Microsoft Word - 164.docx


CHEMICAL ENGINEERING TRANSACTIONS 

VOL. 56, 2017 

A publication of 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Jiří Jaromír Klemeš, Peng Yen Liew, Wai Shin Ho, Jeng Shiun Lim
Copyright © 2017, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-47-1; ISSN 2283-9216

Fabrication, Characterisation, and Pervaporation 
Performance of Graphene/Poly(Vinyl Alcohol) Nanocomposite 

Membranes for Ethanol Dehydration 

Nguyen Huu Hieua,b, Ngo Nguyen Phuong Duyb 
a
Key Laboratory of Chemical Engineering and Petroleum Processing, Reseach Institute for Sustainable Energy  

b
Faculty of Chemical Engineering Ho Chi Minh City University of Technology, Vietnam National University, Ho Chi Minh City 

 nhhieubk@hcmut.edu.vn 

Malic acid cross-linked poly(vinyl alcohol)/graphene (MA-PVA/Ge) nanocomposite membranes were 
fabricated by solution-casting method. The effects of PVA, MA, and Ge concentrations on pervaporation (PV) 
performance of membranes for dehydration of 80 wt% ethanol solution were investigated. The membrane 
characterisations were performed by atomic force microscopy, transmission electron microscopy, Fourier-
transform infrared spectroscopy, X-ray diffraction, tensile testing, differential scanning calorimetry, swelling 
degree, and water contact angle. The characterisation and PV results indicated that the thermal stability, 
swelling degree, and separation performance of MA-PVA/Ge nanocomposite membrane were improved 
compared to neat PVA by adding 10 wt% PVA solution with 20 wt% MA and 0.15 wt% Ge in respect to the 
weight of PVA (20MA-10PVA/0.15Ge). This membrane exhibited good PV performance with a good selectivity 
of 596, an equivalent permeate flux of 0.12 kg/m

2h, and a high PV separation index of 68.4 kg/m2h for 
dehydration of 80 wt % ethanol concentration in the feed solution (CF) at feed temperature (TF) of 50 °C, feed 
flow rate of 60 L/h, and vacuum pressure (PV) of -100 kPa.  

1. Introduction

Ethanol is considered to be the most promising fuels of the future since it is obtained from renewable sources 
(He et al., 2012). Traditional methods for separating azeotropic mixture to obtain absolute ethanol include 
desiccation, using adsorbents, as well as azeotropic distillation and extractive distillation or vacuum distillation. 
In recent years, membrane technology could be applied (Frolkova et al., 2010). Pervaporation (PV), a binary 
or multi-component liquid mixture is separated by partial evaporation via a dense membrane (Barker, 2014). 
Poly(vinyl alcohol) (PVA) is a possible candidate. PVA must be modified to minimise the swelling in water 
when fabricated for the dehydration of ethanol solution. This can reduce its selectivity in the ethanol 
dehydration by PV, though PVA proved to be a satisfactory permeation flux. Cross-linking is a way to prevent 
this drawback of PVA (Yamasaki et al., 1995). The decrease in crystallinity was important (Peng et al., 2011). 
Malic acid (MA) is considered to be a right choice due to a more effective cross-linking and a superior water 
permeability in comparison to others (Peng et al., 2011). Enhancement the PV performance has been 
achieved by adding nanofillers into the polymer matrix (Ravindra et al., 2015).  
In this study, MA cross-linked PVA/Ge nanocomposite membranes with a different loading content of PVA, 
MA, and Ge were prepared to investigate the PV performance of membranes for dehydration of ethanol 
solution. 

2. Experimental

2.1 Materials 

PVA (MW 80,000 and > 98 %), sulfuric acid (98 wt%), sodium nitrate (99 wt%), hydrogen peroxide (30 wt%), 
hydrazine hydrate (35 wt%), and MA (99 wt%) were purchased from Xilong Chemical, China. Graphite 

 

   

DOI: 10.3303/CET1756283

 
 

 

 
 

 
 
 
 
 
 
 
 
 
 
 
 

 

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

 
 
 
 
 
 

 
 
 
 

Please cite this article as: Hieu N.H., Duy N.N.P., 2017, Fabrication, characterization, and pervaporation performance of graphene/poly(vinyl 
alcohol) nanocomposite membranes for ethanol dehydration, Chemical Engineering Transactions, 56, 1693-1698  DOI:10.3303/CET1756283   

1693



(particle size: < 50 µm, density: 20 - 30 g/100 mL) was purchased from Sigma Aldrich, Germany. Potassium 
permanganate (> 99.5 wt%) and ethanol (96 vol%) were purchased from ViNa Chemsol, Vietnam. All 
chemicals were used without any further purification. 

