Thermoplastic-Toughened High-Temperature Cyanate Esters and

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Thermoplastic toughened high temperature Cyanate esters and its application in advanced composites Ahmed Inamdar, Jayalakshmi Cherukattu, Anoop Anand, and Balasubramanian Kandasubramanian Ind. Eng. Chem. Res., Just Accepted Manuscript • DOI: 10.1021/acs.iecr.7b05202 • Publication Date (Web): 07 Mar 2018 Downloaded from http://pubs.acs.org on March 7, 2018

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Thermoplastic toughened high temperature Cyanate esters and its application in advanced composites Ahmed Inamdar1, Jayalakshmi Kandasubramanian1*

Cherukattu2,

Anoop

Anand2,

Balasubramanian

1

Department of Materials Engineering, Defence Institute of Advance Technology (DU), Ministry of Defence, Girinagar, Pune-411025, India

2

Composites Research Centre, Research and Development Establishment (Engineers), DRDO, Ministry of Defence, Pune-411015, India *Corresponding author E-mail: [email protected]

Abstract Cyanate esters (CE) are recognised as matrix materials in composites for high temperature structural applications, owing to their excellent thermal and dimensional stability, resistance to micro-cracks, low moisture absorption and dielectric loss. Though, the brittle nature of CE curtails its effective utilization, thermoplastic toughening has pave the way to circumvent its innate brittle attribute by the virtue of resulting two phase morphology. This review article enumerates detailed deliberation on thermoplastic toughening of CE and its semiinterpenetrating networks. Further, the effect of various decisive variable like thermoplastic concentration, molecular weight, and curing conditions has been also reviewed and disserted in detail. In addition, the mechanical properties of numerous developed CE blends and its toughening mechanism has been deliberated to elucidate its substantial engineering applications. This review article can render detailed contemplation on thermoplastic toughening of CE, composite fabrication methodology and their structural integrity for high temperature applications. Keywords: Cyanate esters; Thermoplastic toughening mechanism; Semi-IPN; Phase separation mechanism; Morphology; High temperature structural composites 1 ACS Paragon Plus Environment

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Introduction Reduction in weight of component, especially in space application is coupled with improvement in performance of the system along with fuel economy and increase in payload capacity. The development of composite materials has provided designer the flexibility to tailor properties such as strength, modulus, fracture toughness, thermal stability, etc. Recent upcoming trend in composite industry is to develop composites for high temperature structural applications, such as parts around aero-engine, leading edges, rotor blades, etc. In the past, epoxy based composites with high strength fibres like carbon/ glass have been major class of material catering the need of such speciality applications1-2. However, current epoxy based system has a drawback of excessive water absorption and residual stresses, leading to micro-cracks when thermally cycled3. Also, the maximum service temperature of these epoxy systems for structural application is approximately 177°C, while further introduction of wet environments restricts this to 149°C4. Hence, researchers are searching for matrix materials exhibiting high service temperature along with improved toughness and less water uptake properties. Cyanate esters, Bismaleimides, Polyimides etc. are the few choices of materials and have been continuously evaluated for their capability to match these speciality application requirements4-12. Cyanate esters are becoming a popular choice in high temperature speciality applications because of their excellent mechanical and physical properties like high glass transition temperature, excellent thermal stability, low dielectric loss property, low moisture uptake and low flammability4. Compared with Epoxies and Bismaileimide (BMIs), Cyanate esters are inherently more hydrophobic and cured neat resin absorb only 0.5-2.5 wt.% of water4,13. Cost of Cyanate esters is also comparable with high performance epoxies and is less than BMIs. Along with high temperature structural space applications, Cyanate esters have

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tremendous potential in electronic industries for making printed circuit boards and building of radome structures, etc.4,14-16. Monomers of Cyanate esters polymerize by a cyciotrimerization reaction to yield a cyanurate linked polymer network also referred as a triazine ring. Cyanate esters are available in a large variety of forms including liquid, solid, semisolid and solution along with excellent shelf life at room temperature4. High crosslink density associated with Cyanate ester contributes to achieve high glass transition temperature but on the flip side exhibits the low fracture toughness. Therefore, enhancing the toughness of Cyanate esters resin is a major concern in order to use it as matrix in high performance applications. Various approaches have been studied to enhance toughness of Cyanate esters including blending with Epoxies, BMIs, reactive rubbers and engineering thermoplastics17-27. However, thermoplastics toughening is attractive and effective toughening mechanism as resulting blend system retains important inherent properties of Cyanate esters. Engineering thermoplastics like Polyetherimides, Polysulfones, Polyimide, Polyethersulfones, Polyacrylate, etc. are miscible in Cyanate monomers forming homogeneous blends27-32. Handling and processing of these blends are far more similar to epoxies, hence well-developed processing technique for epoxies can easily be imported. Curing of these blends lead to phase separation forming semi-IPNs and their properties greatly depending upon the morphology obtained28-30. Various morphologies are observed, including phase inverted and co-continuous morphology. Hence, understanding the effects of morphology controlling variables like molecular weight, curing conditions and blend composition became crucial in order to tailor final properties of blends. Cyanate esters are extensively modified and evaluated to enhance its toughening characteristics using various approaches such as, incorporation of fillers, blending with elastomers or thermoplastics or high temperature thermosets etc.

Despite of having

advantages with thermoplastic toughening in high temperature thermosets, it has not been 3 ACS Paragon Plus Environment

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extensively reported and reviewed. Hence, in this review article, a comprehensive study on thermoplastic toughening of Cyanate esters and tailoring of final properties of the blend through control of morphology are presented. In this abstraction, various toughening mechanism involved in modification of high temperature thermosets, their processing routes and control of variables involve in the processing are reviewed in detail. Further, we have delineated various thermoplastics for their toughening potential in Cyanate esters in addition to the number of different morphology dominating variables and mechanical properties of blends. Subsequently, we have demonstrated the utilization of these toughened blends in development of high temperature composites for engineering applications like radome, tail assembly, leading edge, rotor blades etc. Though, it is ambitious to cover the entire published work on this topic, we have made an attempt to compile most of literature which rendered the potential impact in this field.

2. Concept of Polymer Blends and Inter-Penetrating Networks Polymer blends are defined as a, “mixture of at least two polymers or copolymers with their concentration above 2 wt.%33, and resultant new class of material has improved properties, comprising the advantage of each polymer constituent. Blending is an easy and economical method for developing new polymeric material, allowing tailoring of properties in accordance with end use by appropriate selection of the polymer combinations. Polymer blends are broadly classified into two major types: Miscible blends and Immiscible blends. Miscible blends are homogeneous single phase system, which can undergo phase separation while curing generating different morphologies. Since, the properties of a cured polymer blends depend on the final morphology obtained, various researchers have undertaken extensive studies on the miscibility and phase separation behaviour of polymer blends4,34-36.

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2.1 Concept of Miscible and Immiscible Blends Thermodynamically, blends are classified into miscible, partially miscible or immiscible based on the value of Gibbs free energy ∆  of mixture33,37, given by following equation, ∆ = ∆  − T∆ 

…..………. (1)

In-order to get the miscible solution (Binary blend), following two condition needs to be satisfied: First condition, ∆ < 0

…..………. (2)

And second condition,  ∆ 



∅



,

> 0



.………….. (3)

Where ∆  is the Gibbs energy of mixing, ∅ is the composition, where ∅ is usually taken as the volume fraction of one of the components. Here, ∆  is the entropy of mixing and it is always positive and, therefore, is favourable for mixing. ∆  is the enthalpy change due to mixing, which can be either endothermic or exothermic. Exothermic reaction occurs during mixing, which drives the system towards miscibility and it is possible only if strong specific interactions like polymer hydrogen bonding, dipole–dipole, and ionic interactions are present in polymer components38. These specific interactions can be understood using a number of techniques such as Fourier transform infrared (FTIR) spectroscopy, small-angle neutron scattering (SANS), and nuclear magnetic resonance (NMR) spectroscopy etc. It is believed that, blend which shows single glass transition temperature are miscible blends. However, glass transition temperature is insensitive to thermodynamic miscibility and depends on the degree of dispersion. Hence, single glass transition temperature does not necessarily represent miscible blends, as 5 ACS Paragon Plus Environment

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immiscible blends with fine dispersion of phases have also shown single glass transition temperature33. Zhan. G. et al.39, reported that, blend of Cyanate esters/PEI shows single glass transition temperature at early stage of curing (up to 6 min for curing at 150°C) and then two glass transition temperature peaks for each component. This study concluded that, Cyanate/PEI blend was homogenous up to 6 min at 150°C curing and then phase separated. The most popular theory for defining thermodynamic miscibility of polymer blends was developed by Flory and Huggins in 194133. This theory defines miscibility and help to construct a phase diagram of blends. According to this theory, free energy of mixing is given by,





∆ =  ! " $ %&∅'  + !  $ %&∅) * + +∅' ∅) …………….(4) # # "

Where, ,') =

." #"

,



+ = ,')  !/ $ and  =Molar volume, ∅ =Volume fraction, '

,') =Binary interaction parameter. Flory-Huggins defined the critical binary interaction parameter ,') 010  and for blends with binary interaction parameter above critical point result in phase separation. Zhan. G. et al. 31,39

, applied Flory-Huggins equation to draw a phase diagram for Cyanate/PEI and concluded

that, 15 part per hundred concentration was a critical point corresponding to lowest curing conversion of Cyanate esters. Further, Zhan reported that, the phase separation mechanism at a concentration of thermoplastic lower than the critical point in conversion versus composition, transformation diagram result in nucleation and growth mechanism while, for higher concentration above the critical point leads to phase separation by spinodal decomposition39. Borrojio. et. al40 and Pascault. et. al25, investigated rubber toughened Cyanate ester blend using Flory-Huggins equation and concluded that, phase separation occurs due to change in free energy dominated by change in entropy during polymerization. 6 ACS Paragon Plus Environment

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Also, Solubility parameter approach is used to define soluble blend combinations. The solubility parameter of Cyanate esters is δ=25.23 (J/mL)1/2, and a polymer having solubility parameter value adjacent to the Cyanate esters solubility parameter are defined as a miscible polymer in Cyanate esters33,41.

2.2 Interpenetrating Networks Interpenetrating networks (IPNs) form an another class of polymeric component system, having two cross linked polymer networks without any covalent bonding in between them. Figure 1, shows the schematic representation of full-IPN in which two cross-linked networks A and B combine to form interlinked full-IPN network. Another binary network with only one polymer cross-linked are also termed as IPNs but more precisely, semi-IPNs. As shown in figure 2, linear chain B combines with network A to lead semi-IPN network in which only one polymer is in network form.

Figure 1. Schematic of full Inter-Penetrating Networks

IPNs can be prepared by mixing two monomers and then crosslinking them to form network or by dissolving the second polymer in the network of the first polymer followed by curing the second polymer to form a network. Another route leading to IPN is the blending of two polymers which are thermodynamically miscible and then crosslinking them to form network. 7 ACS Paragon Plus Environment

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IPNs may undergo phase separation following kinematic likes nucleation and growth (NG), spinodal decomposition (SD) and follows four distinct stages to yield final morphology42.

