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CHEMICAL ENGINEERINGTRANSACTIONS 
 

VOL. 60, 2017 

A publication of 

 
The Italian Association 

of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Luca Di Palma, Elisabetta Petrucci, Marco Stoller
Copyright © 2017, AIDIC Servizi S.r.l. 
ISBN978-88-95608- 50-1; ISSN 2283-9216 

Role of Structure of the Pp/Magnetite Nanocomposites on 
Their Thermal Properties 

Abel M.Maharramova, Mahammadali A.Ramazanova*, Luca Di Palma*b, Flora 
V.Hajiyevaa, Habiba А.Shirinovaa, Ulviyya A.Hasanovaa 
a
Baku State University, Physics Faculty, Z. Khalilov Street, 23 Baku, AZ1148, Azerbaijan. 

b
Sapienza University, Department of Chemical Engineering Materials Environment, Via Eudossiana 18, 00184, Roma -INSTM, 

UdR Uniroma1 Sapienza 
mamed_r50@mail.ru 

The thermal degradation behaviour of polypropylene and its magnetite  composites have been investigated by 
differential scanning calorimetry (DSC) and  thermogravimetric analysis (TGA). Distribution of magnetite 
nanoparticles in a polymer matrix has been studied by scanning and transmission electron microscopy and also 
atomic force microscopy. The thermal and mechanical properties of nanocomposites based on polypropylene 
and magnetite nanoparticles have also been investigated. It has shown that, the introduction of Fe3O4 
nanoparticles in polypropylene increases its thermal stability of about 1000C. The maximum increase in the 
thermal stability of PP was observed in the case of a 20% weight content of Fe3O4 nanoparticles in 
polypropylene. 

1. Introduction 

In recent years there has been increasing interest to the composites based on thermoplastic polymers, filled 
with homogenous nanoparticles. The properties of composites polymers with inorganic nanoparticles have been  
determined by the properties of the mixed components and structure of derived composites [А.M.Мagerramov 
2013]. For use of polymer nanocomposites at a relatively high temperature conditions, their thermal stability is of 
great importance. Materials with additive polymer nanocomposites on the one hand have enhanced thermal 
stability which may exhibit resistance to combustion; even impart fireproofing properties to the product, and on 
the other hand- the freezing resistance. Polypropylene is a polycrystalline polymer having attractive mechanical 
properties such as strength and elasticity at ambient temperature. PP with fillers is considered to be one of best 
thermoplastic materials. At high temperatures, the polypropylene with embedded nanoparticles may reveal even 
more interesting and meaningful properties. Modification of polypropylene (PP) leads to creating a variety of 
composite materials and allows to solve the problem of obtaining materials with desired properties and expand 
the area of their use[A.M. Maharramov 2012]. 
Fe3O4 nanoparticles are of great practical application in microelectronics for the creation of unique miniaturized 
sensors; in biomedicine - to develop drug delivery systems; in obtaining of nanocomposites that can find its 
application as effective catalysts in various chemical processes as well as in various fields of science and 
technology. Therefore, the study of physical and chemical properties of magnetic polymer nanocomposite based 
on PP+Fe3O4, including its thermal and mechanical properties is an urgent problem.In this work we have 
studied the role of the structure of nanocomposites based on polypropylene and magnetite 
Fe3O4 nanoparticleson the thermal properties of nanocomposites, as well as the relation between the structure 
and properties of nanocomposites[M.A. Ramazanov 2016]. 

                               
 
 

 

 
   

                                                  
DOI: 10.3303/CET1760010

 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Maharramov A., Ramazanov M., Di Palma L., Hajiyeva F., Shirinova H., Hasanova U., 2017, Role of structure of the 
pp/magnetite nanocomposites on their thermal properties, Chemical Engineering Transactions, 60, 55-60  DOI: 10.3303/CET1760010 

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2. Materials and Methods 

2.1 Materials 

Isotactic polypropylene (PP grade Moplen HF500N, homopolymer); density - 0,92g/cm3 at 250C, Mw = 250000, 
Mn = 67000, Melt Mass-Flow Rate- MFR = 11,5g /10 min (2300C, 2.16 kg), melting T = 1620C. Fe3O4 
nanopowder with size 7-15nm . 

2.2. Synthesis of magnetic polymeric nanocomposites. 

The polymer nanocomposite materials were prepared as follows: isotactic polypropylene was solved in toluene 
solvent, at a temperature 1200C. Magnetite nanoparticles were added to the polymer solution at different weight 
contents (1%, 5%, 7%, 10%) and stirred for two hours in order to prepare a homogeneous mixture. The mixture 
was transferred to a Petri dish and dried in a vacuum oven during the day. From these samples by hot-pressing 
at the melting temperature of polypropylene and a pressure of 10 MPa were obtained 100 micron thin film. 
Cooling the films after hot pressing was carried out in water at the cooling rate 20grad/min [Shirinova.H.A. 
2016]. 