2.2 Membrane fabrication 

Ge was synthesised from graphite by a modified Hummers’ method. 0.05 g of Ge was dispersed in deionised 
water and sonicated for 24 h to obtain Ge suspension. According to the solution-casting method, 10 g of PVA 
was dissolved in deionised water and heated at 90 °C to form 10 wt% PVA solution. Then, 20 wt% (respect to 
the weight of PVA) of a cross-linking MA was gradually added. The solution was stirred for 5 h at 90 °C to 
completely cross-linked reaction. Next, 12 mL of Ge aqueous suspension corresponding to 0.15 wt% (based 
on the weight of PVA) was dropped into MA cross-linked PVA solution, and stirred for 1 h. The obtained 
homogeneous solution was casted on petri dish and dried at room temperature for 24 h to form the 
nanocomposite membrane. Finally, the membrane continued to be dried at 80 °C for 4 h to constant weight. 
The nanocomposite was denoted 20MA-10PVA/0.15Ge, corresponding to PVA, MA and Ge content of 10, 20, 
and 0.15 wt%. 

2.3 Characterisation 

Atomic force microscopy (AFM) measurement was performed on an AFM Nanotech Electronica by casting 
powder dispersion onto freshly cleaved mica substrates and drying under ambient condition. Transmission 
electron microscopy (TEM) images were taken by JEM-1400 machine with an accelerating voltage of 100 kV. 
Fourier-transform infrared spectroscopy (FTIR) spectra were obtained in the range of wavenumber from 4,000 
cm

-1 to  
500 cm-1 during 64 scans on Alpha–E Brucker (Bruker Optik GmbH, Ettlingen, Germany) spectrometer. X-ray 
diffraction (XRD) patterns were obtained by Advanced X8, Bruker (German) with λ = 0.154 nm, step of 4°/min 
from 10° to 40°. Tensile testing was performed with AND RTC 1210A (Tensilon, Japan), carried out under 
initial tensile length of 40 mm, drawing speed of 50 mm/min, and making use of a 1,000 N load cell. 
Differential scanning calorimetry (DSC) was performed with DSC-1 (Mettler Tolado, America) differential 
scanning calorimeter in the temperature range of from -50 °C to 250 °C. Swelling degrees (S) were carried out 
by immersing in deionised water at room temperature at least 48 h to reach absorption equilibrium, and were 
calculated as follows: 

%100×
−

=
D

DS

W

WW
S

 
(1) 

where WS and WD are the weight of swollen and dry membrane.          
Water contact angles measurements were assessed by a OCA20 contact angle meter equipped with an 
image capturing system. Static contact angles were measured by the sessile drop method.  

2.4 Pervaporation experiment 

A laboratory scale PV unit is shown in Figure 1. The membrane was placed on the stainless screen support in 
the module, with the effective surface area of 28.3 cm2. An aqueous ethanol of 80 wt% was used as feed 
solution. During the experiment, the feed solution was heated up to 50 °C and circulated through the 
membrane module from the feed tank. The pressure on the permeate side of membrane was kept at -100 kPa 
via a vacuum pump. The permeate vapour was collected in cold trap at -20 °C. For each experiment, the 
operating time was at least 2 h to ensure that a steady state was reached. The collected permeate in cold trap 
was weighted to calculate the permeate flux and measured the concentration by a refractometer to determine 
the selectivity. The performance of PV was expressed by permeate flux (J), selectivity (α), and PV separation 
index (PSI), as follows (Bruggen et al., 2015): 

t

W

A
J

Δ
Δ

=
1

 
(2) 

OHHCOH

OHHCOH

xx

yy

522

522=α
 

(3) 

)1( −= αJPSI
 (4) 

where ∆W (kg) is the weight of permeate during the experimental time ∆t (h), A (m2) is the effective membrane 
area; and x, y are the mass fraction of either water or ethanol in the feed and the permeate.  

1694



 

Figure 1: Schematic diagram of PV system. (1. Feed tank, 2. Metering pump, 3. Membrane module, 4. 
Membrane, 5. Cold trap, 6. Vacuum pump) 

3. Results and discussion 

3.1 Effect of PVA, MA, and Ge concentrations on pervaporation performance of membranes 

3.1.1 PVA concentration 
The effect of PVA concentration on the membrane performance are presented in Figure 2. Membrane 
selectivity increased while the permeation flux decreased (Hieu et al., 2016). However, the selectivity hardly 
increased when concentration of PVA was over 10 wt%. This can be explained as the free volume of water 
transferring channels have reached a limit value, which led to an insignificant changeability of the membrane’s 
selectivity. This phenomenon is in accordance with previous researches (Hieu et al., 2016). PSI is defined as 
a parameter to evaluate the performance of the overall PV process (Bruggen et al., 2015). As observed in 
Figure 2, at 10 wt% concentration, PVA membrane exhibited the highest PSI with a high permeate flux of 0.22 
kg/m2h and an equivalent selectivity of 28.7. This result indicated that PVA concentration of 10 wt% was a 
reasonable value for membrane fabrication.  