Figure 2. Schematic of Semi-Interpenetrating Networks

During first stage, both polymers remains soluble and forms clear transparent solution, then as polymerization proceeds to stage two, soon it clouds up and phase separation occurs following nucleation and growth mechanism. In stage three, interconnected cylinder develops following spinodal decomposition mechanism. Further, as a polymerization proceeds to the stage four, it results in growth of domains34,43. This dual phase continuity causes for an increase in the area under the loss modulus vs temperature curve near the glass transition temperature44. Morphology with smaller domain sizes shows one broad glass transition peak while larger domain size, two distinct glass transition are observed28,45. IPNs are considerably more important, as they combine two non-compatible polymers in network form, like brittle high temperature thermosets and tough thermoplastics. The resulting material combines the inherent advantages of individuals, such as toughness and the processing ease of thermoplastics and high service temperature of thermosets.

3. Morphology and Phase Separation

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Phase separation occurring in soluble blends of amorphous thermoplastic/thermosets, is an effective means for toughening thermoset without degrading its inherent properties33. Cocontinuous and phase inverted morphologies are known to increase mechanical properties for this type of systems. Figure 3, shows the morphology change as a function of concentration of added component. Component A which is represented in black color is added in component B, shown in white color. At lower concentration of component A, spherical particles of component A are dispersed in a matrix of component B and resulting morphology is termed as a particulate morphology, as shown in figure 3-a.

(a)

(b)

(c)

Figure 3. Schematic of phase separation and morphology changes with an increase in thermoplastic concentration (a) Particulate (b) Co-continuous (c) Phase-inverted

As particles tend to achieve the spherical shape to minimize surface energy, other shapes can also be possible, such as ellipsoids, platelets, etc. This phase separation occurs as shifting from single phase region to metastable region in a phase diagram. In metastable region of the phase diagram, phase separation occurs due to the nucleation and growth (NG) involving slow nucleation of component A followed by growth33.

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Increase in concentration of component A, leads to transition from the single phase region into spinodal region. Here, phase separation occurs by spinodal decomposition (SD) mechanism and leads to co-continuous/ phase inverted morphology. Figure 3-b, shows the co-continuous morphology in which both phases are continuous. This morphology is also termed as “sea-island” type morphology. Further with increase in concentration of component A, phase inversion occurs in which component A become matrix and component B dispersed in particle forms, as shown in figure 3-c.

4. Elastomer vs Thermoplastic Toughening Cyanate esters pre-polymer has reactive (-O-C≡N) functional group which on curing undergoes cyclotrimerization and resultant three-dimensional cross-linked network is often called as a poly(cynurate)s as shown in figure 44,46. The curing reaction is an addition polymerization reaction which does not form any by-products. The Cyanate ester homopolymer based on bisphenols have a glass transition temperature in the range of 250290°C and for Cyanate esters based on novolacs, even high glass transition temperature in the range of 270-350°C or above is possible4. Cyanate esters possess excellent electric properties with low dielectric constant (Dk=2.66-3.08) which is unusual for equally high temperature resins. Even after blending Cyanate esters with Epoxies and BMIs have resulted in superior dielectric properties in the modified systems22,47. Cyanate esters are inherently tougher than epoxy and other high temperature resins and the fracture toughness of neat BADCy resin is 0.62MPam1/2 48. In order to enhance the toughness of Cyanate esters two main approaches are popular. A number of studies are available for toughening of high temperature epoxies with reactive elastomeric rubbers such as carboxyl terminated butadienen-acrynitrle copolymers (CTBN)49-54. This approach has also been extended in toughening of Cyanate esters without much success. Elastomer toughening causes significant improvement in the fracture

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toughness, however a major drawback of this approach is that, it causes degradation in high temperature property. Further, due to the addition of soft rubber in the stiff matrix reduces the overall yield strength and the modulus of system51.

Figure 4. Cyclotrimerization of Cyanate esters Shaw et al.55, blended CTBN to a bismaleimide polymer system and reported improvement in toughness property only after 100 phr concentration of modifier. Hence, for such a high rubber loading, it causes degradation in service temperature and modulus properties. Yang et al.56,57, investigated the toughening of cyanate ester resin using experimental core-shell rubber modifier and reported the significant enhancement in toughness of the matrix. Sachdeva et al.58, investigated rubber toughening of high temperature Polyimide, and reported a decrease in glass transition temperature of Polyimide from 300°C to 137°C. As unsaturation is present in elastomeric structure like Carboxyl terminated butadienenacrynitrile copolymers (CTBN) and amine functionalized butadiene-acrylonitrile copolymer rubbers (ATBN), it provides unwanted sites for the reaction at high temperature58.

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Toughening of high temperature polymer with particulate filler like glass, silica, aluminium hydroxide, Zirconia also have been reported with limited success59,60. On the other side, thermoplastics toughening of high temperature thermosets resulted in significant improvement in fracture toughness without reducing their high temperature properties61-68. As phase separation occurs while curing, individual component retains their glass transition temperature26,69. Marieta et al.70 showed that, Cyanate esters and PolyetherImide having Tg= 275°C and 220°C respectively, retain their transition temperatures after blending at various concentration such as 10, 15, 20 wt% PEI. Phase separated domain of blend resulted in two glass transition temperature values corresponding to individual constituent in blend. Also, slightly increase in glass transition temperature of PEI is reported for 15 and 20 wt% PEI blend. Thus, blending with thermoplastic having higher glass transition temperature results in overall high glass transition temperature of the blend system. Further, chemical resistance is also found to be improved for such systems. Hedrick et al.61,62, investigated hydroxy-functionalized poly (aryl ether sulfones), PSF blending with epoxy resin at different molecular weights and reported improvement in fracture toughness. They showed that, the addition of functionalised PSF results in two phase particulate morphology with particle size increasing with increase in molecular weight of the PSF. Hence, understanding the fundamentals associated with thermoplastic toughening and further its application in toughening of high temperature thermosetting cyanate esters became more important.

5. Thermoplastic/Cyanate esters Blending Techniques Two main blending techniques, namely the solution blending and solvent free temperature assisted solution mixing are adapted in thermoplastic toughening of Cyanate esters. However, each one of them is having certain merits and demerits over each other’s.

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5.1 Solution Blending

Figure 5. Schematic of solution blending process In solution blending technique31,39,43, initially thermoplastics are dissolved in a solvent such as dichloromethane (CH2Cl2) to form a liquid solution. Then, this liquid thermoplastic solution is mixed with Cyanate ester monomers/ pre-polymers at room temperature. This mixture is then continuously stirred and heating is employed if necessary. Then the residual solvent is removed by the use of vacuum along with heating to 90-120 °C and catalyst is added if required. Figure 5, shows the schematic representation of “solution blending” process. Solution blending is convenient and has been successfully implemented for blending of many thermoplastics including PolyetherImide71, PolyetherSulfone72. etc. Large quantity of thermoplastic loadings can easily be processed with solution blending73. However, removal of residual solvent imposes a great challenge and 100% solvent removal is difficult to achieve. Further, increase in viscosity of solution with addition of thermoplastics imposes the difficulty in solvent removal process. 5.2 Solvent Free Temperature Assisted Solution Mixing 13 ACS Paragon Plus Environment

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Figure 6. Schematic of solvent free temperature assisted solution mixing Amorphous thermoplastics like Polysulfone, Polyetherimide, Polyethersulfone, polyarcylate, Polycarbonate, etc. are miscible in Cyanate esters. Thus, this property of Cyanate esters can be utilized for obtaining blends of thermoplastic and Cyanate esters. In this process, pellets/ fine powder of thermoplastics is slowly added in liquid dicyanates such as AroCy L-10 with continuous stirring30, as shown in figure 6. Liquid Dicyanate are initially heated to a temperature of 100-130 °C26,30,74. If required, curing catalyst can be added during blending41. Complete mixing is ensured by observing transparency of the solution and degassing is done to remove bubbles form during mechanical mixing. This process is extensively reported as “Melt mixing”, which is technically referred to the process of melting the polymer and then mixing them to obtain homogeneous blends and it utilizes the specialised equipment’s like compounder, batch mixer or extruders. Hence, this process cannot be corroborated technically as melt mixing. Therefore, the above blending process can also be termed as “solvent free temperature assisted solution mixing” based on its characteristics. Thus, solvent free temperature assisted solution mixing is a most suitable blending technique for miscible thermoplastics up to approx. 20 wt.%73. This advantage of “temperature assisted solution mixing” makes the process more suitable for bulk production. 14 ACS Paragon Plus Environment

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6. Morphology and Mechanical Properties of Thermoplastic Toughened Cyanate esters Blends Final morphology obtained after curing of thermoplastic toughened Cyanate blends has great importance, as it controls physical as well as mechanical properties of the end application. Morphologies which are obtained mainly depends on thermoplastic composition, curing conditions and molecular weight, allowing to tailor properties. Thus, study of morphology and its variables becomes essential for thermoplastic toughness of high temperature thermosetting Cyanate esters resin. 6.1 PolyetherImide Blend Polyetherimide has excellent mechanical and electrical properties. It has high service temperatures (up to 170°C or 180°C), low shrinkage, high moisture resistant property, inherent flame retardancy and low smoke emission during fire. Also, low coefficient of thermal expansion and high dielectric resistivity are important properties of Polyetherimide. But, high cost and large density are the major drawbacks of this novel thermoplastic75. 6.1.1 Effect of Composition on Morphology Harismendy et al.43,45, Tao et al.71, and Wang et al.76 studied the effect of thermoplastic concentration on final morphology obtained. For composition of 5 wt.% PEI, morphology obtained is particulate. However, spherical particles of PEI are very fine and can only be identified in higher magnification. Similar particulate morphology was obtained with blend of 10 wt.% PEI in which spherical domains of size around 0.5 mm diameter are dispersed in the Cyanate-rich matrix, shown in figure 7-a. This, clearly shows that, degree of phase separation is higher for 10 wt.% as compare to 5 wt.% sample and nucleated spherical particle thus grows in size. In this morphology, two particles sizes are observed and in order to increase fracture toughness bimodal distribution is preferred over unimodal distribution. This phase 15 ACS Paragon Plus Environment

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separation was attributed to nucleation and growth mechanism in which PEI phase nucleates and grows in crosslinking cyanate matrix during curing of the blend45. Blend with 15 wt.% shows co-continuous morphology in which both PEI and Cyanate phases remain continuous. Also, small spherical particles of PEI and Cyanate are dispersed in Cyanate rich and PEI rich phases respectively shown in figure 7-b. This is attributed to secondary phase separation which occurred in already phase separated PEI and Cyanate rich domain. Adhesion of particles and matrix in PEI rich phase was poor, where Cyanate rich phase showed good adhesion between particles. This is mainly because of higher contraction of thermosetting rich phase compared to thermoplastics rich phase45. With further increasing composition up to 20 wt.%, leads to complete phase inversion as shown in figure 7-c, in which Cyanate appears as an independent spherical domain of around 2 mm diameter dispersed in PEI matrix. This co-continuous morphology shows broad particle size distribution. The phase separations for 15 and 20 wt.% PEI concentration leading to cocontinuous and phase-inverted morphology follows spinodal decomposition mechanism and 15 wt.% composition is close to a critical point in the experimentally studied phase diagram39.

