The exploitation of conventional, continuous fibre-reinforced plastics
in engineering structures has been steadily diversifying from sports equipment
and high performance racing cars, to helicopters and most recently commercial
aeroplanes. The main benefits of composite materials, such as their excellent
specific strength and stiffness properties, must be viewed with respect to
in-plane fibre-direction applications. However, if a composite plate is
subjected to significant out-of-plane stresses subsurface delaminations may develop between layers due to the
weak through-thickness cohesive strength of the composite (2). Previously,
techniques such as Z – pinning, stitching and 3D – braiding have been
investigated to improve through-thickness properties but these tend to reduce
the in-plane performance of the laminate by damaging primary fibres and
inducing fibre waviness (1).
Carbon Nanotube interfacial strengthening
Throughout the last decade the huge interest in Carbon Nanotubes (CNT)
has been fuel by their extraordinary intrinsic mechanical, electrical and
thermal properties, which make them ideal candidates for multifunctional
structures (3). To overcome the weakness of interlaminarstrength
considerable research has been conducted to develop hierarchical composite
structures by using nanoscale CNT reinforcement alongside microscale carbon and
glass fibers. Examples in nature such as cell
walls and animal shells show that excellent mechanical properties can be
obtained from spreading reinforcement over a number of length scales, even if
the original constituents are fairly weak (4). This paper reviews the progress
in developing such hierarchical composites to improve delamination resistance
and through-thickness properties by intra- and interlaminar reinforcement
of multiwall carbon nanotubes (MWCNT).
In an attempt to improve the through-thickness properties the
introduction of CNTs should,
● Ideally be attached radial to the primary fibres and extend into the
surrounding matrix to stiffen the fibre/matrix interface, improve the primary
fibre surface area and facilitate mechanical interlocking, all of which
improves stress transfer.
● Result in a uniform distribution of CNTs.
● Not reduce the in-plane laminate properties.
● Not introduce other secondary or additional modes of failure by damaging
the primary fibres.
● Allow a scalable, straightforward processing technique that can be
easily incorporated with conventional manufacturing processes such as VARTM or
pre-preg.
In the literature there are currently two popular methods to achieve
this,
1. Dispersing CNTs in a polymer matrix followed by infusion of pre-forms
with the CNT-reinforced resin,
2. A direct attachment of CNTs onto the external surface of the primary
fibres subsequently infused with a pristine resin.
In the following sections the details of the two manufacturing
approaches (shown schematically in Figure 1) are outlined and the implications
of each approach on through-thickness performance such as interlaminar shear strength, and Mode I and Mode II
critical fracture energy discussed.
Fig. 1.
Schematic diagram of conventional CFRP and hierarchical CFRP with CNTs in
matrix and grown on fibres (4).
CNT-reinforced Matrix
The simplest method to manufacture hierarchical nanocomposites is by
mechanically or ultrasonically shear-mixing CNTs into low-viscosity
thermosetting resins, and then infusing or impregnating the primary fibre stack
using conventional techniques such as VARTM (5; 6; 7). To date the most uniform
dispersion of MWCNTs throughout the matrix have been achieved by shear mixing
using a three-roll mill (8; 9). On the other hand this approach is limited to
short CNTs < 1 mm at low volume fractions of 1 – 2%, which greatly limits
the reinforcement potential. Higher volume fractions are to date not possible
since the viscosity of the matrix increases rapidly with CNT content leading to
incomplete infusion (10) or CNT agglomeration/depletion in different areas of
the fabric (11).
Flexural tests of hierarchical composites with glass and carbon primary
fibres show that the in-plane stiffness and strength are not impaired by the
MWCNTs (5; 8). Qiu et al. (5) actually
showed an improvement in tensile strength and stiffness of a glass-fibre
composite of 15.9% and 27.2% respectively, while Veedu et
al. (12) showed improvements of 142% and 5% for carbon composites. Most
importantly, as tabulated in Table 1 short beam shear (SBS) and compression
shear tests (CST) have shown increases in the matrix-dominated interlaminar shear strength (ILSS) between 8% and 33%.
Scanning electron microscopy (SEM) images show that the MWCNTs in the resin
lead to better fibre-to-matrix adhesion as well as pullout and
rupture of the MWCNTs before final matrix failure, which consumes additional
fracture energy (Figure 2).
Fig. 2.
