Processed polymers usually consist of multiple immiscible components such as pigments, fillers, and compounding agents. For complex polymeric mixtures an understanding of relative compatibility of components on a fundamental level is desirable. Such an understanding could help in the design of polymer compounds and in the control and prediction of behavior. For example, reinforcing fillers such as carbon black (CB) and silica are used in rubbers products. The reinforcing ability depends on the structure of the fillers, and the interaction between filler particles and the elastomer matrix. Aggregated fillers can be quantified by the specific surface area, the related primary particle size, the degree of graphitization for carbon, and the hydroxyl surface content for silica. A description of filler structure also includes the fractal aggregate structure that allows access to the surface through structural separation of primary particles. The fractal structure also contributes a static spring modulus to the composite at size scales larger than the filler mesh size for concentrations above the percolation threshold. Aggregates are often clustered in agglomerates that can be broken up during the elastomer milling process.
Fillers display different affinities for various polymers. This affinity is evidenced by their dispersability and their reinforcing properties in elastomer composites. Since fillers are often nanomaterials, standard characterizations of compatibility focus on the specific surface area. Surface area of fillers is usually measured by iodine adsorption (mg/g of filler), or nitrogen adsorption (m2/g of filler), or cetyltrimethylammonium bromide (CTAB) adsorption (m2/g of filler). The structure of fillers has been quantified using oil absorption (g/100 g of filler) or dibutyl phthalate (DBP) absorption (ml/100 g of filler) for CB, as well as through a variety of surface characterization techniques such as determination of the surface hydroxyl content for silica, and the degree of graphitization for carbon black. In addition, techniques have been applied to study compatibility of filler in the rubber matrix by investigating surface and aggregate structure. Atomic force microscopy (AFM) and small angle x-ray scattering (SAXS) have been used to study surface structure and fractal dimension of CB. Scanning electron microscopy (SEM) and transmission electron microscopy (TEM) were used to study particle size and morphology of aggregates.
A method of preparing a blended mixture, the method including mixing an elastomer and a filler to form a test blended mixture; measuring a second virial coefficient, A2 of the test blended mixture; comparing the measured second virial coefficient of the test blended mixture to a threshold value for a production blended mixture; wherein if the measured second virial coefficient of the test blended mixture is higher than the threshold value for a production blended mixture, further preparing a final blended mixture by mixing additional elastomer and filler.
A method of preparing a blended mixture, the method including mixing an elastomer and a filler to form a blended mixture; measuring a second virial coefficient, A2 of the blended mixture; comparing the measured second virial coefficient of the blended mixture to a reference second virial coefficient value for a combination of the elastomer and the filler; wherein if the measured second virial coefficient of the blended mixture is lower than the reference second virial coefficient, further mixing the blended mixture to form a dispersed blended mixture.
A method of preparing a blended mixture, the method including selecting an elastomer and filler from a reference elastomer/filler combination having a reference second virial coefficient, A2 greater than 5 cm3/g2; mixing the elastomer and the filler to form a blended mixture; measuring a second virial coefficient, A2, of the blended mixture; and optionally further mixing the blended mixture until the blended mixture has a measured second virial coefficient greater that the reference second virial coefficient.
Silica is the traditional reinforcing filler for polydimethylsiloxane elastomers due to compatibility in chemical structure. Silica was introduced as a reinforcing filler for diene elastomers for tires in the 1990's and showed a lower rolling resistance and higher fuel efficiency compared to carbon black reinforcing filler. However, silica is very different compared to CB due to its strong polar and hydrophilic surface. A certain quantity of moisture can be adsorbed on silica surface making it difficult to remove. Inter-particle interaction of silica due to hydrogen bonding needs to be considered since it reduces the compatibility of silica and rubber.
The compatibility of colloidal solutions such as mixtures of miscible polymers, solutions of low molecular weight organics and inorganics, and biomolecules is often quantified using a virial expansion to describe the concentration dependence of the osmotic pressure. This approach assumes that molecular and nanoscale motion is governed by thermally driven diffusion with a molecular energy of kT. Elastomer/reinforcing filler compounds have not been considered colloidal mixtures since the materials are highly viscous or solid networks, so thermally driven motion of reinforcing filler aggregates is not expected in an elastomer composite. However, the second virial expansion approach can be used in viscous systems such as in polymer melts where Flory-Huggins theory is applied, a form of the virial expansion for macromolecules. The virial coefficient is also used in native state protein solutions where rigid protein nanostructures are considered. The quantification of compatibility using a pseudo-virial approach may be of value in reinforced elastomer systems and potentially in a number of other similar systems where an analogy can be considered between randomly placed filler aggregates dispersed in the milling process and randomly placed molecules dispersed by thermal motion. In this analogy, it is assumed that the mixture has reached a terminal state of dispersion, or at least a relative state of dispersion when comparing different processing conditions and materials. In this pseudo-thermodynamic approach, processing time, accumulated strain, matrix viscosity all can have an equivalence to temperature in a true thermodynamic system.