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(a)

(b)

(c) Figure 7. (a) Particulate morphology (10 wt.% PEI) (b) Co-continuous morphology (15 wt.% PEI) (c) Phase-Inverted morphology (20 wt.% PEI) (Wang et al, reprinted with permission from ref 76. Copyright 2006, Springer Nature)

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Examination of fracture toughness reveals that, maximum toughening is achieved with 20 wt.% PEI blend, which gives phase inverted morphology and main reason for increment was due to ductile deformation of thermoplastic matrix43,45. Also, particulate morphology associated with 10 wt.% PEI gave almost 2-fold increase in toughness compared to neat Cyanate resin45. This significant improvement is mainly because of crack path deflection behaviour of PEI spherical particles. Tensile study on blends concluded that, addition of thermoplastic does not lead to significant change in flexural properties, though, cocontinuous morphology obtained for 15 wt.% PEI gives maximum tensile strength, tensile modulus and % elongation at fracture71,76. Mechanical properties of Cyanate/PEI blend are summarized in table 1. 6.1.2 Effect of Curing Condition on Morphology Harismendy et al.45, studied the effect of curing temperature on morphology. Three different curing cycles with pre-curing temperature of 140 °C, 160 °C, 180 °C for 3h with post-curing at 200 °C for 2h and 250 °C for 1 h were compared for their effect on generated morphology of various blend compositions, varying from 0-20 wt.%. Further, it was found that, the activation energy for curing reaction of Cyanate esters is independent of thermoplastic loading43. For the blend with 5-10 wt.%, varying the curing temperature does not alter the overall morphology. However, size of spherical particles was found to be increased with increasing curing temperature. Blend with 15 wt.% PEI loading shows no significant change in morphology for three temperature cycles studied and phase separation mechanism remains same. For 20 wt.% PEI blend, 140 °C curing leads to the globules of irregular size and shapes, but 180 °C curing generates higher average particle size distribution. AFM study of fracture surface reveals sign of ductile deformation of thermoplastic matrix around particles45.

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Table 1. Mechanical properties of Cyanate esters-PEI blend with varying PEI concentration and Molecular weight

Tensile

Elongation

modulus

at break

(GPa)

(%)

63.7

2.27

4.14

75.6

2.38

84.7

Tensile Composition

KIC

GIC

(MPa.m1/2)

(J/m2)

327b

0.62a

100a

45,71

4.66

352b

1.35a

495a

45,71

2.39

5.86

427b

1.6a

680a

45,71

73.4

2.00

5.50

464b

3.1a

2480a

45,71

53.3

2.09

4.45

--

--

--

76

62

1.98

4.45

--

--

--

76

67.8

2.33

5.50

--

--

--

76

strength (MPa)

BADCy BADCy/PEI(0.3)

Compression strength (MPa)

Reference

=90/10 BADCy/PEI(0.3) =85/15 BADCy/PEI(0.3) =80/20 BADCy/PEI(0.5) =90/10 BADCy/PEI(0.5) =85/15 BADCy/PEI(0.5) =80/20 a.

Pre-cure at 180 °C for 3h and post curing at 200 °C for 2h, 250 °C for 1h

b.

Pre-cure at 160 °C for 3h and post curing at 200 °C for 2h, 250 °C for 1h

Fracture toughness was found to be increased with increasing curing temperature for 5 and 20 wt.% PEI and it was exceptionally high for 20 wt.% pre-cured at 180 °C. This enhancement is due to obtained bimodal distribution of particle sizes with small spherical particles and big globules. However, 10 wt.% showed decrease in toughness with increase in pre-cure temperature, as particle size increased. For PEI with 15 wt.% composition, the fracture toughness remains unaffected with change in the curing conditions.

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Page 20 of 91

Similar trend was observed for the tensile test study, which shows that increase in tensile strength with an increase in the pre-cure temperature and 20 wt.% PEI blend pre-cured at 180 °C yield highest strength as shown in table 1. 6.1.3 Effect of Molecular Weight on Morphology With the increase in molecular weight, viscosity of blend also increases, thereby affecting phase separation during blend curing. Wang et al.76 used two different PEI of inherent viscosities of 0.3 dl/g and 0.5 dl/g with the 6hr curing at 150 °C. Blend with 10 wt.% for PEI (0.5 dl/g) leads to different morphology than particulate in which ribbon like matrix domain of PEI are dispersed in Cyanate rich matrix. For 20 wt.% of PEI with 0.5 dl/g leads to smaller particle size than PEI with 0.3 dl/g at the same composition, mainly because of smaller Cyanate particles are not able to merge further due to increased viscosity for PEI with 0.5 dl/g sample. In confirmation with previous observation on morphology, 15 wt.% of PEI (0.3) resulting in co-continuous morphology showed maximum tensile strength. Ribbon like morphology is found to give minimum tensile strength and hence, tailoring of molecular weight of modifier become essential, in order to avoid ribbon like morphology.

6.2 Poly(ether Sulfone) blend Poly(ether Sulfone) has high service temperature up to 180°C in an unstressed condition and good mechanical properties. It has fair shrinkage and moisture uptake properties. Broad range of service temperature, good creep behaviour, excellent electric properties are key feature to this thermoplastic75. 6.2.1 Effect of Composition on Morphology Recently in 2013, Thunga et al.26, evaluated toughness and coefficient of thermal expansion behaviour as a result of blending with Poly(ether Sulfone) (PES) at different compositions.

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Up to 15 wt.% of PES, morphology observed was particulate in which finely dispersed PES particles were found inside continuous BECy phase. Increased in concentration from 5 to 15 wt. % PES, resulted in to increase in size and number of PES particles along with a simultaneous decrease in Cyanate phase. This morphology with continuous BECy phase changes to discontinuous structure at 20 wt.% which is called as co-continuous phase. As, with PEI only 15 wt.% loading resulted in co-continuous morphology, here with PES, large loading of up to 20 wt.% is required to achieve similar morphology. This requirement of higher loading as compared to PEI is mainly due to lower molecular weight of PES as compared to PEI. However, instead of phase inversion morphology obtained at higher concentrations in PEI, 30 wt.% PES leads to non-uniform phase separated morphology in which large BECy micro domains are distributed inside separated BECy/PES structure. Evaluation of flexural properties using three-point bending test concluded that, flexural stress, flexural strength and flexural toughness increase initially up to 10 wt.% PES that led to particulate morphology and then decreases with further increase in PES concentration. Kinloch et al.69, examined the fracture toughness properties and results of mechanical properties of PES/CE blend which are listed in table 2. This decrease in flexural property at higher concentration (20-30 wt.%) are due to discontinuous BECy phase. However, coefficient of thermal expansion (CTE) was found to decrease with increasing PES concentration, as PES has a considerably lower CTE (~25 ppm/°C) than BECy (~60 ppm/°C) at room temperature. Low value of thermal expansion coefficient is essential for high temperature polymer composites to improve dimensional stability and avoid residual thermal stress in composites26. When PES are functionalised and blended with Cyanate esters, they exhibit improved properties. Chang et at30, used hydroxyl and Cyanate terminated Poly(ether Sulfone) denoted as a HPES and CPES respectively for toughening of BPADCy. Two PES composition with 21 ACS Paragon Plus Environment

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Page 22 of 91

10 wt.% and 50 wt.%, giving particulate and co-continuous interconnected structure respectively, were evaluated for fracture toughness with and without using curing catalyst. Surprisingly, for 10 wt.% blend of CPES resulted in blurring interface along with particulate morphology as shown in figure 8-a.

(a)

(b)

Figure 8. Morphology of 10 wt.% PES having different functional groups (a) CPES (b) HPES with 1 wt.% catalyst (Chang et al, reprinted with permission from ref 30. Copyright 2000, Elsevier) Table 2. Mechanical properties of PES toughened cyanate ester blend Composition

Flexural

Flexural

Flexural

Fracture

stress

strain

toughness

energy

(MPa)

(MPa)

(MPa)

J/m2

0% PES

110.8a

6a

349a

150b

26,69

5% PES

128a

8.7a

735a

--

26

10% PES

131.7a

8a

638a

190b

26,69

15% PES

118a

7.7a

600a

--

26

20% PES

92a

4.5a

199a

379b

26,69

25% PES

--

--

--

330b

75

30% PES

59a

2.15a

51a

340b

26,69

Reference

a. Pre-cure at 180 °C for 2 h and post-cured at 250 °C for 2 h

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b. fracture at 21 °C

This blurring interface is a result of interaction between BPADCy and CPES due to Polycyclotrimerizations by inherent Cyanate groups present in both monomers. This blurring interface causes improvement in adhesion between particles and matrix. As HPES does not have any Cyanate group, hence no blurring interface was observed. But as shown in figure 8b, the use of 1 wt.% catalyst reveals the existence of blurring interface due to inter-reaction between the hydroxyl termini in HPES and the Cyanate group in BPADCy, which is promoted by the catalyst, thus improving mechanical properties as listed in table 3. weight. It was found that, increase in molecular weight increases fracture toughness in both Cyanate esters and higher toughening was achieved with co-continuous morphology obtained at 20 and 25 wt.% of PES.

