueous solution of 6M KOH, which is a common
electrolyte for liquid supercapacitors [2, 3, 23],
was used during the ionic conductivity
measurements. The conductivity values of the
polymeric fibers were calculated using the
resistance obtained from a slope of the I-V plot, a
known area of the film (A), and the measured
thickness of the film (L) [27] using the following
equation:
L
R A
  (2)
WhereR represents resistance obtained from the
slope of the I-V plot.
III. Results And Discussion
3.1. Capacitance Measurement Tests
Dielectric materials are used in almost all
electrical equipment. They have low conduction
and the capability of storing an electric charge. The
dielectric properties of polymers are very
important in many industrial applications, such as
cable insulation, encapsulates for electronic
components, and wiring board materials.Dielectric
materials can store an electric charge in different
forms depending on theirstructure [18, 28]. Higher
filler material loadings will generally increase the
dielectric constant values to a notable limit, so that
the material can be used for various industrial
applications. However, some properties of
composites, such as thermal, electrical, and
mechanical, may degrade due to higher filler
loadings. Accordingly, the weight percentage of
carbon black nanopowders was limited to 4 wt% in
the present studies.
Figure 5 shows the dielectric constant
values of the obtained PVdF/PVP nanocomposite
fibers as a function of carbon black concentration.
As can be seen, the addition of carbon black in
PVdF/PVP nanofibers results in higher dielectric
constants. Generally, the dielectric propertiesof a
polymer depend on temperature, frequency,
structure, and composition of the polymer and
filler materials.
The measured dielectric constants of the
nanocomposite fibers remarkably increased from
1.59 to 3.97, when the carbon black concentration
reached 4 wt% in the PVdF/PVP nanocomposites.
As observed in Figure 5, the dielectric constant
values of PVdF/PVP samples were significantly
increased by adding 1 wt% of carbon black in the
fibers. By increasing the carbon black weight
percentage to 4 wt% in the PVdF/PVP fibers, the
dielectric constant values were slightly enhanced to
3.97.
This drastic improvement in dielectric
constant values of PVdF/PVP fibers is attributed to
the charge carrier concentration of carbon black
embedded into the polymer structures [27]. The
addition of carbon black to a polymer will certainly
increase the charge carrier concentration, thereby
increasing the polarizability of the electrospun
fibers [18]. The relationship between the dielectric
constant εr and the molecular polarizability αt is
given by [29]
0
1 ( )
t
r
N 


  (3)
Where 𝑁 is the concentration of
molecules, and 𝜀0 is the permittivity of free space.

