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Engineering, Technology & Applied Science Research Vol. 11, No. 3, 2021, 7228-7232 7228 
 

www.etasr.com Ahmad et al.: Influence of Starch Content on the Thermal and Viscoelastic Properties of Syndiotactic … 

 

Influence of Starch Content on the Thermal and 

Viscoelastic Properties of Syndiotactic 

Polypropylene/Starch Composites 
 

Naveed Ahmad 

Department of Chemical and Material Engineering 

College of Engineering 
Northern Border University 

Arar, Saudi Arabia 

naveed.ahmad@nbu.edu.sa 

Farooq Ahmad 

Department of Chemical and Material Engineering 

College of Engineering 
Northern Border University 

Arar, Saudi Arabia 

farooq.ahmad@nbu.edu.sa 

Ibrahim Alenezi 

Department of Chemical and Material Engineering College of Engineering 
Northern Border University 

Arar, Saudi Arabia 
i.alenezi@nbu.edu.sa 

 

Abstract—In this study, syndiotactic Polypropylene/Starch 

(sPP/starch) composites were prepared using a solution mixing 

technique. The thermal characterization was performed using 
Differential Scanning Calorimetry (DSC), and the melting point 

was measured for all polymer composites. The thermal 

degradation temperature was measured using thermal 

gravimetric analysis. The viscoelastic measurements were 

performed using the Atomic Rheometric Expansion System 

(ARES). Both melting point and thermal degradation 
temperatures were found to decrease with increasing starch 

content. Moreover, the elastic modulus was found to decrease 
when the starch content increased. 

Keywords-aeration; melting point; sPP/starch composites; 

thermal degradation temperature; elastic modulus; frequency 

sweep test 

I. INTRODUCTION 

Polymer composites are synthesized by embedding natural 
or synthetic materials into a polymer to increase its desired 
properties [1, 2]. Several studies have been conducted on 
enhancing the properties of polymer products [3-23]. Polymer 
composites with different combinations of filler and polymer 
are studied in order to obtain the desired and targeted properties 
of polymer products [3]. However, the final desired 
microstructure and macrostructure properties of polymers and 
composites depend on the nature, amount, geometry, and 
interfacial interactions of the components [4]. Rheology is used 
as a tool to study a polymer's or a polymer composite's 
microstructure, as the rheological response is highly sensitive 
to the molecular structure of polymers and their composites [5-
9]. While several studies have been conducted on the synthesis 
and the rheology of polymer and polymer/clay composites [10-

18], only a few have targeted the viscoelasticity of 
polymer/clay composites. 

The rheological properties of polyethylene 
oxide/montmorillonite clay gels and multilayered films were 
studied in [14], using an Atomic Rheometric Expansion system 
(ARE-2 rheometer), and noticing a slight increase in both the 
loss modulus (G') and the storage modulus (G'') when 
increasing the clay content. The thermal properties were 
examined using Differential Scanning Calorimetry (DSC) and 
Thermal Gravimetric Analysis (TGA), while the results were 
related to the microstructural properties of the composites and 
the films. The effect of clay content on the rheology of 
polypropylene/clay nanocomposites was investigated in [15], 
examining both linear and non-linear rheology, finding that 
loss modulus (G'), storage modulus (G''), and dynamic 
viscosities increased monotonically with organophilic 
montmorillonite nanocomposites. The viscoelastic properties of 
syndiotactic polypropylene (sPP) were investigated in [16], 
examining the effect of the degree of syndiotacticity on the 
rheological parameters, including plateau modulus and 
entanglement molecular weight. This study indicated that 
increasing the degree of syndiotacticity enhanced the plateau 
modulus causing a decrease in the molecular weight between 
entanglements. In [17], the influence of clay contents on 
plateau modulus and entanglement molecular weight was 
studied on polypropylene/clay composites, concluding that an 
increase in the clay content increased the plateau modulus and 
consequently decreased the entanglement molecular weight. 
The rheological properties of a drilling fluid polymer treating 
agent named Driscal-D using a Fann 50SL rheometer were 
investigated in [24]. The effects of adding polymer, electrolyte, 
clay type, and antioxidant on the rheological properties of a 

Corresponding author: Naveed Ahmad 



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Driscal-D solution were examined, finding that solution's 
viscosity tends to increase when increasing polymer addition 
and decreased in the presence of an electrolyte. Furthermore, 
adding clay in a Driscal-D solution enhanced its rheological 
properties, which could improve cuttings transportation. 