Table 3. Effect of functional group and curing catalyst on mechanical properties

Tensile Composition

strength, σ (MPa)

Tensile Modulus, E (GPa)

Fracture energy, G

Reference

2

(J/m )

HPES 10 wt%

81.97

3.15

33.5

30

HPES 50 wt%

78.85

2.82

138.5

30

81.97

3.15

67

30

78.85

2.82

415.6

30

CPES 10 wt%

81.98

3.16

80.3

30

CPES 50 wt%

78.89

2.82

416.6

30

HPES 10 wt% with curing catalyst HPES 50 wt% with curing Catalyst

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Page 24 of 91

6.2.2 Effect of Molecular Weight on Morphology Rau et al. [77], evaluated the influence of different molecular weights of Hydroxyl functionalized Phenolphthaein based Poly(arylene ether sulfone) on morphology of PESCyanate esters blend. Two PES with number average molecular weight Mn=15000 g/mol and Mn=20000 g/mol were used to modify Cyanate esters at varying composition from 20 to 30 wt.% PES. For Molecular weight of Mn=15000 g/mol, 20 wt.% PES resulted in cocontinuous morphology and increasing concentration to 30 wt.% led to finer phase structure. However, increase in molecular weight to Mn=20000 g/mol for similar 20 wt.% concentration was found to generate phase-inverted morphology. Zhan et al.31, found similar effect when intrinsic viscosity of PES was increased in Cyanate/Epoxy/PES blend. Thus, higher viscosity at the onset of phase separation, due to increase in molecular weight can achieve co-continuous or phase-inverted morphology even at lower concentration of modifier. Recently, Uhlig et al.78, studied four different molecular weight of PES to modify two different grades of Cyanate esters. Cyanate esters BADCy and METHYLCy were modified using PES at varying molecular

6.3 Polysulfone blend Polysulfone are having broad range of service temperature from -100°C to +200°C and they are known for their excellent mechanical and electrical properties, fatigue endurance, fair shrinkage and water uptake properties. Continuous exposure to high service temperature up to 150°C are common for Polysulfone thermoplastics. Additionally, their moisture and hot water resistance properties are remarkable with no hydrolysis75. 6.3.1 Effect of Composition on Morphology

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Study on Cyanate ester blend with Polysulfone (PSF) was first reported by Woo et al.73, in 1994. Morphology study reveals that, there is a transition of morphology from particulate to co-continuous at 20 wt.% concentration. Further, Hwang et al.48, investigated functionalised Polysulfone for its effect on toughening of Cyanate esters in 1997. Polysulfone were functionalised via bromination and cyanation reaction to result Cyanated Polysulfone (CNPSF), and both PSF and CN-PSF were solution blended with BADCy in three different concentrations of 10, 20, 30 part per hundred (phr). For PSF concentration of 10 phr, particulate morphology was observed with spherical particles having a size of around 0.5-1.0 µm dispersed in BADCy matrix. Increase of PSF concentration to 20 phr leads to phase inversion where the size of dispersed BADCy particles are around 4-8 µm. Further increase in concentration to 30 phr does not alter the morphology but, the size of BADCy particles reduces to 1-2 µm due to increased viscosity of the blend supressing the growth of particles. For CN(0.6)-PSF blend, smaller particle size of 0.2-0.3 µm was observed for 10 phr and increase in concentration to 20 phr generates co-continuous morphology. Further increasing concentration to 30 phr causes phase inversion, but particle size observed was small, 0.3-0.4 µm. Also, adhesion between particles and matrix found to be good for observed morphology. This change in morphology and reduction in particle sizes are due to the chemical reaction of functional group in CN-PSF with cyanate group. Fracture toughness evaluation highlighted that, blend of CN-PSF with 30 phr have a maximum toughening effect due to tough CN-PSF act as matrix and chemical reaction helps in improving adhesion between particle and matrix. Interestingly, 20 phr concentration for both cases leads to equal toughening, as morphology observed are different where CN-PSF blend leads to co-continuous morphology while PSF blend with phase inversion morphology. 6.3.2 Effect of Curing Condition on Morphology

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Change in morphology as a result of different curing condition were studied by Hwang et al. 29

, in 1999. Observation of morphology revealed that, the change in phase separation

mechanism as a function of curing temperature for the BADCy/PSF blend. For curing temperature of 250°C, particulate morphology with PSF particles dispersed in BADCy phase was observed for 10 phr which changes to co-continuous phase at 15 and 20 phr concentration, followed by phase inversion at 30 phr. However, decrease in curing temperature to 200 and 230°C changes the phase separation mechanism even at 20 phr concentration and results in phase inversion, in which BADCy particles are dispersed in PSF matrix phase. Further, BADCy particle size reduces with increasing concentration to 30 phr. This reduction in BADCy particle size is due to increase in viscosity with a decrease in curing temperature constraining the growth of particles. For a low curing temperature of 80°C, only 10 phr of PSF concentration form co-continuous morphology and changes to phase inversion at 15 phr only. Marieta et al.79, used the AFM tool to study morphology change as a result of different precure temperatures. For 15 wt.% besphenol A Polysulfone, transition of particulate morphology to dual phase morphology consist of both particulate as well co-continuous phases which were observed with increasing pre-cure temperature from 160°C to 180°C. Also, AFM images study revealed secondary phase separation that occurs in the separated thermoplastic domain. 6.3.3 Effect of Molecular Weight on Morphology Molecular weight causes change in morphology due to the fact that, viscosity increases as molecular weight of modifier increases. Hwang et al.72, in 2000 studied the effect of four different molecular weights on morphology. Initially at low molecular weight samples with 10 phr concentration, morphology forms are particulate having PSF particles dispersed in BADCy matrix. At the same concentration, increase in molecular weight leads to the increase

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in size of PSF particles and at a higher molecular weight of around Mw=84400, phase changes to co-continuous morphology. Thus, with higher molecular weight only 15 phr concentration can cause phase inversion and this change is driven by viscosity change. 6.3.4 Mechanical Properties of Cured Blend Table 4. shows that, the fracture toughness of neat BADCy were improved as a result of adding Polysulfone. For the neat PSF as well as CN-PSF, maximum value of fracture toughness was obtained for 30phr concentration. However, Cyanated Polysulfone gives maximum toughening Table 4. Mechanical properties of neat PSF and CN-PSF at varying concentration Composition

BADCy

BADCy/neat PSF(10 phr)

Flexural strength, MPa 195.97 ±

Flexural strain, % 7.4 ±

3.7

0.3

185.4

Flexural Modulus, MPa 3112 ± 51

Reference KIC (MPa.m1/2) 0.62

48

± 6.9 ± 0.6 3107 ± 64

0.825

48

± 4.5 ± 0.2 3200 ± 114

1.125

48

± 4.5 ± 0.2 3106 ± 51

1.25

48

± 7.3

± 2789 ± 61

0.78

48

5.8 ± 0.8 2844 ± 69

1.14

48

± 5.0 ± 0.2 2887 ± 61

1.52

48

7.3 BADCy/neat PSF(20 phr)

183.8 9.0

BADCy/neat PSF(30phr)

130.8 2.9

BADCyCN(0.6) phr) BADCyCN(0.6) phr) BADCyCN(0.6) phr)

PSF(10 166.5 7.5 PSF(20 149.6

1.2

±12.5 PSF(30 141.3 3.6

due to present functional group which reacts and improves the adhesion between particles. Woo et al.73, compared two thermoplastics, PolyetherImide (PEI) and Polysulfone (PSu) at 20 wt.% in polycyanate and concluded that, PSu is more effective in toughening, due to the 27 ACS Paragon Plus Environment

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observed small particle size of approx. 0.8 µm than that of PEI particles which are of 2 µm size or greater in co-continuous phase. KIC fracture toughness for 20 wt.% PSu/Polycyante was 1.45 MPa.m1/2, much higher than that of PEI KIC =1.10 MPa.m1/2 at the same concentration. However, the glass transition temperature of PSu is lower compared to PEI, i.e. Tg10 wt.% PPG, resulted in tensile strength of around 30-35 MPa and glass transition value above 250 °C. Improvement in tensile property was observed up to a concentration of 40 wt.% and further addition of modifier led to decrease in tensile properties of the matrix. Iijima et al.84, synthesised random as well as multi-block type Polyimides and blended with Cyanate esters. They concluded that, random PIs are more effective in toughening than multi-block type PIs. Further, co-continuous and phase-inverted morphology resulted in effective modification of Cyanate esters. A Blend of 15 wt.% random PIs (M.W 63400) resulted to almost 65% increase in fracture toughness without degrading flexural modulus and glass transition temperature. Puglia et al.85, reviewed the effectiveness of hybrid modification of epoxy with micro scale elastomer/thermoplastic and nanoscale fillers such as, silica, carbon nanotubes, clay, etc. They concluded that, hybrid modification in epoxy allow to tailor multiple properties independently

at

two

length

scale

i.e.

nanoscale

filler

and

micro

scale

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thermoplastic/elastomer and thus, extending their range of applications. This hybrid modification provides the effective way to balance between toughness and modulus properties along with imparting excellent thermal and moisture stability in the epoxy resin. This hybrid modification can also be extended for these thermoplastic toughened Cyanate ester blends to enhance their properties further. Filler modification of Cyanate resins have been studied by various researchers86-88. Prashanth et al.89, incorporated Zirconium tungstate in CE to enhance its dimensional stability, as Zirconium tungstate has a negative coefficient of thermal expansion (CTE). They reported that, modified CE resin resulted in decrease in the CTE of matrix, and hence reduced the warpage and curvature in fibre reinforced composites thereby minimizing residual stress. In another study, Pan et al.90 modified CE resin with silicate nanorods and reported in 40% increase in the modulus. Further, strength and toughness was increased to 42 and 55% respectively. Wooster et al.91, studied hybrid modification of CE with silica filler and both elastomer and thermoplastic modifiers, increase in toughness have been reported. Xie et al.92, evaluated the effect of hybrid fillers, CTBN rubber/silicon nitride (CTBN/Si3N4) in the BADCy resin and reported about 59.5 % increase in impact strength. Also, flexural strength was increased by 34.3% for the hybrid modified system. Thus, hybrid modification of CE blends is an another effective method to enhance the properties of matrix, thereby extending their applications.

7. Toughening mechanisms in thermoplastic toughened Cyanate ester blends: Understanding the mechanism of toughening is important, as it allow to design properties through controlling various decisive factors such as particle size, volume fraction, modulus, etc. Phase separation occurs in thermoplastic toughened thermoset resins, producing two phase morphology follows various toughening mechanisms based on the characteristics of polymer used. Commonly reported toughening mechanism for these blends are- crack 32 ACS Paragon Plus Environment

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pinning, crack path deflection, crack bridging, stress whitening and debonding, cavitation and plastic hole growth,93etc. which are further discussed in detail. 7.1 Crack bridging: Crack bridging is most probable mechanism in thermoplastic toughened resins, where the phase separated rigid particles span the two crack surfaces and reduces the stress concentration by applying surface traction at the crack tip94. Energy absorbed by crack to tor bridging particles increases the toughness and mechanism is termed as a “crack bridging”. Figure 9, illustrate the schematic representation of crack bridging in which, crack propagate in brittle matrix, through particles without breaking them. Then, with the opening of crack, these particles span the crack surfaces and energy absorbed in stretching and tearing of bridging particles leads to toughening.

