TEMPLATE FOR ACADEMICA SCIENCE JOURNAL


 

AL-QADISIYAH JOURNAL FOR    
ENGINEERING SCIENCES 

Vol. 10, No. 4  

ISSN: 1998-4456 

 

Page 505 Copyright  2017 Al-Qadisiyah Journal For Engineering Sciences. All rights reserved. 

 

STUDYING THE EFFECT OF CHEMICAL TREATMENT AND 
ORIENTATION ON FRACTURE TOUGHNESS OF KENAF FIBRE- 

EPOXY COMPOSITES 

 

Mushtaq Albdiry, 

Department of Materials Engineering, University of Al-Qadisiyah, Iraq. 

E-mail: mushtaqalbdiry@gmail.com; mushtaq.taleb@qu.edu.iq 

 

       Received on 23 July 2017        Accepted on 31 October 2017        Published on 15  February 2018 

DOI: 10.30772/qjes.v10i4.499   

Abstract: In this paper, the effect of surface modification and fibre arrangements of kenaf 

fibers on fracture toughness of epoxy composite was investigated. The chemical treatment of 

kenaf fibers (KFs) with 6 % NaOH was achieved, and composites with two different fibre 

arrangements (X and Y) directions were fabricated. Values of fracture toughness (KIc) 

measured of the compact tension (CT) specimens for both untreated kenaf fibre-reinforced 

epoxy (ut-KFRE) composites and treated kenaf fibre-reinforced epoxy (treated-KFRE) were 

much better than the neat epoxy. The KIc value of the treated-KFRE composite in Y-fibre 

direction was the highest of 2.74 MPa.m1/2 while it was 1.45 MPa.m1/2 for the neat epoxy. 

Different toughening mechanisms were noticed in the fracture surfaces of the composites in 

relation to the fibre reinforcement planar, they are shear yielding and fibre splaying with the 

X-direction and broken fibers, fibre pullout and fibre delamination with the Y-fibre orientation. 

Keywords: Kenaf fiber; fracture toughness; alkaline treatment; fiber orientation. 

 

 INTRODUCTION 

In recent years, the development of sustainable or biodegradable materials representing at using 

natural fibre reinforced polymer composites in commercial and medical applications has attracted a 

remarkable attention from both academic perspective and industrial viewpoint. This attention has emerged 

since these materials can be useable instead of non-renewable petroleum-based materials, particularly 

petroleum-based plastic due to their lighter weight, cheap and provide better stiffness to weight than glass. 

Additionally, by using natural fibres can preserve consumable resources such as petroleum, reducing landfill 

capacities, and alleviating a global warming impact due to diminishing carbon footprints that are generated 

by consumption of petroleum [1].  

mailto:mushtaqalbdiry@gmail.com
mailto:mushtaq.taleb@qu.edu.iq


 

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Kenaf fibres are among many different natural fibres with different chemical compositions of cellulose, 

lignin and hemicellulose (e.g., sisal, ramie, jute, flax, hemp, etc.), highly being used in reinforcing polymer 

matrix composites due to its high tensile strength and Young’s modulus of 930 MPa and 53 GPa, 

respectively. Kenaf as natural (plant) fibers is normally used in reinforcing polymer matrix composites. 

However, the main drawback of natural fibres is the complex structure of elementary fibres that contain 

cellulose, hemicellulose, pectin lignin and others; is its hydrophilic nature with strong hydrogen bonds and 

weak interfacial adhesion which complicates forming bonded interface with a relative non-polar hydrophobic 

matrix and resulting in poor strength properties of the produced composites [2, 3].  

In order to improve the bonded interface between hydroxyl groups in natural fibres with matrix resin, 

thus different chemical, physical and mechanical modifications or treatments of the natural fibers have been 

implemented. The chemical treatments (e.g., alkaline treatment, silane treatment, isocyanate treatment, and 

acetylation) consider the most viable treatments, in which, reagents solution are normally used which contain 

functional groups that are capable of bonding with the hydroxyl group from the natural fibres. Amongst them, 

the alkaline treatment based on sodium hydroxide (NaOH) (or mercerization) is the most widely used for 

natural fibers, especially for kenaf fibre when reinforcing thermoplastics and/or thermosets. Via applying the 

alkaline chemical treatments ensures removal of lignin, hemicelluloses, pectin, wax and oils, etc. covering 

the external surface of the natural fibers, breaks and disperses hydrogen bonds in the network structure and 

increases the number of free hydroxyl groups on the surface of the fibres and therefore fibre reactivity [4, 5]. 