2.3 Methods of analysis 

2.3.1. Scanning electron microscopy (SEM) 
Distribution of magnetite nanoparticles in polymer matrix was studied using scanning electron microscopy 
(SEM, JEOL JSM-7600 F). Scanning was carried out at an accelerating voltage of 15 kV and a working distance 
of 4.5 mm. In order to avoid the chargingof the surface of polymeric nanocomposite thin film, the sample was 
covered by 10 nm thick layer of platinum. 
2.3.2. TEM analysis 
Transmission electron microscopyanalyses of nanocomposites were taken on Transmission Electron 
Microscope of model JEM-1400 plus at the accelerating voltage 50 kV. Samples of nanocomposites were 
previously sonificated. For this study toluene was chosen as the solvent, because it was identified as one of the 
best solvents in this experiment. The sonification power was varied from 0 to 30% of the maximum power (130 
W) and sonication time was 15 min. 
2.3.3. Atomic force microscopy 
The morphology of the nanocomposites was studied by using atomic force microscopy NTegra Micro40 2011 
(NT-MDT, Zelenograd). For the scan, special silicon cantilevers fabricated by plasma etching method with a 
radius of curvature of the needle 20 nm and the resonance frequency of 1-5 Hz wereused. Scan size was 3 × 3 
microns. The measurements were performed in the semicontact microscopy mode in air, fixed needle change of 
the cantilever oscillation amplitude, which determines the surface topography. The scanning speed and the 
number of scanned lines of the image were 256 and 1,969 Hz, respectively. 
2.3.4.Thermogravimetric analysis (TGA). 
Thermogravimetric analysis of samples was conducted in a thermogravimetric analyze [Fayçal Dergal2013].  
(TGA) Model Seiko Exstar 6000 TG / DTA 6300. Nanocomposites samples were heated from 30 ° C to 650 ° C 
with a heating rate of 10

0C / min in a nitrogen atmosphere.  
2.3.5.Differential scanning calorimetry (DSC) 
Differential scanning calorimetric analysis of nanocomposites was performed on nanocomposites by usingDSC 
6100 (Seiko Instruments Japan) model Differential Scanning Calorimeter (DSC). Samples were placed into 
aluminium sample pans and experiments were carried out under nitrogen atmosphere with a purge rate of 20 
ml/min. Samples were heated from 20°C to 250°C then cooled to 25 °C. [Sébastien Leveneur 2014]. 

3. Results and discussion 
Figure 1 presents the TEM image of Fe3O4 nanoparticles in the polypropylene matrix obtained by introducing of 
Fe3O4 nanoparticles into the PP solution. Analysis of the micrographs revealed that, the spherical nanoparticles 
are distributed uniformly in the volume of the stabilizing matrix. As it can be seen from a comparison of the 
obtained data, the proposed techniques of the introduction of nanoparticles into a polymer matrix does not affect 
the shape of nanoparticles and the agglomeration of particles does not occur. However, on the TEM images of 
PP+Fe3O4 nanocomposite, there is some broadening of the size distribution, caused by small amounts of 
aggregated nanoparticles with diameter of 8 nm. Probably, this effect is due to the high temperature at the stage 
of introduction of Fe3O4 nanoparticles in a polymer matrix, which can lead to partial agglomeration of particles 
and a corresponding increase of their share in the size distribution. 
 

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Figure 1.TEM image of  PP+10%Fe3O4. 

Figure 2 shows SEM images of nanocomposites based on PP + Fe3O4 at 5% and 20% weight content of 
magnetite nanoparticles. As can be seen from the figure, with the increasing nanoparticle weight content up to 
20% in a polymer matrix the size of nanoparticles slightly increases. Thus, at 5% concentration of the 
nanoparticles size is 8-15, and at 20% - 16-30 nm  

 

Figure2. SEM images of nanocomposites on the base PP+ Fe3O4a) PP+5% Fe3O4;b) PP+20% Fe3O4 

Figure 3 shows AFM images of nanocomposites based on PP + Fe3O4 with different weight content of 
magnetite. As it can be seen from the image, with the addition of magnetite nanoparticles in a matrix, more 
ordered structure formed. So, at 5% weight content of Fe3O4nanoparticles in a polymer the distribution of 
magnetite is relatively ordered, more perfect structure is formed at 7%. From the AFM image, it is seen that the 
further increase of the magnetite content in the polymer matrix leads to nanoparticle agglomeration. This 
correlates well with the values of the average roughness of the surface of the nanocomposites [Saboktakin M.R. 
2009]. 

 

 

Figure 3.  АFМ images of  nanocomposites PP+Fe3O4 a) PP+5%Fe3O4, b) PP+7%Fe3O4, c) PP+10%Fe3O4 

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Figure 4. shows histograms of the surface roughness of the nanocomposites based on PP+Fe3O4. So, the root 
mean square roughness of the surface of the nanocomposite PP + 5% Fe3O4 is 40-50 nm; PP+7%Fe3O4 is 30-
40 nm; PP+10% Fe3O4 is 60-100 nm. From this it may be concluded that the 7%weight contents of Fe3O4 
nanoparticles in a polymer matrix lead to more perfect supramolecular structure of polypropylene.  