Figure 9. Schematic showing stages of crack bridging mechanism

In the fractographs, the fractured surface showing damaged particles in the plane of crack give the evidence for toughening by crack bridging mechanism. Several studies on

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thermoplastic toughened epoxy have reported, crack bridging as a major toughening mechanism61,64-65. Also, crack bridging is independent on the potential of matrix for plastic deformation95. Kunz-Douglass et al.96, studied rubber toughening of epoxy resin and proposed a model for crack bridging. They observed that, when crack propagates, it leaves rubber ligaments remain attached to crack surface and stretches with opening of crack wedge, thereby acting like a spring. Based on their observation, they proposed a first model to quantify toughening based on the amount of elastic energy stored in the rubber particles while stretching. This model considers, three major factors that leads to toughening- (1) Particle size (2) Tearing energy of particle (3) Volume fraction of particle in the matrix. According to rule of mixture, toughness of composite can be express as follow, 4 23 = 23 51 − 7 8 + ∆23

……………(5)

Where, 4 23 = Fracture toughness of matrix

7 = Volume fraction of particles ∆23 = 4⎾; 7 = increased in fracture toughness due to bridging particles Where, ⎾t = tear energy of particle (smaller the particle, higher tearing energy)

Kinloch et al.97, disagreed with above theory, as it does not consider stress whitening, large plastic deformation, increase in toughness at elevated temperature, etc. Also, rubber tear theory does not explain about, how nonreactive rigid thermoplastic particles can lead toughening, as they possess low deformation characteristic. They proposed another a model, which consider matrix dilatational deformation and cavitation cause by rubber particles as a primary toughening mechanism. Their observation concluded that, major toughening in rubber toughened epoxy achieved due to plastic deformation of the matrix. Based on Kinloch

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98

work8, Huang et al. , developed a mathematical model to assess the toughening due to both

crack bridging as well as cavitation and shear banding, According to Kinloch model97,

Fracture energy of rubber toughened epoxy is given by the following equation, 23 = 23 +Ψ

……………(6)

Where, 23 =fracture energy of unmodified epoxy resin

Ψ= toughening due to rubber particles and, Ψ=∆1 + ∆= + ∆> Where,

∆1 = toughening due to crack bridging, ( ∆1 = 4⎾; 7 , given by rubber tearing strain model proposed by Kunz-Douglass96)

∆= and ∆> are toughening contribution due to plastic shear banding and plastic void growth in the matrix, respectively. For the calculation of ∆= and ∆> , Kinloch et al.51,97,99, proposed a plastic shear-band mechanism. Thus, using above model, various aspect of toughening such as particle size, volume fraction, fracture strength of particles, etc. can be designed effectively. However, these model are proposed for rubber particles and their application for thermoplastic toughening is still remains questionable due to different physical properties of particles.

7.2 Crack pinning: In this mechanism, rigid thermoplastic particles act as a crack arrester, wherein it causes the crack to blow out, and thus to absorb extra energy. This is common mechanism for morphology containing thermoplastic particles dispersion rather containing brittle thermoset in particulate form, as thermoplastics are tough and impenetrable99. In crack pinning mechanism, fracture surface consists of ‘tail’ near the particle, which can be observed in 35 ACS Paragon Plus Environment

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fractographs. Schematic representation of crack pinning mechanism is shown in figure 10. When moving crack meets the inhomogeneity in the path, crack temporarily gets pinned at that point. The front of pinned crack then bow forward between pinning particles, and until, it forms semi-circular segments with diameter equal to the spacing between pinning points, the overlapping of segment will result behind the pinning points, thereby breaking the crack front, shown in figure 10. Thus, energy absorb during the time of crack pinned till the breaking of crack front behind the pinning points, leads to toughening, known as a “crack pinning mechanism”.

Figure 10. Schematic of crack pinning mechanism In 1970, Lange95 reported about crack pinning mechanism, in which second phase inhomogeneities act as an obstacles impeding the front of moving crack, requiring more energy for propagation. In their study, aluminium trihydrate filler were added in epoxy as a fire retarding filler, which simultaneously led to increase in fracture toughness and increment were found to depend on the volume fraction of the fillers. To explain the model, fractographs were sudied and stated that, crack initiate in brittle matrix which interact with second phase particle, bow between filler particle but remained pinned. There model gives, a 36 ACS Paragon Plus Environment

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functional relationship between the fracture energy of filler modified material and the average spacing between the filler particles. According to their model, fracture energy in filler modified composite is given by the following equation, 

0 = 2@A +  B

……………(7)

Where, T= line energy per unit length of crack front d= arc of circle (i.e. distance between inhomogeneity d=2R) Crack pinning is mainly associated with inorganic rigid filler particles and is less effective in ductile matrix material98. Another model was proposed by Evan100, which accounts for the segment interaction of crack front and predicts the nonlinear increase in fracture toughness, which is the function of volume fraction of particle. Kinloch et al.99, reported about crack front bowing, when epoxy resin was modified with glass particles. Yee101, investigated toughening of nylon 66 with rigid polyphenylene oxide particles and found that, rigid particles induce localized dilatation and matrix deformation are the major reason for toughening. Also, cavitation and the crack pinning by rigid particle, increasing stress concentration at crack tip contributes significantly. 7.3 Crack path deflection: Crack path deflection is the mechanism associated with rigid second phase particles dispersed in brittle matrix. In this mechanism, the rigid thermoplastic particles cause crack to deviate from its path in to another plane. This crack path deviation results in increased surface area and hence, the energy required for the propagation of crack. Crack path deflection mechanism is schematically represented in figure 11.

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Figure 11. Schematic representation of crack path deflection mechanism Kinloch et al.102, reported about crack path deflection, as a toughening mechanism for particulate morphology in thermoplastic modified epoxy system. Faber et al.103, proposed a quantitative model for crack-path deflection, which assumes particle size has no effect in path deflection. Their model is based on the fact that, when crack intercepts the second phase particle, it will tilt at an angle of C from its original plane and the angle of tilt depend upon the position of particle with respect to path of advancing crack, shown in figure 12-a. If adjacent particle causes crack to tilts back in opposite direction, crack front will twist, shown in figure 12-b.

(a)

(b)

Figure 12. Tilt and twist of crack due to interaction with particle

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Thus, this tilting and twisting of crack results in mixed mode of loading. The tilted crack represents the Mode I (opening) and Mode II (sliding) loading, while twisted crack has mode III (tearing) loading along with Mode I. Using these loading conditions and local stress intensities at the crack front, Faber proposed the equation for fracture toughness given by, 0 = 

 

0

……………(8)

Where, = Average strain energy release rate representing net crack driving force   =strain energy release rate for un-deflected crack. Based on this study, Faber concluded that, twist of crank front is the important and contributes significantly in toughening.

7.4 Cavitation and massive-shear yielding mechanism: This mechanism is associated with blunting of crack tip due to its interaction with cavity developed around the second phase particle in the matrix. This interaction of crack front with the cavity, relives the tri-axial tension state to more uniaxial tensile stress state and this new stress state favours the shear band formation, creating large plastic zone104-105. Most of the studies on rubber toughening of epoxy, reported that, cavitation around the rubber particles, that leads to crack blunting and plastic deformation, are primary toughening mechanism105106

.

Person et al.105, investigated the deformation of CTBN- modified epoxy resin in three-point bending test and concluded that, cavitation of the rubber particles was the primary toughening mechanism present. Observation under optical microscope, reveal about shear bands, which were generated due to cavitated particles. Gazit et al.106, studied reactive rubber toughening in epoxy resin and reported that micro-cavitation process resulted in toughening of epoxy. In tensile testing, micro-cavitation was observed throughout the sample gauge length. Also, 39 ACS Paragon Plus Environment

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stress whitening and shear band was observed in sample tested on tensile impact tester, shown in figure 13.

(a)

(b)

Figure 13. Tensile impact test sample- (a) stress whitening (b) shear band formation (Gazit et al., reprinted with permission from ref 106. Copyright 1983, American Chemical Society)

It has been reported that, light scattering from the caviated particles results in stress whitening, which often observed at the crack tip or at fracture surface101,107. Stress whitening has also been reported in thermoplastic modified system in few references98. Dompas et al.104, proposed a model for rubber particle cavitation which assume spherical rubber particle and hydrostatic tension on the particle act as driving force for cavitation. They concluded that, particle cavitation is a function of relative volumetric strain given by following equation, DE =

')FG HIJK  LG MN/P

…………(9)

Where, Δ= Relative deformation of particle R1 =Bulk modulus of rubber

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Γ=0 = Energy per unit area @1 = van der Waals surface tension of rubber

From above equation it’s clear that, larger particle will cavitate first in deformation process followed by smaller particles.

7.5 Toughening mechanisms in thermoplastics modified Cyanate esters blends: Toughening mechanism in any system is complex and often consist of more than one mechanisms working simultaneously. McGrail et al.108 reported that, crack path deviation and crack front pinning are the toughening mechanisms in particulate/co-continuous/phase inverted morphologies. Their study was based on reactively terminated polysulfone and Cyanate esters, Epoxy and BMI blends. DiBerardino et al.27, studied toughening mechanism associated with Polyimide modified Cyanate ester and reported that, crack bridging and crack pinning mechanisms are the major toughening mechanism. Kim et al.109 evaluated toughening of Cyanate esters with Polyetherimide and concluded that, co-continuous morphology causes toughening through crack deflection and crack pinning by PEI continuous domains, shown in figure 14-a. Whereas, in phase inverted morphology region, shown in figure 14-b, PEI matrix deformation is the major reason for the toughening.

(a)

(b)

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Figure 14. Scaning electron micrograph (a) co-continuous region (b) Phase-inverted region (Kim et al., reprinted with permission from ref 109. Copyright 2002, Springer Nature)

Oyanguren et al.67, examined the fracture toughening mechanism in co-continuous morphology developed in polysulfone-Epoxy blend. They reported that, in thermoplastic rich domains, toughening mechanisms are the crack-path deflection, bifurcation lines and plastic drawing of PSu-rich particles. While, in thermoset rich domains, plastic drawing of the PSurich phase along with stress whitening and debonding of thermoset rich particles leads to toughening. Kinloch et al.69, used fracture mechanics approach to explain the effect of thermoplastic modification and mechanisms of toughening in modified Cyanate ester systems. Polyester copolymer and hydroxyl-terminated poly(ether sulfone) was used to modify and improve the toughness of Cyanate ester resin. Tapered double cantilever beam (TDCB) testing were used to calculate fracture energies of the modified systems. For unmodified system, stick/slip crack propagation was observed as a failure mechanism, which is associated with very brittle materials27. Figure 15, shows the scanning electron micrograph of unmodified Cyanate ester, in which fracture surface is very glossy, indicating that little plastic deformation has occurred, also the fracture surface has steps and change in level of cracks, which is associated with feather markings caused by the crack forking in fast brittle fracture.

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Figure 15. Scanning electron micrograph of unmodified BADCy resin. (Kinloch et al, reprinted with permission from ref 69. Copyright 2003, Springer Nature)

For PES/BADCy modified system, phase inverted morphology was observed for 20 wt% PES and it was found that, particles are not well bounded with matrix, as surface of particles was smooth with no matrix material attached to it as shown in figure 16. Thus, they concluded that, the cavitation and plastic hole growth micro-mechanism are the toughening mechanism for the modified system, which leads to significant increase in fracture toughness69.