The current study examines the viscoelasticity of 
syndiotactic polypropylene/starch composites (sPP/starch), 
with starch content ranging from 0 to 8%, using an Atomic 
Rheometric Expansion System (ARES) to investigate the effect 
of starch content on the melt rheological response of 
composites. 

II. METHODOLOGY 

A. Polymer Composite Synthesis 

1) Materials 

Syndiotactic Polypropylene (sPP) having a 60% degree of 
syndiotacticity, supplied by Zhongwei Industrial Co. Ltd., was 
used as a matrix. Starch, originating from potato, was used as 
the filler. Xylene, provided by Shanxi Zhongwei Industrial Co. 
Ltd., was used as a solvent in mixing. The samples' details are 
listed in Table I. 

TABLE I.  SAMPLES' DETAILS 

Number of 

samples 

Name of 

samples 

Percentage of 

starch content 

Degree of syndiotacticity 

(%rrr) 

1 sPP/S-8 8%  

2 sPP-6 6%  

3 sPP/S-4 4%  

4 sPP/S-2 2%  

5 sPP 0 60 

 

2) Preparation of Composite Samples 

Solution mixing was applied to create a set of syndiotactic 
polypropylene/starch composite samples with four different 
starch content proportions. The starch was accurately weighed 
and mixed with the polypropylene matrix using xylene as a 
solvent in a 1000ml beaker. The mixing temperature was kept 
at 120°C using a heating mantle until all syndiotactic 
polypropylene granules dissolved in a clear solution. The 
solvent containing syndiotactic polypropylene was initially 
shaken vigorously by hand and then stirred by a high-speed 
electrical stirrer keeping the heating conditions. The starch, 
dissolved in xylene, was added slowly to the syndiotactic 
polypropylene and xylene mixture. Vigorous and continuous 
stirring helped the uniformity of starch mixing and the 
intercalation of sPP to starch layers. The beaker operated for a 
few hours to evaporate the xylene. Then, the size of the 
prepared polymer-starch composite was mechanically reduced. 
After the completion of xylene evaporation, the composite 
samples were created by compression molding at 170°C 
temperature and 7Psi pressure for one and a half hour [10].  

B. Polymer Composite Analysis 

1) Differential Scanning Calorimetry (DSC) 

The melting temperature (Tm) of all samples was measured 
using Differential Scanning Calorimetry (DSC). The samples, 
weighing 4mg, were heated up to 350°C at a constant heating 

rate of 40°C/min. During the heating cycle, the melting point 
peak was obtained. Afterward, the sample was kept under this 
annealing process for 7 minutes to eliminate crystallinity and 
remove thermal history. The analysis was performed using the 
instrument software TA-60 to find the melting temperature 
(Tm) of all samples.  

2) Rheometry 

The sPP/starch composites were pressed using Hot Press to 
prepare a uniform film for each composite. An Atomic 
Rheometric Expansion System (ARES) (TA Instruments), 
having a geometry of 8mm diameter parallel plate, was used to 
perform the viscoelastic tests under nitrogen atmosphere to 
reduce sample degradation. All experiments were carried out at 
a different gap depending on the sample's thickness. At first, 
strain sweep and stability tests were carried out. After choosing 
the suitable strain value (0-10%), dynamic frequency sweep 
tests were performed at temperatures ranging from 100°C to 
200°C to obtain both elastic and viscous moduli at different 
frequencies and the master curves using the time-temperature 
superposition principle. No tests were performed below 100°C 
due to the faster crystallization kinetic.  