 

Figure 2: Effect of PVA concentration on J, α, and PSI 

3.1.2 MA concentration 
Nanocomposite membranes presented higher selectivity but lower permeate fluxes than that of neat PVA 
when MA contents were less than 20 wt% (Figure 3). The phenomenon showed in contrast when the MA 
contents are higher than 20 wt%. This can be due to the crystallinity and hydrophilicity which may affect each 
other. The crystallinity and hydrophilicity will decrease with the increase in density of cross-linking (Peng et al., 
2011). 

3.1.3 Ge concentration 
Effect of different Ge loading on PV performance of membranes is shown in Figure 4. At a low loading level (≤ 
0.15 wt%), Ge nanosheets were well-dispersed into and obtained stable structure PVA chains. This is in 
agreement with the initial theoretical prediction of Ge nanosheets’s acting as molecular sieves that help to 
reject large particles, such as ethanol, after they were dispersed into the PVA matrix (Lee et al., 2013).  

1695



 

Figure 3: Effect of MA content on J, α, and PSI 

 

Figure 4: Effect of Ge loading content on J, α, and PSI 

3.2 Characterisation 

3.2.1 AFM and TEM images 
AFM image and height profile for Ge are as shown in Figure 5. This result confirmed that Ge sheets were 
successfully synthesised with an average thickness of 0.953 nm. In order to evaluate the dispersion of Ge 
sheets in the PVA matrix, the ultrathin sections of membrane were observed via Figure 6. A homogeneous 
dispersion and alignment of Ge in PVA that obtained dark lines with the average thickness of 5 - 20 nm was 
observed in Figure 6.  
 

 

Figure 5:  AFM image and height profile of Ge Figure 6: TEM images of (a) vertical and (b) 
horizontal sections of 20MA-10PVA/0.15Ge 
membrane 

3.2.2 FTIR analysis 
Figure 7 shows the FTIR spectra of 20MA-10PVA, 20MA-10PVA/0.15Ge, and neat PVA membranes. The 
absorptions at 3,550 cm-1 – 3,200 cm-1, 2,840 cm-1 – 3,000 cm-1, and 1,145 cm-1 are typical to the presence of 
–O–H, –CH2– (symmetric and asymmetric) and –C–O groups of PVA matrix (Gohil and Ray, 2006). 
Compared to PVA, the spectra of 20MA-10PVA and 20MA-10PVA/0.15Ge exhibited an enhancement of the –

1696



C=O stretching peak at 1,741 cm-1 and the decrease in the –O–H and –C–O stretching vibration, which can be 
identified as the formation of ester bonds between –COOH groups of MA and –OH groups of PVA chains 
(Bolto et al., 2009). For 20MA-10PVA/0.15Ge membrane, it is noticed that there are the same intensities of 
peaks as that of MA-PVA membrane.  

3.2.3 Membrane crystallinity 
XRD is an effective method to characterise the crystalline properties of nanocomposite. As shown in Figure 8, 
the peak of Ge, and neat PVA appeared at 2θ ≈ 10° and 20°. This result demonstrated the dispersion of the 
Ge nanosheets into matrix and the completeness of cross-linking reaction of MA with PVA. 

Figure 7: FTIR spectra of membranes. Figure 8: XRD patterns of Ge and membranes. 

3.2.4 Mechanical properties 
The tensile strength, TB, and elongation at break, EB, of PVA and nanocomposite membranes are summarised 
in Table 1. The decrease in TB of composite membranes was observed. The decreasing trend of TB confirmed 
the fact that the degree of crystallinity and the mechanical strength of polymer often go hand in hand, i.e., the 
higher the crystallinity. Further, as a matter of fact, the expense of TB is generally on the enhancement of EB of 
material (Lee et al., 2013).  

Table 1: Tensile strength, Tb, elongation at break, EB, swelling degree and water contact angles of 
membranes 

Membranes TB (MPa) EB (%) Swelling degree (%) Contact angle (°) 
10PVA 176.45 4.46 89 51.6 
20MA-10PVA 128.54 4.69 66 62.3 
20MA-10PVA/0.15Ge 96.36 4.08 54 67.5 

3.2.5 Thermal properties 
From the DSC curves as shown in Figure 9, Tg and the melt isotherm, Tm of membranes were 125 – 131 °C 
and 224 °C. At the same time, new bridges are being generated between the chains through the cross-linker 
and the incorporation are occurring due to its acting as a nucleating agents of fillers with the chains (Lee et al., 
2013). 