In colloidal mixtures the miscibility of a binary system can be considered in terms of the second virial coefficient. For instance, protein precipitation from solution in the process of protein crystallization has been predicted using the second virial coefficient. The virial expansion is used to describe deviations from ideal osmotic pressure conditions, π=ϕnumRT, to a power series expansion,
where ϕ is the number density of particles or molecules. B2 indicates the enhancement of osmotic pressure due to binary interactions of a colloid in a matrix in terms of the thermal energy, kT. B2 is related to an integral of the interaction energy between particles. Such a binary interaction energy can be used as an input to computer simulations of polymer/filler mixing. B2 could also be used to quantify filler/polymer interactions in the prediction of mechanical and dynamical mechanical performance. If trends in B2 can be determined as a function of chemical composition of an elastomer matrix or surface-active additives, then these values could be used to predict the performance of new compositions for enhanced performance. In this study a binary compound could be considered a polymer and miscible additives such as oil/plasticizer and processing aids, making up the matrix phase, mixed with an immiscible additive such as a reinforcing filler.
A parallel definition of the second virial coefficient using the mass density concentration, ϕmass, rather than the number density concentration, ϕnum, is possible,
where M is the molecular weight of a particle. ϕmass=Mϕnum/Na, where Na is Avogadro's number, and A2=B2Na/M2, following Bonneté et al. B2 is related to the binary interaction potential for particles, U(r), by,
B2 has units of cm3/particle, and A2 has units of mole cm3/g2. If a hard core potential is assumed, then the hard core radius, σHC, is given by,
σHC should be a size scale on the order of the size of an aggregate.
The second virial coefficient can be used to predict stability and compatibility of elastomer/filler systems, especially when coupled with DPD (dissipative particle dynamics) simulations. A typical repulsive potential for a DPD system is of the form,
where σ is the diameter of the aggregates, here the end to end distance Reted is used, and A is a dimensionless binary short range repulsive amplitude that can be defined for particle interactions. Equation (5) can be used in equation (3) and numerically solved for “A” using B2. “A” could be used to simulate the behavior of a filler in an elastomer matrix to determine the segregation of filler in a polymer blend.
Scattering data from carbon black reinforced elastomer composites was fit using the unified scattering function with four structural levels. First a unified function for the mass fractal aggregates was used with three structural levels, equation 6,
where level 0 pertains to a graphitic layer, level 1 to the primary particles and level 2 the aggregate structure. Level 0 does not exist for silica. The subscript “I0” in equation (6) refers to dilute conditions or isolated fractal aggregates in the absence of screening. For each structural level the unified function uses four parameters to describe a Guinier and a power-law decay regime. For the smallest scale a graphitic layer, level 0, can be observed with a power-law decay of −2 slope for 2d graphitic layers, which can have a lateral dimension of about 15 Å. Level 1 pertains to the primary particles of the aggregates, which can have a radius of gyration of about 170 Å. The primary particles form aggregates, level 2, can have a mass fractal dimension of about 2.1, and the aggregates can have a radius of gyration of about 2,200 Å.
From the scattering fitting parameters several calculated parameters can be obtained. For the primary particles, the Sauter mean diameter, dp, and a polydispersity index, PDI, can be obtained and from these values the log-normal geometric standard deviation, σg, and the geometric mean value of size, μ can be determined. For the fractal portion of the scattering curve the minimum dimension, dmin, connectivity dimension, c, mole fraction branching, ϕBr, degree of aggregation, DOA, aggregate polydispersity, Cp, and average branch length, zBr, can be obtained. The end to end distance, used for σ in equation 5, can be calculated from,
Reted˜dpP1/d
The interaction between filler and elastomer can be modeled using the random phase approximation, RPA,
where ϕw is the weight fraction, and ν is related to the second virial coefficient by,
In addition to the mass fractal structure and screening (equations (6) and (8)),
where B3 is the power-law prefactor for the lowest-q agglomerate structure. The agglomerate scattering is observed to be independent of the screening effect of equation 8.
Samples were milled in a 50 g Brabender mixer at 130° C. with a rotor speed of 60 rpm for 6 min until the torque versus time curve had dropped from a peak value and reached a plateau. Table 1 shows the 15 sample types for three elastomers filled with five fillers. Each type was studied with four concentrations of 1, 5.6, 15.1 and 29.9 wt. %. PB2 was provided by Bridgestone Americas, while newPB and PI were obtained from Sigma Aldrich. CB110 and CB330 were from Continental Carbon and CRX2002 from Cabot. SiO2190 was from PPG and SiO2130 was from Evonik. Measurements were performed at the Advanced Photon Source, Argonne National Laboratory using the Ultra-Small-Angle X-ray Scattering (USAXS) facility located at the 9 ID beam line, station C.