According to this relation, the dielectric constant
must increase by increasing the polarizability.
3.2. Surface Hydrophobicity
Contact angle measurements were
conducted on the PVdF/PVP nanocomposite
samples in order to determine the effects of carbon
black nanopowders on the surface properties of the
fibrous separators. Hydrophobicity and
hydrophilicity are terms related to the behavior of
solid surfaces when placed in contact with water
droplets. A hydrophobic surface is one on which a
droplet of water forms a contact angle greater than
90o
, whereas a hydrophilic surface is one on which
a droplet of water forms a contact angle less than
90o
[30]. Polymer surfaces with contact angles
between 150o
and 180o
are called super-
hydrophobic. This phenomenon is also known as
the “lotus effect”, which exhibits self-cleaning and
anti-contamination features [31].
The hydrophobicity or wettability of a
separator plays an important role in the
performance of a supercapacitor because a
separator with high wettability can retain the
electrolyte solutions and facilitate the diffusion of
electrolytes. Table 1 shows the contact angles of
PVdF/PVP fibers at different carbon black
loadings.
Contact angles values of the PVdF/PVP
fibers were slightly decreased by adding carbon
black nanopowders. However, nanocomposite
fibers indicated hydrophobic behaviors when the
carbon black concentration reached 0.5 wt%. Then,
increasing the carbon black percentages in the
PVdF/PVP fibers exhibited hydrophilic behaviors,
which may be more suitable for supercapacitor
separators. The addition of 4 wt% of carbon black
into PVdF/PVP fibers improved the wetting
property of the surface and showed a contact angle
of 78.51.
PVP has higher wettability characteristics
than PVdF because the surface tension of PVP (68
mN/m) fibers is much higher than that of PVdF
(33.2 mN/m). Therefore, it is obvious that a
combination of PVdF and PVP can provide better
properties for supercapacitor separators. Increasing
the carbon black content improved the surface
wettability of membranes which might be due the
high surface area of carbon black (1500 m2
g-1
),
surface energy and accessible surface to perform
higher hydrophilicity [7, 32, 33]. The membrane
should soak quickly and completely in typical
aqueous electrolytes to transport ions, but should
not dissolve in the electrolytes and change the
physical and chemical properties during charging
and discharging.
3.3. Ionic Conductivity Tests
Generally, encapsulation of a polymer
matrix with conducting elements can also increase
the ionic conductivity [34, 35]. Figure 6 shows the
ionic conductivity values of PVdF/PVP nano
composite fibers as a function of carbon black
nanoparticles. As can be seen, the ionic
conductivity of the carbon black-based PVdF/PVP
nanocomposite fiber samples increased 76.86% at
4 wt% carbon black loading.The calculated ionic
conductivity values of PVdF/PVP nanofibers are
given in Table 2.
Test results clearly indicate that the
incorporation of carbon black raises the ionic
conductivity, which may considerably increase the
functionality of supercapacitor separators. The
measured ionic conductivity value for the
PVdF/PVP fibers without the addition of carbon
black was 2.42 × 10-4
S cm-1
, which increased to
4.28 × 10-4
S cm-1
by adding 4 wt% of carbon
black to the fibers.Increasing the ionic conductivity
with a higher carbon black percentage is also
confirmed with a higher value of capacitance in the
presence of 4 wt% carbon black compared to
PVdF/PVP fibers without the addition of carbon
black. The high ionic conductivity may be
attributed to the interconnected pores by carbon
black nanopowders and the molecular structure of
PVdF. Carbon blacknanoparticles are found to be
highly branched with open structures, and high
porosity which might assist ionsto move faster,
resulting in higher ionic conductivity at higher
carbon black contents in the microstructure
[7].Porous separators with an accessible
transportation path will provide better movement
for ions between anode and cathode electrodes.
Due to their nanoscale size, conducting polymer
nanostructures are expected to improve
performance and shorten the diffusion path length
for transporting ions.
IV. Conclusions
The electrospinning method was
employed to fabricate various polymeric
PVdF/PVP separators incorporated with different
percentages of carbon black nanoparticles for
supercapacitors with high porosity, surface area,
and ionic conductivity. Following the
electrospinning process, the nanofiber samples
were characterized using SEM, the capacitance
bridge, the water contact angle, and GAMRY/EIS.
The PVdF/PVP nanofibers were mainly nanosize
(between 100 and 200 nm). The ionic conductivity
of the PVdF/PVP electrospun membranes reached
4.28 × 10-4
S cm-1
by adding 4 wt% of carbon
black. The dielectric constant values of the fibers
were significantly increased in the presence of
carbon black nanopowders, which may have been
the result of the charge-carrying nanoinclusions

embedded into the polymer structure. The
wettability of the PVdF/PVP nanofibers improved
by adding carbon black nanoparticles in the
polymer structure. The present study clearly shows
that electrospun nanocomposite fibers have
excellent physical and chemical properties, which
may be effectively utilized for the fabrication of
supercapacitor separators.
V. Acknowledgment
The authors gratefully acknowledge the
Kansas NSF EPSCoR (#R51243/700333), and
Wichita State Universityfor the financial and
technical support of this work.
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Table Captions:
Table 1: Water contact angle values of electrospun
PVdF/PVP nanocomposite fibers as a function of
carbon black concentrations.
Table 2: Ionic conductivity values of electrospun
PVdF/PVP nanocomposite fibersas a function of
carbon black concentrations.
Figure Captions:
Figure 1: Schematic view of electrospinning
process.
Figure 2: SEM images of carbon black (ELFTEX8)
powderat low (left) and high (right) magnifications.

Figure 3:EDX SEM images: (a) electrospun
PVdF/PVP fibers, and incorporated with (b)
0.25wt%, (c) 0.5wt%, (d) 1wt%, (e) 2wt%,and (f)
4 wt%carbon black.
Figure 4: Schematic view of capacitance
measurement of dielectric materials using ASTM
D 150 test.
Figure 5: (Color online) Dielectric constant values
of PVdF/PVP fibers as a function of carbon
blackconcentrations.
Figure 6: (Color online) Linear sweep
voltammogram curves for PVdF/PVP
nanocomposite fibersas a function of carbon black
concentrations.
Table 1:
Carbon Black
Concentration (wt %)
Water Contact
Angle (o
)
0 112
0.25 111
0.5 95
1 81
2 80
4 78
Table 2:
Carbon Black
Concentration (wt %)
Ionic Conductivity
(Scm-1
)×10-4
0 2.42±0.04
0.25 2.90±0.03
0.5 3.56±0.04
1 3.87±0.05
2 4.05±0.03
4 4.28±0.05
Figure 1:
Figure 2:
(a)
(b)
(c)

(d)
(e)
(f)
Figure 3:
Figure 4:
Figure 5:
Figure 6:

Tuning the Ionic and Dielectric Properties of Electrospun Nanocomposite Fibers for Supercapacitor Applications

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