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DISPERSION NUCLEATING--EFFECTS OF POLYMER NANOCOPMPOSITES

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Arjun K Gopi
Arjun K Gopi

DISPERSION NUCLEATING--EFFECTS OF POLYMER NANOCOPMPOSITES

Science
1 of 13
AMRUTHA K S 2ND M.Sc BPS CBPST, KOCHI
Introduction  While large surface-to-volume ratio of nanoparticles makes them superior reinforcements over conventional fillers, it also brings difficulties in dispersing the nanoparticles due to their strong interactions among themselves. Due to these inter nanoparticle interactions, it is extremely difficult to disperse nanoparticles uniformly, specially at higher particle loadings.  Several processing methods including shear mixing, mechanical mixing, in-situ polymerization and sonication have been used for dispersing nanoparticles in polymers.
Effect of Dispersion at High Particle Loadings  In shear mixing and sonication to disperse montmorillonite clay nanoparticle into vinyl ester resin. The clay nanoparticle loading was 3-8% by weight. The compressive results of clay modified resin showed that the resin with 5% nanoclay exhibited a reasonable improvement in compressive strength and a considerable (20%) improvement in modulus.  However the mechanical properties, especially strength, tended to go down when nanoclay was loaded beyond 5 wt%.
 16% improvement in tensile strength and 90% improvement in tensile modulus were reported at 5wt% loading of fillers 3wt% 5wt% 8wt%
 Epoxy matrix modified with modified with silica nanoparticles (up to 14 vol%) via sol-gel method enhanced the mechanical properties of polymer nanocomposites such as modulus, microhardness, and fracture toughness. It is therefore reasonable to say that the sol-gel method can be used to produce well dispersed high nanoparticle loading nanocomposites with much improved mechanical properties.
Dispersion of Particles of Different Sizes  While particle dispersion plays the foremost role in enhancing polymer’s properties.  it is also greatly influenced by the size of particles. Smaller particles have higher surface area (at same particle volume fraction) and,  Hence, greater surface interactions among the particles. This is what makes the dispersion of nanoparticles harder.  Nanocomposites show increase in modulus with the decrease in particle size that leads to dispersion more difficult.
Nucleation  In polymer technology, especially for injection molding the desired high crystallization rates often require the addition of nucleating agents.  A nucleating agent is substance that forms nuclei for the growth of crystals in super cooled polymer melt. virtually ay solid body with a high energy surface may act as a nucleating agent closely matches the crystallization surface of polymer.  The nucleating agent may preferably induce a crystallographic form of the polymer. for e.g., addition to isotactic PP of either 1,2,34-bis(3,4-dimethyl-benzylidene sorbitol) or N,N’- dicyclohexyl-2,6-naphthalate dicarboxamide, preferably generate a-iPP or b-iPP, respectively
 The nucleating efficiency depends on several independent variables, such as temperature,pressure,stress,part thickness as well as the presence of the other processing additives  An efficient nucleating agent must have a high-energy surface-the large the specific surface ,the more efficient it is expected to be.  Nucleation involves initial adsorption of macromolecules on the surface. the process is particularly efficient if the foreign body is able to provide a energetic matrix for the formation of thermodynamically favorable crystalline forms.
 Alternatively, the crystalline cell type ad size of the nucleating agent may induce a transitory crystalline polymer forms that upon annealing transforms into a stable form of higher packing density  The nucleating efficiency may be expressed in terms of the energy ratio required to generate a nucleus in a heterogeneous nucleation over that in a homogenous one.  The nucleation is the rate determine step, while the extend of crystallinity is constant. Thus the nucleation rate ,r , depends on the degree of super cooling ,
Where,  Em is the energy required to form a nucleus ,  is a geological factor ,  is the specific surface energy ,  Vm is the molar volume of the crystalline substance.  is the melting entropy,  n is the Avrami exponent and  kb is the Boltzmann constant.
Nanofillers such as clay may have high nucleating effect. The wide variety of intercallatants,intercalating methods and compatibilisers may form a barrier between high energy clay surface and semicrystaline polymer matrix.
DISPERSION NUCLEATING--EFFECTS OF POLYMER NANOCOPMPOSITES