The scattering pattern at 1 wt. % reflects the structure of CB aggregates. The carbon black includes four levels of structure. Level 0 pertains to the graphitic structure observed above q=0.02 Å−1. The graphitic level displays a power-law −2 for the 2d structure. From about 0.008 to 0.02 Å−1 the primary particle structure is observed, level 1. This level displays smooth sharp surfaces and a power-law decay of −4 slope following Porod's law. From 0.0008 to 0.008 Å−1 the fractal aggregate, level 2, is observed with a power-law decay reflecting −df for the aggregate. At the lowest q, steep power-law decay is observed reflects surface scattering from a large-scale structure of agglomerates of CB aggregates or from defects in the samples. The power-law decay varies between mass fractal and domain structures. Only scattering from the dispersed aggregates component of the structure is considered for the determination of A2. Screening in equation (8) only effects levels 0 to 2 since the large-scale super-structure, level 3, is under dilute conditions. At higher concentrations fits to only levels 1 to 2 are considered since the graphitic structure of CB does not change.
To obtain values for ν
The pseudo-second order virial coefficient, A2, in binary milled compounds is obtained from the rate of dampening of the mid-q data in
Samples are marked as “SC” in Table 4 and 5 indicating an aggregate structural change at higher concentrations.
The second virial coefficient is an indication of miscibility with larger values indicating greater affinity in a binary mixture. It is observed that mixing of finer particulate fillers is more difficult than coarser fillers.
Of the three types of polymers PI, triangles in
The concentration series shown in
The percolation concentration of carbon black filled samples is usually measured by bulk conductivity, for example, it can be observed at concentrations in the range of 25 to 30 weight percent. Conductivity measurement quantifies the first point where a conductive pathway exists across millimeters of sample. The scattering overlap concentration reflects local percolation of the structure. Micrographs of the filled samples in Figures show such local percolation.
The percolation concentration follows the fractal scaling law so that c*˜M/V=Rg2df/(Rg23)˜Rg2df−3.
For filled elastomers with filler loading above the overlap concentration (percolation threshold) the filler particles form a network with a mesh size that decreases with increasing concentration, as shown in the drawings in
Immiscible mixtures of nano to colloidal particles in polymers show some resemblance to colloidal solutions. While colloidal solutions have a random dispersion of particles driven by dynamic thermal equilibrium and are influenced by enthalpic interactions between particles, polymer mixtures display a random dispersion of particles driven by the mixing process and influenced by surface interactions between particles. The effectiveness of mixing will depend on particle size, accumulated strain, viscosity of the matrix polymer and the hydrodynamic properties of the nanoparticles being dispersed. A pseudo-thermodynamic approach to these systems can be used to quantify the compatibility of a given nanoparticle and polymer binary pair. This approach can be used to rate different polymer/nanoparticle pairs as to relative compatibility. Reinforced elastomer composites were examined using this new application of the second virial coefficient to describe compatibility of carbon black and silica with three different elastomers. It was found that this approach distinguishes compatibility for different elastomer/filler compounds. Ultra small-angle x-ray scattering was used to measure the scattering pattern at several concentrations of filler. Changes in scattering with concentration were described with a single second virial coefficient for each elastomer using a scattering function related to the random phase approximation. The approach can be applicable to a wide range of nano composite materials.
The pseudo-second virial coefficient, A2, was well behaved in the PB/PI and CB/SiO2 compounds that were studied. A close to linear dependence of A2 with primary particle size agrees well with the observation that it is more difficult to mix smaller particles. The interfacial contribution to this compatibility could be ascertained by the sign and value of the dp=0 intercept.
Values for the repulsive interaction potential amplitude, “A” were estimated for the samples from the A2 values and calculations of Reted. These values could be used in coarse grain computer simulations of filler segregation in these elastomers. The percolation threshold concentration and the mesh size for concentrations above overlap were determined. Both of these features are well behaved in the samples studied.
The present disclosure is a novel description of compatibility in polymer compounds that is useful in predicting compatibility in complex mixed systems, for example, systems based on processing history and tabulated values for A2. The approach is versatile and can be applied to pigment dispersions and many other polymer/nanoparticle compounds.
This application is a continuation of U.S. application Ser. No. 17/150,465, filed on Jan. 15, 2021, which is a continuation of U.S. application Ser. No. 16/584,047, filed Sep. 26, 2019, which is a continuation of U.S. application Ser. No. 15/809,204, filed Nov. 10, 2017, which claims priority to U.S. Provisional Application No. 62/420,131, filed Nov. 10, 2016, all of which are incorporated by reference herein in their entirety.
Number | Date | Country | |
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62420131 | Nov 2016 | US |
Number | Date | Country | |
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Parent | 17150465 | Jan 2021 | US |
Child | 18133301 | US | |
Parent | 16584047 | Sep 2019 | US |
Child | 17150465 | US | |
Parent | 15809204 | Nov 2017 | US |
Child | 16584047 | US |