Additionally, the chemical treatment of the natural fibres by alkali enhances the fibre’s surface roughness, 

which in turn causes surface fibrillization and drastically improves mechanical interlocking and fibre–matrix 

adhesion.  

Due to the growing demand of using natural fibres-polymer composites in structural applications, there 

is a need to thoroughly understand the fracture toughness and behaviour of these composites especially 

determining maximum loads applied to the component that can be carried before creating defects, initiating 

microcracking and causing local stress concentrations that result in catastrophic failure. Thus, numerous 

studies have been identified the fracture behaviour for different natural fibres-reinforced polymer composites, 

and others reported the importance of chemical treatments especially alkaline treatment with sodium 

hydroxide (NaOH) on mechanical and thermal properties of natural fibres/polymer composites [3, 6-8]. 

However, few works in the literature have conducted the influence of chemically treated natural fibres on the 

fracture behaviour and toughness of composites [7, 9-12].  

Nosbi et al. [13] discussed the degradation of compressive properties of pultruded kenaf fibre 

reinforced unsaturated polyester composites. It was found that the strength and modulus of the composite 

are reduced and the compressive strain at failure recorded an increase due to the formation of hydrogen 

bonding between polymer molecules and cellulose fibers.  



 

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          The effect of reinforced fibre arrangements on the mechanism of toughening and fracture toughness of 

glass fibre-reinforced composites and natural hemp fibre-reinforced PLA was presented by [14, 15], 

respectively. They found that the fracture energy and toughness increases with increasing ply angle up to 40
°
 

and then it decreases. Nevertheless, there is no particular study has investigated the alkaline treatment of 

kenaf and its arrangement (orientation) on crack path and fracture characteristics of composites. Hence, this 

study aims to comprehensively understand the role of treated kenaf fibres with NaOH in improving fracture 

toughness of the composites. And understanding the effect of fibre orientations (arrangements) on the 

fracture resistance of the composites since the properties of the fibrous composite materials are strongly 

affected by the fibre properties and its microstructural parameters such as fibre length and diameter, fibre 

distribution, fibre orientation, volume fraction of the fibers and packing arrangement of the fibers.  

 

1. EXPERIMENTAL 

1.1. MATERIAL AND ALKALI TREATMENT 

         Epoxy (DER331) and hardener (JOINTMINE 905-3S) with ratio of 2:1 were used as a polymer resin for 

kenaf fibre composites. After cleaning and extracting the kenaf fibres, portion of the prepared fibres were 

treated with 6 % sodium hydroxide (NaOH) solution for 24 h at room temperature, then washed by 

demineralised water and dried under sun light. The SEM micrographs for both untreated fibres and treated 

with NaOH are shown in Figure 1 a & b. Some specifications of the neat epoxy (NE) and untreated kenaf 

fibre reinforced epoxy (ut-KFRE) are listed in Table 1. 

1.2. COMPOSITES FABRICATION 

         A conventional hand lay-up technique with aluminium mould of 110 mm x 110 mm x 16 mm was 

utilised to fabricate epoxy-kenaf composite. The mould was waxed with release agent before pouring epoxy 

into it to prevent cured composite from adhesion with the mould. Unidirectional kenaf fibres were then placed 

on top of the resin and a steel roller covered with saturated resin was used to remove air bubbles and 

maintain a fully impregnated between fibre and polymer resin. The procedure was repeated until the required 

weight fraction of kenaf fibre (30 % wt.) is consumed. The composite samples of compact tension (CT) 

geometry as well as a schematic graph showing different fibre orientations-reinforced composites i.e. X-

direction and Y-direction are illustrated in Figure 2 and Figure 3 a & b, respectively.  



 

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Figure 1: SEM micrographs showing untreated kenaf fibre with impurities (a), and treated kenaf fibre with 
exposed cellulose (b).  

 

Table 1: Specifications of neat epoxy (NE) and untreated Kenaf fibre reinforced epoxy composite (ut-KFRE).  
 

Property
* 

NE KFRE 

Fiber volume fraction 0 % 30 % 

Density g/cm³ 1.1 0.975 

Modulus of elasticity GPa 3.2 ± 0.3 13.5 ± 2 

Tensile strength MPa 75 ± 5 133 ± 2 

Elongation % 3.5 ± 0.2 5.3 ± 2 

*all given properties are experimentally measured in this study. 