 

Figure 4. Histogram image of nanocomposites surface roughness a) PP+5%Fe3O4, 
b)PP+7%Fe3O4,c)PP+10%Fe3O4 

As it can be seen from the figure 5, the decomposition occurs at one-stage step. From the TGA curve, it is clear 
that the PP begins to decompose at temperatures 237,040 C with a continuous weight loss up to 475,640C.After 
the temperature 475,640С, the area on TGA curve corresponds to the constant weight. After the addition of 
5%weight content of magnetite nanoparticles, the starting temperature of thermo-oxidative degradation of 
nanocomposites shifted to higher temperatures, that is 306,470C with a continuous weight loss of up to 477,650 
C. 

 

Figure 5. TGA curves of pure polypropylene and nanocomposites on the base PP+ Fe3O41)PP; 2)PP+5%Fe3O4; 
3)PP+10%Fe3O4; 4)PP+20%Fe3O4 

Further increase of Fe3O4weight content in the polypropylene matrix leads to further shifts of the decomposition 
temperature to higher temperatures. So, at 20% weight content of Fe3O4the decomposition temperature for 
nanocomposite is 334,240 C with a continuous weight loss of up to 495,60 C. 
Consequently, it was found that the addition of magnetite nanoparticles in polypropylene matrix increases the 
thermal stability and heat resistance, and this observed up to 20% of weight content of Fe3O4. This fact is 
associated with the inorganic nature of magnetite with uniform distribution, which supplies the superior 
interference of heat sources, thus, improves the thermal stability [M.A. Ramazanov 2009]. Subsequently, the 
20% weight content of magnetite in the polymer increases the thermal stability of polypropylene by almost 100° 
C, which is very high for such an industrial polymer as PP. 
The results of TGA analysis of the samples of pure PP and PP + Fe3O4 are given in Table 1. 
 
 

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Table 1. Influence of magnetite nanoparticles weight content on the thermal stability of polypropylene  

Sample Initial decomposition 
 temperature(oС) 

Half decomposition 
 temperature (oС) 

Final decomposition 
temperature  (oС) 

PP 237,0 458,37 475,64 
PP +5%Fe3O4 306.4 455.74 477.65 
PP +10%Fe3O4 305.83 458.67 480.89 
PP +20%Fe3O4 334.24 488.44 495.6 

 
To study the thermal phase transitions of polymeric nanocomposites based on PP and Fe3O4, the differential 
scanning calorimetry (DSC)measurementswere carried, which allows to define the degree of crystallinity, glass 
transition temperature, melting and crystallinity temperatures. Figure 7 shows curves of the melting temperature 
of polymer PP+Fe3O4nanocomposites. Defining the heat of fusion, the degree of crystallinity of the polymer can 
be calculated which can be investigated by the following relationship: 
 (%) = HH ∙ 100% 

 
H – melting heat, determined by the area ofpeak responsible for the melting of the polymer, H0 - the heat 
released at the melting of 100% crystalline polymer, for polypropylene, it is H0 = 207 mJ/mg 
 

 

Figure 7. The melting temperature for the PP+Fe3O4nanocomposites, derived from DSC analysis 
1)PP+5%Fe3O4; 2)PP; 3)PP+7%Fe3O4; 4)PP+10%Fe3O4 

Table 2. data obtained by differential scanning calorimetry for pure PP and PP+Fe3O4 nanocomposites. 

Sample Melting 
temperature 
(°C) 

Crystallisation 
temperature 
(°C) 

Melting enthalpy 
(mJ/mg) 

Degree of 
crystallinity 
(%) 

PP 158 113,3 91,9 42,39 
PP +5%Fe3O4 161,5 114 88,3 44,65 
PP +7%Fe3O4 160,9 115 99 47,82 
PP +10%Fe3O4 160,9 117,3 96 46,37 

 
In accordance with the table that  the pure PP melts at 158°C and  with the formula (1), the calculated degree of 
crystallinity of the PP is 44.39%. As it can be seen from the figure 7, the addition of fillers does not lead to a 
significant change in the melting temperature. The degree of crystallinity is increased at 7% weight content of 
Fe3O4 and then slightly decreases [M.A.Ramazanov 2003].Further decrease of crystallinity degree is due to the  
destruction of the crystalline phase with increasing of filler concentration towards the polymer matrix. 

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4. Conclusion 

The thermal degradation behaviour of polypropylene and its magnetite  composites have been investigated by 
differential scanning calorimetry (DSC) and  thermogravimetric analysis (TGA). Distribution of magnetite 
nanoparticles in a polymer matrix has been studied by scanning and transmission electron microscopy and also 
atomic force microscopy. The thermal and mechanical properties of nanocomposites based on polypropylene 
and magnetite nanoparticles have also been investigated. It has shown that, the introduction of Fe3O4 
nanoparticles in polypropylene increases its thermal stability of about 1000C. The maximum increase in the 
thermal stability of PP was observed in the case of a 20% weight content of Fe3O4 nanoparticles in 
polypropylene. 

Acknowledgement 

The research presented in this paper was carried out with support grants eif-2011-1(3)-82/29-m-79. 

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