Figure 16. Scanning electron micrograph of 20 wt% PES/BADCy blend (Kinloch et al, reprinted with permission from ref 69. Copyright 2003, Springer Nature)

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Figure 17. Scanning electron micrograph of 10 wt% PES/PT blend (Kinloch et al, reprinted with permission from ref 69. Copyright 2003, Springer Nature)

When Cyanate resin based on phenolic trizine (PT) was modified with PES, the developed morphology showed a good adhesion between Cyanate ester particles and PES matrix, thus failing by ductile tearing of matrix. Figure 17, shows the scanning electron micrograph of PT resin modified with 10 wt% PES, showing good adhesion between particles and matrix phase. Harismendy et al.45, studied PEI toughening of Cyanate ester and concluded that, particulate morphology corresponding to 10 wt% PEI led to toughening by crack path deflection and crack bridging with very little deboning present. They observed good adhesion between particles of PEI and Cyanate ester matrix.

8. Structure/property relationship: The resulting properties of the blends are directly linked to the morphology obtained after phase separation. As per the discussions on the morphology and toughening mechanism, it can be concluded that, co-continuous and phase inverted morphologies are effective in toughness enhancement and higher degree of phase separation will lead to higher toughening effect81. In phase-inverted morphology having good bonding between the phase separated particle and matrix, plastic deformation of thermoplastic matrix is the mechanism, which lead to significant toughening. Whereas, for morphology with loosely bonded particles, toughness is enhanced via cavitation, plastic hole growth and shear banding mechanism. Toughening in particulate morphology containing thermoplastic particles dispersed in the matrix follow crack bridging mechanism along with crack pinning and crack deflection mechanism. However, very fine particle dispersed in the matrix are ineffective and does not improve toughness significantly43,45. In co-continuous morphology, plastic deformation of 44 ACS Paragon Plus Environment

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thermoplastic rich domain is the important mechanism which improve toughness significantly. Functionalised thermoplastic such as Cyanate terminated poly(ether sulfone), results in blurring interface in morphology due to excellent bonding between thermoplastic phase and matrix, further enhances the toughness30. Thus, to enhance the toughness property of brittle CE, co-continuous and phase inverted morphologies are important along with use of functionalised thermoplastics.

9. Experimental method for the mechanical characterisation of toughened blends: Among all the properties, mechanical properties are usually the most important, as essentially all end applications and service conditions require some degree of mechanical loading. Selection of material for the application is often based on their mechanical properties such as fracture toughness, tensile strength, modulus, elongation, and impact strength. Hence, accurate characterization of these mechanical properties have become essential for the successful design of the component. Thus, in this section characterization methods for the toughness and deformation of CE and its thermoplastic blend are discussed in detail. 9.1 Fracture toughness: Fracture mechanics approach is used to calculate the resistance of material to the propagation of present crack, called as fracture toughness. This is important property of material and must be consider while designing the components for various applications. In fracture mechanics approach, it considers that, the crack is present in the material at which stress concentration occurs during loading. Then, the crack will grow when the stress intensity at crack tip will exceed the cohesive strength of the material110. It considers the linear elastic fracture mechanics in which, all energy dissipation is due to fracture process and the deformation that occurs in linear elastic. Fracture toughness of polymer/polymer blends are mainly 45 ACS Paragon Plus Environment

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characterized by Single-edge-notch bending (SENB) and compact tension (CT) tests. ASTM D5045 is mostly preferred test standard for these tests, which gives toughness in terms of the critical stress intensity factor (KIC) and critical strain energy release rate (G

IC).

In this

method, pre-cracked specimen is loaded either in tension or three-point bending and KIC value is calculated from the equation, which is derived from plane strain condition at the crack tip. Sharp notch is first machined in the sample and crack is initiated by inserting a fresh razor blade at the notch, while tapping blade. Recommended initiated crack length for test is at least two times longer than radius of machined notch. 9.1.1 Single-edge-notch bending (SENB) test: In this test, specimen consist of centre notch and loaded in three-point bending, shown in figure 18. For specimen having sheet geometry, sample thickness (B) should be assume equal to sheet thickness and width is taken as, W=2B. Initial crack length should have calculated such that, 0.45 < a/W< 0.55 (crack length nominally equal to thickness B and W/B=2), which includes crack pre-notch plus razor notch. Specification of sample for SENB test, is shown in figure 19. During test, readings of load and corresponding displacement of crack are recorded and curve of load vs crack displacement will be obtained.

Figure 18. Single edge notch bending test (SENB)

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Figure 19. Test specimen for single edge notch bending test 9.1.1.1 Calculation of fracture toughness: Stress intensity factor (K IC), is calculated using following standard formula, RT =

U 

VW "/ 

X YZ, MPa.m1/2

……………(10)

Where: [T = load in KN B = specimen thickness, cm W = specimen depth, cm a = crack length, cm and Z = \/] for 0 < Z < 1 Y Z  = 6Z '/)

_'.aab'b).'cbd.adH).e  f 'H)'bP/

……………(11)

Strain energy release rate is given by known relation, '0

 'bg L"K

h

…………..(12)

Where, 47 ACS Paragon Plus Environment

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i = Poisson’s modulus E = Young’s modulus 9.1.2 Compact Tension (CT) test: Test specimen used in compact tension test is shown in figure 20, which consider dimension such that crack length (pre-notch plus razor notch) is, a=B and W/B=2. Sample is loaded in tension on the machine which has controlled constant displacement rate (e.g. Servo hydraulic Instron testing machine) using fixture called clevis, displacement of crack and corresponding load is recorded. Recommended cross heat rate is 10 mm/min for both test methods. During test, readings of load and corresponding displacement are to be recorded and curve of load vs displacement will be obtained.

Figure 20. Test specimen for compact tension (CT)

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9.1.2.1 Calculation of fracture toughness: Stress intensity factor (K IC), is calculated using following standard formula, RT =

U 

VW "/ 

X YZ

……………(13)

Where, [T = load in KN B = Specimen thickness, cm W = specimen depth, cm a = crack length, cm and Z = \/] for 0.2 < Z < 0.8 Y Z  =

)HA.kklHm.lmb'd.d)  H'm.e) P bc.l N  'bP/

……………(14)

Further, Strain energy release rate is calculated using previous equation (12). Various studies on thermoplastic toughened resin have employed above test methods for evaluation of fracture properties62,109,111-113. Yoon et al.114, reported single-edge-notched bending test with 3-point bending mode at the rate of 0.5"/min for polysulfone toughened epoxy. In another study, Brooker et al.115 reported compact tension test for thermoplastic modified epoxy system. Sample with dimension of 20mm x 20mm x 3.5 mm were used and pre-cracked using small hacksaw together with razor blade to cut sharp crack while loading at rate of 1 mm/min.

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9.2 Tensile properties: In a broad sense, tensile test is the measurement of material ability to withstand pulling force and to quantify the maximum deformation in the material before breaking. Tensile elongation and modulus are the most important parameters indicating strength of material and is widely specified property for the material. Tensile modulus is determined from stress-strain diagram gives the information about relative stiffness of a material, which is useful in design of component for specific application. For the evaluation of tensile properties, tensile testing machine with constant cross head movement is used, which has a one movable grip and one stationary grip with self-aligning ability, thereby preventing alignment problem. An extension indicator known as an extensometer is used to determine the relative distance between two designated points located in the gauge length, during the elongation of test specimen. Test specimen for tensile test can be prepressed either for injection moulding or compression moulding for plastics116. Specimen may also be prepared by machining from plate, slab or similar form and for Cyanate esters blends, process employed is to cast the film/cured resin in the mold followed by machining. Test specimen dimension required for testing are described in ASTM D638 in detail and which is the most commonly used standard for the measurement of tensile properties of plastics. This test uses dumbbell-shaped specimen and type I sample is mostly preferred for the test, shown in figure 21.

Figure 21. Test specimen of tensile test 50 ACS Paragon Plus Environment

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There are five standard test speeds are specified in the standards, however, most frequently used speed of test is 0.2 in./min. To evaluate the tensile properties, test specimen is positioned on the grip of machine and loaded at rated speed. Load cell detect the resistance of specimen to elongation and this, load values at yield, maximum and break are recorded. 9.2.1 Calculation of tensile properties: Number of parameters such as tensile strength, percentage elongation at yield/break, modulus of elasticity, etc. can be calculated through tensile testing, using formulas given below, Tensile strength =

Load N cross section areasq. m. 

Tensile strength at yield MPa =

Maximum Load recordedN cross section areasq. m. 

Tensile strength at break MPa =

Load recorded at breakN cross section areasq. m. 

Modulus and elongation properties are calculated from stress-strain curve, for which extensometer is attached to specimen, which magnifies the actual elongation of specimen. To calculate modulus, tangent is drawn to first linear straight portion of the curve and two points are selected on tangent as per convenience recording stress and strain values. Formula used to calculate modulus is as followTensile modulus MPa =

diffrence in stressN/sq. m.  m difference in strain  m

And Tensile strain =

Change in length Guage length

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Various study on the thermoplastic toughened blends of Cyanate esters, also have reported tensile Characterisation. Tao et al.71 and Zhan et al.31, evaluated tensile properties of Poly(etherimide) and poly(ether sulfone) modified Cyanate ester blends respectively, using Instron tensile tester with sample having gauge length of 15 mm and cross head speed of 1 mm/min. In another study, Srinivasan et al.81, reported tensile porperties for poly(arylene ether) modified cyanate ester resin with a cross head speed of 1.27 mm/min. 9.3 Impact properties: Impact resistance of material is the ability of any material to resist fracture, under the high speed stress loading. The impact properties are the measure of the overall toughness of material, which is the ability of material to absorb energy before fracture. Impact strength of polymeric material are the direct representation of their toughness characteristic, and higher the impact strength, higher will be the toughness. Impact properties of polymeric material are usually calculated using Izod-charpy impact test, as per ASTM standard D256. The objective of Izod-charpy impact test is to calculate the strength of standard test specimen to the pendulum impact load and the results are expressed in terms of kinetic energy loss by the pendulum for the breaking of specimen. The energy absorb in the breaking of specimen consists of the energy needed for the deformation of the specimen, to initiate crack, to propagate crack and to toss the broken end of the specimen. Specimen used in the Izod test are notched to provide stress concentration which promotes brittle fracture and thus, preventing plastic deformation. In Izod test, specimen is clamped vertically as a cantilever beam and it is struck by a swing of a pendulum, released from the predetermined height over the specimen clamp. While in charpy test, similar setup is employed except for the positioning of sample, as here sample is supported horizontally like a beam and fractured by the blow from the pendulum in the middle of the specimen. Dimension of sample used in Izod-charpy test is as shown in figure 22, which can be prepare either by moulding for cutting 52 ACS Paragon Plus Environment

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from sheet. Preferred width specimen is 6.35 mm or above, as test specimen having width less than this may overestimate the strength due to absorbed energy in crushing, bending, and twisting.

Figure 22. Izod-charpy impact test specimen

9.3.1 Izod test: Clampping setup for Izod test is shown in figure 23, in which notch end facing towards the strike edge of pendulum. During test, pendulum with known mass is released from predetermined height, having certain known potential energy allowed to strike to the specimen. During the impact, energy absorbed in the fracture of specimen are read directly in in-lbf or ft-lbf from the scale or digital display. Impact strength is then calculated by dividing energy absorbed in breaking by the thickness of specimen. In another case,

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Figure 23. Schematic representation of Izod test

9.3.2 Charpy test: This test is similar to Izod, except sample poisoning, as shown in figure 24. Here, sample is mounted horizontally and supported unclamped at the both ends. Reading are taken for sample those break completely and impact strength is calculated by diving breaking energy by thickness of the specimen.