SEM images showing much more matrix stuck to the fracture surface of CNT
reinforced matrix suggesting better matrix/fibre adhesion (7)
The SEM images also indicate that the alignment of the CNTs is heavily
influenced by the direction of the resin flow during infusion and local
orientation of the primary fibres (4). As resin infusion generally occurs in
the through-thickness direction the VARTM approach can give some control in
aligning the CNTs in the preferred direction for improving transverse properties,
although a certain degree of random alignment remains. Furthermore, one study
has shown (5) that functionalised MWCNTs resulted in slightly higher SBS shear
modulus and strength (~3%) compared to a pristine un-functionalised MWCNTs.
Using SEM imagery the authors showed that this stemmed from a superior
interfacial bonding between the CNTs and the matrix.
Delamination resistance is generally investigated using Mode – I double
cantilever beam (DCB) tests and Mode – II end-notched flexure (ENF) tests.
Table 1 summarises the significant improvements of up to 98% and 75% for Mode I
and Mode II fracture toughness respectively compared to non-hierarchical
composites. The characterisation of the fracture surfaces using SEM imagery has
shown that the additional pullout and
bridging of the CNT is responsible for the toughening. Similarly, Garcia et al.
(13) have developed an efficient technique of growing CNT mats on growth
substrates and then “transfer printing” the CNT mats in between tacky pre-preg plies using a roller. Since this process better
controls the CNT alignment in the through-thickness direction much higher
improvements of fracture toughness of 152% in Mode I and 214% in Mode II were
observed. However, the process of “transfer printing” CNT films at every ply
interface is a very time consuming endeavour and may therefore not be as
applicable to scalable industrial integration as the VARTM process.
Table 1. Improvements in ILSS and
delamination resistance of CNT-reinforced composites.
Fibre |
Matrix |
Nanofiller |
Nano- Reinforced Region |
Test Method |
Improve-ment |
Ref. And Year |
woven glass |
VARTM epoxy |
1 wt% of pristine and
functionalised MWCNT |
entire matrix |
SBS (ILSS) |
7.9% |
(5), 2007 |
woven glass |
epoxy |
0.5-2 wt% MWCNTs |
entire matrix |
Compression Shear Test (ILSS) |
9.7% (0.5%) 20.5 (1%) 33% (2%) |
(14), 2008 |
carbon |
epoxy |
5 wt% cup stacked CNTs |
entire matrix |
DCB (Mode I) – ENF (Mode II) |
98% – 30% |
(15), 2007 |
carbon |
epoxy |
1 wt% MWCNTs |
entire matrix |
DCB (Mode I) – ENF (Mode II) |
60% – 75% |
(16), 2009 |
UD carbon |
pre-pregepoxy |
~1% CNT forests |
layer between pre-pregplies |
DCB (Mode I) – ENF (Mode II) |
152% – 214% |
(13), 2008 |
The fabrication of hierarchical composites by impregnating microscale
primary fibres with nanoscale-modified resins is limited to maintaining low
matrix viscosities. Furthermore, resin flow during impregnation tends to align
CNTs parallel to the primary fibre direction, the least desirable orientation
for improving through-thickness properties. In this respect growing or
“grafting” CNTs directly onto the surfaces of primary fibres followed by
infusion with a pristine, low-viscosity matrix allows higher volume fractions
and is ideal for orientating fibres radial to the primary fibres. Furthermore,
this approach overcomes the problems of CNT agglomeration or self-assembly into
bundles as observed when CNT are freely dispersed in a matrix. Three techniques
for attaching CNTs onto fibres were found to be most popular in the
literature: CNT-modified Fibres
1. Direct
growth of CNTs onto fibres via Chemical or Thermal Vapour Deposition (CVD and
TVD) (12)
2. Electrophoretic
deposition (EPD) (6)
3. Coating
of primary fibres with CNT-modified sizing agents (7)
The first example of synthesising CNTs onto carbon fibres via CVD was
conducted in 1991 by Downs and Baker (18). In this approach the primary glass
or carbon fibres are initially oxidised with nitric acid and the iron catalysts
then deposited onto the fibres using incipient wetness techniques such as
sputtering, thermal evaporation or electrodeposition (4). The ultimate result
is the growth of highly aligned and dense CNT forests onto fibre cloths (Figure
3) that are then stacked and impregnated by infusion techniques such as VARTM
(12). Experiments have shown that the CNT forests are efficiently wet-out by
liquid resins and polymer melts as a result of capillary forces (6; 19).