 

 

 

 

 

 

 

 

 

Figure 2: the compact tension (CT) geometry used in this study. 

a) b) 

 

All dimensions are in mm 

40 2 20 

8 a=10 

W=42 

B=16 

Ø8 x 

2 

4 



 

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Figure 3: Schematic graph of X- direction fibre orientations in the composite (a), and Y-direction (b) 
according to ASTM 5045 standard. 

 

1.3. FRACTURE TOUGHNESS MEASUREMENT  

         The neat epoxy (NE), untreated and treated kenaf fibre reinforced epoxy (ut-KFRE) and (t-KFRE) with 

two different orientations were cut by a diamond saw from the cured composites to dimensions of compact 

tension (CT) geometry according to ASTM 5045 standard [16]. The holes were opened using a steel drill, the 

notch and pre-crack were cut precisely with a band saw and inserting a razor blade, respectively. Fracture 

toughness testing was carried out using a universal tensile machine model LR 50 K with a crosshead speed 

of 1.5 mm/min. Both the load and the displacement values for five specimens from each composite direction 

(X and Y) are tested at room temperature and the averaged is recorded. A critical stress intensity factor (KIc) 

is calculated from the following equations [16]: 

)(
2/1

W

a
f

BW

P
K

Q

Ic 







                  ………….. (1) 

For a CT specimen, the shape factor, )(
W

a
f  is given by  
















432

2/3

)(6.5)(72.14)(32.13)(64.4866.0

)1(

2

)(
W

a

W

a

W

a

W

a

W

a
W

a

W

a
f          ………….. (2) 

 
(a) X-direction 

P 

P 

P 

P 

X-axis 

Y-axis 

(b) Y-direction 



 

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 In order to satisfy the plain-strain conditions, the following size criteria are checked: 

2
)/(5.2)(,,

yIc
KaWaB                 (3) 

where PQ is the peak load, B the specimen thickness (16 mm),  the crack length (10 mm), W the specimen 

width (42 mm), and the yield stress of the material. 

 

1.4. THE FRACTURED SURFACE STUDY 

         In order to understand the mechanism of fracture and deformation behaviour, the fractured surface of 

the composite from Mode I fracture test was examined by using Scanning Electron Microscopy (SEM) model 

Quanta 400 F. The samples were firstly coated with a thin layer of gold to improve the conductivity of the 

material before doing the test. 

 

2. RESULTS AND DISCUSSION 

2.1 CHEMICAL TREATMENT  

         The SEM images for both untreated kenaf fibres (ut-KFs) and treated kenaf fibres (t-KFs) with 6 % 

alkali NaOH are shown in Figure 1 a & b. There is a noticeable difference between the surface 

morphologies for the ut-KFs and t-KFs in terms of smoothness and roughness. The characteristics of t-KFs 

surface considerably improved and became cleaner and smoother after the NaOH treatment compared to 

the ut-KFs. In addition, the fine fibres in the bundle are exposed after washing the outer layer of the fibres 

with NaOH while the impurities are clearly noticed in the surface morphology of ut-KFs. Hence, the 6 % 

NaOH treatment is adequate to eliminate the impurities from the natural kenaf surface determined in this 

study. The improved surface morphology would improve the level of interfacial adhesion between the fibre 

and the matrix under the applied load on the fabricated fiber-reinforced polymer composites.  

2.2 FRACTURE TOUGHNESS 

         The load-displacement curves for the compact tension (CT) specimens made from neat epoxy, 

untreated kenaf fibre reinforced epoxy (ut-KFRE) and treated kenaf fibre reinforced epoxy (treated-KFRE) 

composites with two different X and Y fibre directions are presented in Figure 4. All CT fracture composite 

specimens performed better and carried higher tension loads before fracturing than neat epoxy. The 

composites reinforced by kenaf fibres in Y-direction conducted higher loads than these for the reinforced 

composites by X-direction regardless the considerations of alkali treatment method. This is an obvious 

indication since the neat epoxy (thermoset resin) is brittle in nature and the reinforced fibres contributed in 

absorb more energy and carry further load before fracturing.  



 

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         The treated-KFRE in Y-direction CT specimens had the highest tension loads before fracturing where 

they reached 1777 N, giving the maximum fracture toughness (KIc) of 2.74 MPa.m
1/2

, which is almost double 

its value of 1.45 MPa.m
1/2  

for epoxy as shown in Figure 5.  

 

Figure 4: Load-displacement curves of the fractured CT specimens under tension. 