III. RESULTS AND DISCUSSION 

Frequency sweep tests were performed on all samples. The 
frequency sweep tests for samples having 2% and 6% starch 
contents are shown in Figures 1 and 2 respectively. It can be 
noted that the elastic modulus increased along with the 
frequency range (0 to 100rad/s), while the viscous modulus 
tended to decrease. Figure 1 shows a cross-over frequency at 
almost 1rad/s indicating that relaxation time was a little greater 
than 1s. Figure 2 shows that viscous was greater than elastic 
modulus at lower frequencies, while the elastic modulus was 
higher than viscous at higher frequencies. The cross-over 
frequency of the 6% sample was found to be greater than the 
one in the 2% sample, indicating that relaxation time for the 6% 
sample was less than for the 2%. This result also indicates that 
increasing starch content decreased the elastic and increased 
the viscous response. In other words, a strength decrease occurs 
when the starch content increases. 

 

 
Fig. 1.  Frequency sweep test for sPP/S-2 at 200°C. 



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Fig. 2.  Frequency sweep test for sPP/S-6 at 200°C. 

A. Effect of Starch on Melting Point 

The effect of starch on the melting point temperature of 
sPP/starch composites is shown in Figure 3. As it can be noted, 
increasing starch content decreased the melting point 
temperature of sPP/starch composites. The melting point of the 
composite was actually the melting point of starch. Starch's 
thermal stability is low compared to the syndiotactic 
polypropylene polymer. Therefore, increasing starch decreases 
the melting point temperature of sPP/starch composites. 

 

 
Fig. 3.  Relationship between starch and melting point (Tm). 

B. Effect of Starch on Thermal Degradation Temperature 

The thermal degradation temperature of all composites was 
measured using Thermal Gravimetric Analysis (TGA). The 
TGA analysis for the sPP sample containing 4% starch is 
shown in Figure 4. This Figure depicts two drops in mass: The 
first drop indicates the removal of water from the composite 
sample, i.e. the dryness of the sample, while the second drop 
indicates the degradation of the sample. Thermal degradation 
temperature decreased when increasing starch content, as 
shown in Figure 5. 

 

 
Fig. 4.  FDSC and TGA analysis of sPP/S-4. 

 

Fig. 5.  Relationship of thermal degradation temperature and starch content. 

C. Effect of Starch on Elastic Modulus 

The elastic modulus was calculated using frequency sweep 
tests for all samples. The maximum value for each sample was 
noted. The elastic modulus indicates the mechanical response 
of a sample, and it was examined as a function of starch 
content. Increasing starch content decreased the elastic 
modulus, as shown in Figure 6. Therefore, increasing starch 
content decreased the strength of the composites. This result 
comes in agreement with the findings of [17], which 
investigated the effects of clay content on the thermal and 
rheological properties of sPP/clay composites. Clay content and 
starch affected the rheological and thermal properties of 
sPP/clay composites oppositely. Clay content increased the 
melting point temperature and the plateau modulus of sPP/clay 
composites. On the other hand, starch decreased both the 
thermal properties and the elastic modulus. An increase in clay 
content increased the mechanical response of the sPP/clay 
composites, while an increase in starch content decreased the 
mechanical and increased the viscous response of syndiotactic 
polypropylene/starch composites. 

Starch (%age)

0 2% 4% 6% 8%

T
h
e
rm
a
l 
D
e
g
rd
a
ti
o
n
 (
C
)

280

300

320

340

360

380

400

420

440
Starch (% age) vs T

D
 (C) 



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Fig. 6.  Relationship between starch contents and elastic modulus. 

IV. CONCLUSION 

The viscoelastic and thermal analysis of sPP/starch on 
melting point, thermal degradation temperature, and elastic 
modulus depend on starch content. This stydy's findings 
showed that viscoelasticity is a powerful tool to investigate the 
microstructure and the chain parameters of polymer/starch 
composites. Thermal and viscoelastic properties were found 
sensitive to starch content proportions. Starch alters both the 
melting point and the thermal degradation temperatures, as 
increasing starch content decreased both of them. The same 
trend was found for the elastic modulus, as it decreased when 
the starch content increased. In conclusion, increasing starch 
content results in a decrease of the mechanical and elastic 
responses of the composite.  

ACKNOWLEDGMENT 

The authors wish to acknowledge the approval and the 
support of this research study by the grant no.7178-ENG-2017-
1-7-F from the Deanship of Scientific Research in Northern 
Border University, Arar, K.S.A. 

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