Fig. 3. SEM images showing CNT forests (b) grown in woven
pristine fibre cloth (a) (12)
Recently, Injection CVD (ICVD) techniques have been favoured to then
grow the CNTs on the primary fibres via a pyrolysis of solutions containing a
catalyst precursor and a hydrocarbon source (20). The ICVD technique has
resulted in better degree of orientation and growth of longer CNTs compared to
classical CVD approach.
The most crucial parameters in grafting CNTs onto glass or carbon fibres
are,
● Choosing a good catalyst for strong anchoring interaction between CNTs
and fibres to maximise stress transfer and reduce damage during manufacturing
processes, While
● At the same time prevent oxidation damage to the primary fibres by to
aggressive a catalyst.
Fig. 4. Electrophoresis (6)
Oxidation and gasification are especially problematic for carbon fibres
since the active catalysts deposited onto the fibres etch into the surface and
thus may reduce their strength by up to 55% (4). As a solution Bekyarova et al. (6) selectively deposited multi- and
single-walled CNTs onto woven carbon fabric using electrophoresis. In this
approach MWCNTs are first produced as is using a classical CVD process and then
dispersed in an aqueous media between two negative electrodes to charge the
CNTs (Figure 4). The dry carbon fabric was then immersed in the CNT doped media
and sandwiched between two steel plates connected to a positive charge. Driven
by the electric potential, the CNTs are thus deposited onto the carbon cloth
and the CNT-carbon fibre performs then infused with epoxy using VARTM. A very
simple approach has been presented by Zhu et al. (7) who sprayed nanotubes
directly onto woven fibers prior to VARTM
processing. The drawback of this technique compared with direct growth methods
is relatively little control over the CNT orientation (4).
The pioneering work of Downs and Baker (21) reported a 4.75x increase in
interfacial shear strength (IFSS) of a nanofibre-grafted
carbon composite, although such incredible improvements have not been repeated
thus far. Table 2 summarises interlaminar and
delamination resistance enhancements taken from different sources in the
literature and based on multiple primary fibre, CNT and matrix combinations. Veedu et al. (12) showed improvements of 348% and 54%
for GIC and GIICrespectively for MWCNT enhanced SiC woven fabrics using a classical CVD
technique; Bekyarova et al. have found
improvements of 27% in ILSS for CNT enhanced carbon fabrics using
electrophoresis deposition; while Zhu et al. demonstrated improvements of 45%
in ILSS of MWNT doped glass fiber reinforced
vinyl ester composites using a simple spray up with only 0.015 wt% of CNTs. In all three studies SEM imagery showed that
the improvements arise from the increased surface area of the primary fibres
and excellent wettability, which facilitates a strong bond between fibres and
matrix by mechanical interlocking.
Based on these results the general consensus is that the damage
tolerance of a structure can readily be improved by CNT grafting (4). However,
there is also a large variability in the results arising from the different
manufacturing processes, material combinations and CNT loadings applied that
conceal the exact effectiveness of the method. There is agreement that the
degree of enhancement is greatly dependent on the orientation and length of the
grafted CNTs and further experimental research is required to ascertain the
optimal morphology and manufacturing technique to achieve this (4).
Table 2. Improvements in interlaminar strength and delamination resistance
for nano-grafted composites.
Fibre |
Matrix |
Nanofiller |
Manufacturing Technique |
Test Method |
ILSSImprov. |
Ref. And Year |
woven glass |
vinyl ester |
0.015% SWCNTs and MWCNTs |
Spray-up between plies |
SBS |
20-45% |
(7), 2007 |
carbon |
epoxy |
0.25 wt% MWCNTS |
Electro-phoresis |
SBS |
27% |
(6), 2006 |
SiC |
epoxy |
2 wt% MWCNTs |
CVD |
DCB (Mode I) – ENF (Mode II) |
348% – 54% |
(12), 2006 |
Perspectives
The research so far has focused on demonstrating the great potential of
CNTs to improve the through-thickness of properties of conventional FRPs. In
the future research should focus on,
● Developing scalable manufacturing processes that may find application in
real, large-scale industrial applications.
● Finding new approaches that solve agglomeration and high viscosity
issues to allow higher loadings of CNTs.
● Functionalization of CNTs to improve CNT dispersion and stress transfer
with the host matrix.
● Reducing or preventing the reduction in strength of primary fibres
induced by grafting fibres onto external surface.
● Ascertaining the optimal CNT orientation and aspect ratio to optimise
the through-thickness performance.