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DISPERSION NUCLEATING--EFFECTS OF POLYMER NANOCOPMPOSITES

  • 1. AMRUTHA K S 2ND M.Sc BPS CBPST, KOCHI
  • 2. Introduction  While large surface-to-volume ratio of nanoparticles makes them superior reinforcements over conventional fillers, it also brings difficulties in dispersing the nanoparticles due to their strong interactions among themselves. Due to these inter nanoparticle interactions, it is extremely difficult to disperse nanoparticles uniformly, specially at higher particle loadings.  Several processing methods including shear mixing, mechanical mixing, in-situ polymerization and sonication have been used for dispersing nanoparticles in polymers.
  • 3. Effect of Dispersion at High Particle Loadings  In shear mixing and sonication to disperse montmorillonite clay nanoparticle into vinyl ester resin. The clay nanoparticle loading was 3-8% by weight. The compressive results of clay modified resin showed that the resin with 5% nanoclay exhibited a reasonable improvement in compressive strength and a considerable (20%) improvement in modulus.  However the mechanical properties, especially strength, tended to go down when nanoclay was loaded beyond 5 wt%.
  • 4.  16% improvement in tensile strength and 90% improvement in tensile modulus were reported at 5wt% loading of fillers 3wt% 5wt% 8wt%
  • 5.  Epoxy matrix modified with modified with silica nanoparticles (up to 14 vol%) via sol-gel method enhanced the mechanical properties of polymer nanocomposites such as modulus, microhardness, and fracture toughness. It is therefore reasonable to say that the sol-gel method can be used to produce well dispersed high nanoparticle loading nanocomposites with much improved mechanical properties.
  • 6. Dispersion of Particles of Different Sizes  While particle dispersion plays the foremost role in enhancing polymer’s properties.  it is also greatly influenced by the size of particles. Smaller particles have higher surface area (at same particle volume fraction) and,  Hence, greater surface interactions among the particles. This is what makes the dispersion of nanoparticles harder.  Nanocomposites show increase in modulus with the decrease in particle size that leads to dispersion more difficult.
  • 7.
  • 8. Nucleation  In polymer technology, especially for injection molding the desired high crystallization rates often require the addition of nucleating agents.  A nucleating agent is substance that forms nuclei for the growth of crystals in super cooled polymer melt. virtually ay solid body with a high energy surface may act as a nucleating agent closely matches the crystallization surface of polymer.  The nucleating agent may preferably induce a crystallographic form of the polymer. for e.g., addition to isotactic PP of either 1,2,34-bis(3,4-dimethyl-benzylidene sorbitol) or N,N’- dicyclohexyl-2,6-naphthalate dicarboxamide, preferably generate a-iPP or b-iPP, respectively
  • 9.  The nucleating efficiency depends on several independent variables, such as temperature,pressure,stress,part thickness as well as the presence of the other processing additives  An efficient nucleating agent must have a high-energy surface-the large the specific surface ,the more efficient it is expected to be.  Nucleation involves initial adsorption of macromolecules on the surface. the process is particularly efficient if the foreign body is able to provide a energetic matrix for the formation of thermodynamically favorable crystalline forms.
  • 10.  Alternatively, the crystalline cell type ad size of the nucleating agent may induce a transitory crystalline polymer forms that upon annealing transforms into a stable form of higher packing density  The nucleating efficiency may be expressed in terms of the energy ratio required to generate a nucleus in a heterogeneous nucleation over that in a homogenous one.  The nucleation is the rate determine step, while the extend of crystallinity is constant. Thus the nucleation rate ,r , depends on the degree of super cooling ,
  • 11. Where,  Em is the energy required to form a nucleus ,  is a geological factor ,  is the specific surface energy ,  Vm is the molar volume of the crystalline substance.  is the melting entropy,  n is the Avrami exponent and  kb is the Boltzmann constant.
  • 12. Nanofillers such as clay may have high nucleating effect. The wide variety of intercallatants,intercalating methods and compatibilisers may form a barrier between high energy clay surface and semicrystaline polymer matrix.