3.2.6 Swelling degree 
Table 1 shows the swelling properties of PVA and nanocomposite membranes. The presence of a large 
number of the hydroxyl groups in PVA results in strong hydrogen bonding, which in turn decreases the 
swelling of PVA in water. For 20MA-10PVA and 20-MA-10PVA/0.15Ge membranes, the swelling degree was 
greatly suppressed. This can be explained by cross-linking of the PVA polymer chains through the formation 
of ester linkages between carboxylic groups of MA and hydroxyl groups of PVA chains (Gohil and Ray, 2006). 

3.2.7 Contact angle 
Water contact angle results are shown in Figure 10 and Table 1. The membranes were hydrophilic. The neat 
PVA showed the highest hydrophilic, with a water contact angle of 51.6°. This is due to the increase in the 
cross-linking density of PVA via MA, and the dispersion of hydrophobic Ge sheets into PVA chains.   

1,0001,500 2,000 2,500 3,000 3,500 4,000 

1697



 

Figure 9: DSC curves of membranes 

 

 

 

Figure 10: Photographs of water contact angles: (a) 
PVA, (b) 20MA-10PVA, and (c) 20MA-10PVA/0.15Ge. 

4. Conclusions  

A nanocomposite membrane was fabricated via a solution-casting method. Pervaporation testing results of the 
membrane for dehydration of 80 wt% ethanol solution demonstrated that the addition of 20 wt% MA and 0.15 
wt% Ge in respect to the weight of PVA resulted in a good selectivity of 596, permeate flux of 0.12 kg/m2h, 
and PSI of 68.4 kg/m2h. AFM image indicated that the successfully synthesised Ge with an average thickness 
of 0.953 nm was obtained. TEM images revealed that Ge nanosheets dispersed into the PVA matrix to the 
dark lines with an average thickness from 5 - 20 nm. Tensile testing, DSC, swelling degree, and water contact 
angle analyses demonstrated that the characteristics of 20MA-10PVA/0.15Ge membrane were improved in 
comparison to PVA.  

References 

Barker R.W., 2014, Membrane Technology and Application, 2nd ed., John Wiley & Sons, New Jersey, USA. 
Bolto B., Tran T., Hoang M., Xie J., 2009, Crosslinked poly(vinyl alcohol) membranes, Progress in Polymer 

Science 34, 969-981. 
Bruggen B.V., Luis P., 2015, Chapter 4: Pervaporation, Ed. Tarleton E.S., Progress in Filtration and 

Separation, Academic Press, Massachusetts, USA, 101-154. 
Frolkova A.K., Raeva V.M., 2010, Bioethanol dehydration: state of the art, Theor Found Chem Eng 44, 45-

556. 
Gohil J.M., Ray P., 2006, Studies on the cross-linking of poly(vinyl alcohol), J Polym Res 13, 161-169. 
He Y., Bagley D.M., Leung K.T., Liss S.N., Liao B.Q., 2012, Recent advances in membrane technologies for 

biorefining and bioenergy production, Biotechnology Advances 30, 817-858. 
Hieu N.H., Long N.H.B.S., Kieu D.T.M., Nhiem L.T., 2016, Fabrication and characterzation of graphene and 

graphene oxide-based poly (vinyl alcohol) nanocomposite membranes, J Electron Mater 45, 2341-6. 
Lee S., Hong J.Y., Jang J., 2013, The effect of graphene nanofiller on the crystallization behavior and 

mechanical properties of poly(vinyl alcohol), Polymer International 62, 901-908,. 
Peng F., Jiang Z., Hoek E.M.V., 2011, Tuning the molecular structure, separation performance and interfacial 

properties of poly(vinyl alcohol)-polysulfone interfacial composite membranes, Journal of Membrane 
Science 368, 26-33. 

Ravindra S., Rajinikanth V., Mulaba-Bafubiandi A.F., Vallabhaburabu V.S., 2015, Performance enhancement 
of the poly(vinyl alcohol) (PVA) by activated natural clay clinoptilolite for pervaporation separation of 
aqueous-organic mixtures, Desalination and Water Treatment 57, 1-15. 

Yamasaki A., Iwatsubo T., Masuoka T., Mizoguchi K., 1995, Pervaporation performance of asymmetrically 
crosslinked PVA membranes, Journal of Applied Polymer Science 58, 1657-1660. 

1698