Figure 24. Schematic representation of Charpy test

9.4 Dynamic Mechanical Thermal Analysis (DMTA)

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Dynamic Mechanical Thermal Analysis is an advance characterization technique to evaluate the viscoelastic properties of polymeric materials. In this technique, viscoelastic property measurement is carried out in an oscillatory mechanical deformation experiment, as a function of temperature and frequency38,117. DMTA analyser consist of, a linear drive motor to load the sample via probe, a sensor to measure displacement such as a linear variable differential transformer (LVDT), a temperature control furnace, drive shaft and the clamps to hold sample while testing. Based on the service condition of polymer blends, various deformation modes such as tension and compression, torsion and bending (Single cantilever, dual cantilever or three-point bending), and shear mode are employed in the characterization117. DMTA works on the principle that, polymer when subjected to external stimuli (e.g. mechanical), it develops processes in their structure such as change in length and angle of bonds, which takes time to bring in new equilibrium. These process in the structure are the function of time called “relaxation time”, which also depend upon temperature. During the recovery in the polymer, it creates the back-stress in the material opposite to applied stress, thus causes a material to return to original state when external stress is removed. These stress levels are in the linear elastic range of material, such that stress α strain, and constant of proportionality is called Young’s modulus (E). The analyser gives the thermograms as plot of elastic modulus, E and tan δ, versus temperature/frequency, from which viscoelastic properties of material are recorded. The tan δ is the ratio of loss modulus (E") to the storage modulus (E'), and its peak represents the glass transition temperature of polymer. Storage modulus represents the, energy absorbed and release elastically during deformation, while, loss modulus represents the amount of energy absorbed by the material due to internal motions.

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In DMTA experiment the applied sinusoidal stress σ is such that, the viscoelastic material loads in elastic region. Expression for resultant sinusoidal stress and strain is as follow, ‰Š = ‰A . cos ‹. Œ. Š

……………(15)

 Š = A . cos ‹. Œ. Š + Ž 

……………(16)

Where, Œ= Angular frequency of the oscillation The equation for complex modulus is then given by, ∗ =

‘; ’;

=  - + ‹"

……………(17)

and tan Ž =

h" h-

……………(18)

Where, "= Loss modulus and ′= Storage modulus Various studies on thermoplastic toughened Cyanate esters blends have also reported, DMTA characterization tool for the evaluation of viscoelastic properties of blends26,73,70,118. Kim et al.109, characterized the blend of PEI/CE using DMTA technique in dual-cantilever bending mode. Sample of dimension 35 X 10 X 2 mm, were loaded at fixed frequency of 1 Hz at heating rate of 2°C/min over a temperature range of 50°C to 350°C. The effect of various morphology generated on the loss and storage modulus of the blend were evaluated. In another study, Harismendy et al.43 evaluated the viscoelastic property of BADCy/PEI blend using three-point bending arrangement with 44 mm span and elastic modulus property of blend were reported. Thus, DMTA analysis is a tool, that provides the understanding of complexity that appear due to time-temperature dependency on the modulus of polymeric viscoelastic materials. 56 ACS Paragon Plus Environment

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10. Processing characteristics of thermoplastic/Cyanate esters blends: Processing characteristics of developed toughened thermoplastic/Cyanate esters blends and various fabrication techniques applicable to process these materials for manufacturing the final component/structures, e.g. fibre reinforced composites, fibres, films, etc. are critically discussed in the next section. 10.1 Processing characteristics: Cyanate esters and their blends are still new materials in the field of structural composites, owing to their processing similarities with epoxy resin, processing of these material to develop fibre reinforced composites and other structures is not a challenge. Epoxy resin have been widely explored and various methods have been developed for fabrication of high quality fibre reinforced composites. Hence, these developed processing techniques for epoxy resin can easily be imported for Cyanate esters with/without little modifications. Cyanate ester monomers are available in large variety of forms such as solid (REX-371), liquid (AroCy l-10) and semi-solid (XU71787)4, hence it offers an advantage for processing. Another advantage with Cyanate ester monomers is their storage stability. Uncatalysed Cyanate esters monomer can be stored for more than 6 months at room temperature and even for longer duration at lower temperature4. Cyanate esters are self-curing resin in which, curing is trigger by the temperature, though to increase the rate of cross-linking, curing catalyst can also be used. Popular catalyst for Cyanate esters are chelates of metal ions and carboxylate salts119-120 with co-catalyst nonylphenol30,77,121. Low toxicity is one of the important characteristics of Cyanate esters, which thus simplifies the processing4,46. However, Cyanate esters are highly exothermic and hence, this should be carefully considered while processing.

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10.2 Composite fabrication methods for Cyanate esters and their blends: All common fabrication methods of composite can be used for Cyanate esters and their blends due to their processing similarities with epoxy resin. This processing advantage of Cyanate esters resin attracts them for various commercial applications. Cyanate ester resin also possesses excellent tack and drape characteristics, which is required for composite fabrication and hence, avoids use of any external adhesive4. Developed composite processing techniques such as resin transfer moulding (RTM)77,122-123, resin film infusion (RFI)77, prepregs17,122,124, filament windings125-128, autoclave moulding12,129-130, pultrusion131-132, etc. can be efficiently used for fabrication of fibre reinforced composites with Cyanate ester resin. In the following section, commonly used composites fabrication techniques for structural applications are described in detail. 10.2.1 Resin transfer moulding (RTM): Resin transfer moulding (RTM) is common composite fabrication technique widely used for fabrication of structural composites. The schematic of resin transfer molding process is shown in figure 25. In this technique, fiber preform/dry fiber reinforcement are placed on the surface of lower half mold and then the upper mold is closed.

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Figure 25. schematic of resin transfer moulding (RTM)

Mold are having the shape of desired part and a release gel is applied on the mold surface for easy removal of the composite. Resin is then pumped into the mold under pressure, displacing the air through vents, until the mold is filled. The uniformity of resin flow can be enhanced by vacuum application21. After the fill cycle, the cure cycle starts during which the mold is heated, and the resin polymerizes to become rigid plastic, thus forming composite. The viscosity of the resin plays an important role in resin transfer molding process because injection time depends upon viscosity of the resin. If viscosity of resin is high, high pressure is required which may cause displacement of fibres inside the mold during the resin injection stage, known as fiber wash133. Recommended viscosity of resin for RTM are in the range of 100-300 cP1. Rau et al77, worked on the resin transfer moulding system for thermoplastic toughened Cyanate esters blend. Various molecular weight and formulation of Poly(arylene ether sulfone) were blended with CE and carbon fibre reinforced composite laminate were

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fabricated using RTM process. RTM technique resulted in high quality laminate with void content less than 2%. Improvement in damage tolerance were reported for thermoplastic modified composites, studied using compression after impact (CAI) test. Mechanical properties of composite are listed in table 7, which shows that, high loading of thermoplastic at same molecular weight (15000 g/mol) resulted in higher fracture toughness and flexural modulus. Also, with increase in molecular weight to 20000 g/mol at same concentration resulted in increased mechanical properties.

Table 7: Mechanical properties of Carbon fibre reinforced composite

Molecular

Concentration,

Flexural

Fracture

weight,

%

modulus,

toughness-

GPa

G11C, KJ/m2

3.55

2.5

g/mol CE Poly(arylene

15000

20

3.98

3.1

ether

15000

25

4.08

3.8

sulfone)/CE

15000

30

4.4

3.94

blend

20000

20

4.02

3.5

Reference

77

Hillermeier et al.123,134, reported RTM technique for thermoplastic and elastomeric toughened Cyanate resin. Two thermoplastic, PEI and PS were blended with CE at 10 wt% and glass fibre reinforced laminate were evaluated for their mechanical properties. Fracture toughness of 653 and 563 J/m2 were reported for PEI and PS matrices, respectively. Parlevliet et al.122, from airbus group, investigated epoxy/Cyanate esters blends composite properties manufactured by RTM and showed excellent high temperature stability of the product. 60 ACS Paragon Plus Environment

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10.2.2 Prepreg and autoclave moulding:

Figure 26. Schematic of Hot-melt prepreg process

Prepreg technique have been attractive choice for Cyanate esters composites in past. Prepregs are the pre-impregnating fibres material, which can be impregnated either in resin solution or by filming technique (hot melt process). Large variety of fibres such as carbon, aramid, glass, quartz, etc. can be easily been prepregged4. In solution technique, impregnation of reinforcement is archived by dipping it in molten resin. In an alternate method, hot melt process, film of resin and reinforcing fibre are sandwich between two release films, while simultaneous application of heat and pressure135, shown in figure 26. Generally, fabrication of composites with stack of prepregs are achieved by an autoclave or compression moulding processes126. In autoclave, prepregs are stacked in a mold in a definite sequence and then spot welded to avoid any relative movement in between the prepreg sheets. After stacking the prepregs, the whole assembly is vacuum bagged to remove any air entrapped in between the layers. Then, the entire assembly is transferred to autoclave, which provides the heat and pressure required for consolidation and curing of resin. Prepegging technique have been

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widely explored for Cyanate esters and significant number of literature is available. Wang et al.124, reported prepregg technique for fabrication of composite with polyetherimide and polyamideimide toughened cyanate resin. They reported that, resultant composite has low heat release rate and self-extinguish time of only 4 sec. Autoclave processing for composite was studied by Hayes et al.130, for glass fibre reinforced composite with elastomer toughened Cyanate resin. Epoxy-terminated butadine acrylonitrile rubber were used to modify Cyanate ester resin, which resulted in increase in mode I fracture toughness to 2-fold as compare to unmodified CE. However, water absorption was found to increase as result of rubber modification. Barton et al.12, investigated prepregging and autoclave technique for BMI/CE blend. Their study concluded that, blend of 50 wt% BMI and 50 wt% CE gives maximum interlaminar shear strength (109.7 MPa). Parlevliet et al.122, investigated epoxy modified cyanate ester composite fabricated using prepreg process. Formulated blend possesses excellent track and drape, resulted in easy processing through prepreg and composite structure showed high stability and mechanical properties at elevated temperature (135°C). Mathew et al.17 and Hamerton et al.129, also investigated prepreg technique for fibre reinforced Cyanate ester composites fabrication and concluded that, prepreg and autoclave process are can easily be imported in these blends.