 

         In Figure 5, the average values of the fracture toughness (KIc) for neat epoxy and the composites are 

given. The KIc values of the neat epoxy considerably increased with the existence of the reinforced KFs 

whether they are ut-KFs or t-KFs. The influence of the kenaf surface treatment on improving the fracture 

toughness is clearly observed where it contributed in an increment of about 0.5 MPa.m
1/2

. In other words, 

considering of 6 % NaOH alkali treatment of KFs is working to improve KIc values for the ut-KFRE 

composites by 24 % of these untreated composites without taking the orientation of fibre reinforcement in 

consideration.    



 

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0 

0.5 

1 

1.5 

2 

2.5 

3 

3.5 

Neat epoxy         X-direction  Y-direction 

K
Ic

 (
M

P
a

.m
1
/2
) 

 

Ut-KFRE 

Treated-KFRE 

Neat epoxy 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure 5: Fracture toughness of epoxy and composites with two KFs- reinforcement directions. 

 

2.3. EFFECT OF FIBRE ORIENTATIONS 

         The KIc values for the treated-KFRE (Y-direction) composites are superior compared with the neat 

epoxy and epoxy reinforced by X-fibre direction. This is due to the improved interfacial adhesion between the 

treated-KFs and epoxy which enhanced the stress-transfer from the resinous region to the fibers and 

consequently enhanced the KIc of the treated-KFRE composites [17]. The improved treated-KFs and epoxy 

adhesion may also contribute to detain the growth of the delamination, which potentially occurs under the 

tensile loading.  

         The fracture surface morphology of the neat epoxy is shown in Figure 6. It is brittle fracture showing 

crazing region. However, with the improved interfacial bonding between the treated-KFs and epoxy, more 

energy is consumed by fibre before pull-out or broken (fracturing). Using the Y-fibre to reinforce the 

composites in this study is further improving its toughness where the applied stress is discreet by continuous 

treated-KFs that can subsequently affect the toughening mechanism of the treated-KFRE composites. A 

similar conclusion was revealed by Fiore et al. [18], it was revealed that the use of unidirectional (UD) kenaf 

fibres or randomly oriented treated-KFs increased the tensile strength and tensile modulus due to the 

improved compatibility between fibre and epoxy. 

 



 

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Crack propagation 
Crack tip 

            300 μm 
 

Figure 6: Fracture surface of the neat epoxy. 

 

         The fibre arrangement in anisotropic materials such as polymer-based fibre composites is playing a 

notable role in changing their toughening mechanisms and mechanical properties since their properties are, 

in general, varying through each axis and depending on the fibre direction in which they are aligned. For 

instance, in term of un-treated fibres aligned in X-fibre direction, it was observed that the dominant 

toughening method is shear yielding of the resinous region and the progressive fibre splaying (see Figure 7). 

The role of chemical modification on the fibre surface aligned in the same fibre direction emerged a little 

amount of treated KFs pull-out along with broken fibre due to the good interfaces between the fibre and 

matrix, as shown in Figure 8.  

         On the other hand, the KFRE composites reinforced by un-treated KFs oriented in 90° (Y-direction) 

exhibited besides the fibre pull-out toughening mechanism other two mechanisms are fibre splitting and fibre 

delamination as shown in Fig. 9. The reason of the appearance of such mechanisms and thereof the high 

fracture toughness of the composites reinforced in Y-fibre direction could be attributed to the large crack-

bridging zones formed by intact kenaf fibres in the crack wake. The fracture surface of the treated-KFRE 

composites reinforced in Y-direction exhibited a broken fibre as shown in Figure 9 and Figure 10.  

 

 

 

 

 

 



 

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Broken fibre 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

CONCLUSIONS 

In this study, composite materials from treated kenaf fibers (KFs) with 6 % NaOH chemical treatment 

and epoxy were fabricated. Two different X & Y reinforcement fibre directions were applied. The fracture 

toughness (KIc) values of all composites are highly affected by the surface modification of KFs and 

dependent on the fibre orientations. The composites reinforced by treated KFs in Y-direction had the 

Figure 7: Fracture surface of ut-KFRE 
composites in X-fibre direction. 

Figure 8: Fracture surface of treated-KFRE 
composite in X-fibre direction. 

 

Figure 9: Fracture surface of ut-KFRE 
composites in Y-direction. 

 

Figure 10: Fracture surface of treated-KFRE 
composites in Y-direction. 

 



 

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maximum KIc of 2.74 MPa.m
1/2

 at 89 % improvement compared to the neat epoxy. Several toughening 

mechanisms were observed changing with the conditions of composite materials i.e., shear yielding and little 

pullout for the composited reinforced by X-direction and broken fibre and fibre delaminated as well as 

fibrillation for the composites reinforced by KFs in Y-direction. 

 

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