10.2.3 Resin film infusion (RFI):

Resin film infusion is liquid moulding technique and emerging as an alternative to RTM. It reduces the cost of tooling required keeping quality of composites comparable to that achieved with RTM136. Schematic of Resin film infusion technique for fabrication of composites is shown in figure 27. In this technique, sandwich of resin film and fibre cloths is form by alternate laying them in required fashion, which then vacuum bagged as per the sequence shown in figure 27. Peel ply are used for easy removal of composite and bleeder to

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absorb excess resin137. Entire bagged assembly is then heated to result in curing of resin with simultaneously maintaining the vacuum pressure for consolidation. Under the action of heat, viscosity of resin film decreases allowing resin to flow and vacuum pressure causes consolidation and infusion of resin to in the fibre, thus impregnating it.

Figure 27. Schematic of Resin film infusion process

High viscosity Cyanate resin are suitable for fabricating composite panels using resin film infusion process, as it possesses film formability. Although one of the important technique for structural composites, literature on resin film infusion study on Cyanate esters are limited. Rau et al.77, investigated resin film infusion for Cyanate ester/polysulfone blend and suggested that, RFI is suitable composite fabrication techniques for high viscosity resin. Poly( arylene ether sulfone) with molecular weight of 15000 g/mol when blended at higher loading of 25 wt%, resulted in increase in viscosity, thus RFI process was used to fabricate composite samples. Mechanical properties of composite are listed in table 7. In case of thermoplastic toughening, higher thermoplastic loading in Cyanate esters results in significant increase in viscosity, thus higher pressure is needed for fabrication of composite via RTM, which then increases the chance of fibre wash. However, this increased viscosity of resin is an advantage for RFI, as resin film can be easily cast.

10.2.4 Pultrusion:

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Figure 28. Schematic of pultrusion process Pultrusion138 is a continuous composite fabrication process, in which, composites are formed by pulling the reinforcement through heated closed die of required shape. Schematic representation of pultrusion process is shown in figure 28. Reinforcement in the form of either continuous rovings or fibre cloths is unrolled from creel and passes through resin tank, which saturates the fibre. These impregnated reinforcement is then guided to the hot die where the reinforcement shaped in to the desired profile, while simultaneous curing of resin due to heating139. Inbuilt cutter mechanism then cuts the composites profile in final shape. Some pultrusion systems also employ a pre-former to squeeze excess polymer before passing to hot die section. Thus in pultrusion process, a constant cross section profile of the composite product is produced on a continuous basis. Shivakumar et al.131-132, fabricated Cyanate esters

composite rod with carbon fibre using pultrusion technique and proposed its application for brush seals in gas turbine engines.

10.2.5 Filament winding (FW):

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Figure 29. Schematic of Filament winding process

In filament winding method, fibre strands are passed through resin tanks to impregnate the fibre completely. These impregnated fibre strands are then passed onto a rotating mandrel, where they get wound in a controlled manner and in a specific fibre orientation. The figure 29, shows the schematic of filament winding process. In this process, fibre tension is critical parameter because compaction is achieved through the fibre tension. Optimum fibre tension is required so as to avoid porosity in composite. At the same time, too high tension may break the fibre or initiate fibre fracture at the surface. Finally, curing of resin is done by heating in oven and final composite product is taken out from mandrel. For complex shapes, soluble plaster or collapsible rubber can be used for mandrel. This method is widely used for making pipes, pressure vessels, tanks, etc. Cyanate ester (PT resin) have been successfully filament winded for cylindrical structures (e.g. pressure bottles) and showed excellent properties at even high temperature (T~288°C)125. Esslinger et al.126, manufactured filament wound Cyanate esters composite structures for missile application and improvement in thermal performance is reported. Tian el al.127, studied property of carbon fibre laminate manufactured by wet filament winding process with epoxy/ Cyanate esters resin. They reported that, formed laminate composite has long service life characterized by standard 65 ACS Paragon Plus Environment

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vessel explosive test. Cyanate esters resin have also been used for filament winding of cylindrical structures and rings with carbon fibres125. Cui et al.128, used filament winding technique for epoxy and BMI modified Cyanate esters resin and reported that, formed composite has excellent strength and thermal stability. Comparison of all composite fabrication process are illustrated in table 8. Table 8: Comparison of composites fabrication techniques Fabrication techniques Resin transfer moulding

Autoclave moulding

Resin film infusion

Advantages

Disadvantages

1. Good surface finish on both side of the product surface 2. Higher production rate 3. Process can be manual control, semi-automated or highly automated 4. Uniform composite part thickness 5. Low emission during composite processing 6. Strict dimensional tolerances 7. High injection pressure is not required 8. Low material wastage due to near net shape parts fabrication

1. Mold cavity limits the size

1. Achieve high volume fraction of reinforcement 2. Minimal void content in the finished part due to removing entrapped air through vacuum 3. High degree of uniformity in part consolidation 4. Applicable for both thermoplastic and thermosetting polymer composites

1.

2. 3.

of the composite 2. High tooling cost 3. Matched tooling is

expensive and heavy in to withstand pressure 4. Generally limited to small size components 5. Possibility of unimpregnated areas

1. 2.

3.

Part size depend upon the autoclave size High cost of production Low rate of production

High fibre volumes can be 1. Not widely proven accurately achieved with low outside the aerospace void contents industry Potentially lower cost than 2. An oven and vacuum prepreg bagging system is Complex shaped parts can be required to cure the manufactured with ease component as for prepreg 66 ACS Paragon Plus Environment

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4. 5.

Local flow of resin insures complete wetting of fibres Suitable for filler/functional composites

Pultrusion

1. Low cost and automated process 2. Produces high quality of parts 3. High surface finish as compared to other composite processing methods 4. High rate of production as it is a continuous production process 5. High fibre volume fraction in the parts 6. Resin content can be accurately controlled. 7. Resin impregnation area can be enclosed thus limiting volatile emissions.

1. Suitable for constant cross sectional areas 2. Tapered and complex shapes cannot be produced 3. Control of fiber orientation is not possible 4. Thin wall parts cannot be produced 5. Limited to constant or near constant crosssection components. 6. Heated die costs can be high.

Filament winding

1. High strength to weight ratio in fabricated parts 2. High degree of uniformity in fiber distribution, orientation and placement 3. Labor involvement is minimal as it is an automated process 4. Design flexibility possible with the change in winding patterns, material and curing option 5. Size of the component is not restricted 6. High production volume 7. Process automation results in cost saving.

1. Capital investment is relatively high 2. Very precise control over the mechanism is required for uniform distribution and orientation of fiber 3. Composite product configuration be such that it should facilitate in mandrel extraction 4. Surface finish is poor 5. Fiber direction cannot be changed within one layer of winding.

10.3 Processing of fibres: Over a last few years, polymer nanofibers are being popular among researchers due to their wide applicability. They have been continuously studied for their use in filters, scaffolds, sensors, reinforcement in composite materials, protective clothing, etc.140 Most of

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thermosetting resin used in fibre reinforced composites suffer from poor delamination, fracture strength and poor impact resistance150. Recently, toughening of brittle matrix with interleaved nanofibers veils have been popular, due to their selective improvement in properties without degrading other mechanical properties151-153. Large number of studies on enhancement of toughness with interleaved nanofiber have been reported for fibre reinforced epoxy composites154-157. This approach can also be easily extended for Cyanate ester fibre reinforced composites. Conventional techniques such as drawing, template synthesis, phase separation, self-assembly and electrospinning have been used to form nanofibers. Due to its simplicity and higher efficiency, electrospinning is the most popular method used to form nanofibers. The drawback of low production volume of conventional electrospinning can be overcome by use of multi-needle electrospinning and needleless spinning, but on the expense of increase in production cost158. Other techniques such as centrifugal rotary spinning159-160, pressurized gyration161-162, force spinning163, and infusion gyration162, which utilizes centrifugal force to produce fibre are getting attraction over electrospinning, as they are largely independent on materials properties. Hong et al.164, in their recent study reported that, “pressure coupled infusion gyration” process as an effective alternative for electrospinning process. This technique uses both pressure and centrifugal force to produce fibres. It consists of the central vessel on which orifices are mounted at equidistance and driven by DC motor. Through syringe, polymer solution is infused into the bottom of vessel along with high pressure nitrogen gas to force solution through orifices. They demonstrated the process and reported that, 60-850nm diameter fibres were produced with poly(ethylene oxide) polymer solution. The major advantage with this technique is that, its yielding efficiency is very high along with low tooling cost.

11. Application of Cyanate ester composites:

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Enhanced mechanical properties of modified Cyanate esters resin make them a strong matrix material for advanced structural composites. Properties of Cyanate esters like, low moisture absorption156, high dimensional and thermal stability, excellent electrical properties, low flammability125, etc. make them a favourable matrices in composites, over conventional epoxy resins and other high temperature resins. High moisture absorption in any resin system has adverse effect on the performance of system, as it causes the change in dimension, reduces glass transition temperature, deteriorates the hot-wet performance of system and also causes micro-cracking46. Further, absorbed moisture causes an increase in dielectric constant of system, which then reduces the performance in applications such as radomes, radars, printed circuit boards, leading edges, etc. Cyanate esters absorb almost one-fourth as much of moisture absorbed by conventional epoxies4. Thus, use of Cyanate esters in one of these applications has an advantage of low moisture absorption, overcoming the above listed problems and thus improving the performance of the system4. In the next section, we have discussed various potential applications of Cyanate ester resins and their composites, which includes applications in primary structural composites, aero-space structures, electronic equipment’s, satellite components, etc. 11.1 Primary structural applications: Applications which have significant load bearing requirement and those are flight critical are termed as a primary structure157. In such applications, one of the major drawbacks of conventional material like epoxy is its brittle nature and high moisture absorption. Cyanate esters are inherently tougher than epoxies and thermoplastic toughened Cyanate esters blends results in phase separation, exhibiting high improved toughness of resin48. Also, high temperature performance of toughened system and solvent/chemical resistance are key advantages associated with the use of cyanate esters for structural applications125. One of the major requirement of resin in structural applications is the balance between damage tolerance

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and hot-wet performance. Thus, thermoplastic toughened Cyanate ester provides excellent balance between toughness and compressive strength, without degrading its creep and solvent resistant properties45,71. Such primary structural applications include, parts around aeroengines, tail assembly, air ducts in aircrafts, muffler system in high speed racing cars, rotor blades in helicopters, etc.64,125,158. Developing high speed missiles e.g. Mach 3, the temperature produced at the nose are high (T~500°C) and hence, high Tg Cyanate esters toughened with thermoplastic composites surpass over ceramic materials, due to their high short-term thermal stability, light weight and low production cost125. 11.2 Satellite/ Space application: Components used in satellite applications such as optical benches, reflectors, dimensionally stable platforms, etc. currently, uses high modulus graphite/epoxy composites157. However, high moisture absorption of epoxy system is the main drawback, which affects the performance of composites and are prone to micro-cracks when thermally cycled. Also, high outgassing of resin used in space applications is a major problem, as it can condense on optical and electronics components of system, thereby reducing their performance. Hence, low outgassing property of Cyanate ester is an another important advantage in satellite applications159-160 along with low moisture absorption and high dimensional stability. Cyanate esters have < 1% outgassing volatile loss and