Transcript Larson
BEGIN BEGIN DISCOVERIES DISCOVERIES WHERE WHERE Foundation Foundation Science Science National National Controlling Polymer Rheological Properties Using Long-Chain Branching PI: Ronald Larson Univ. of Mich., Dept of Chem. Eng., Macromolecular Science and Engineering Program Possible co-PI: Michael Solomon Univ. of Mich., Dept of Chem. Eng., Macromolecular Science and Engineering Program Possible co-PI: Jimmy Mays Univ. of Tennessee, Dept of Chemistry WHERE DISCOVERIES BEGIN National Science Foundation Industrial Relevance “The flow behavior (‘rheology’) [of polymers] is enormously sensitive to LCB [long chain branching] concentrations far too low to be detectable by spectroscopic (NMR, IR) or chromatographic (SEC) techniques. Thus polyethylene manufacturers are often faced with ‘processability’ issues that depend directly upon polymer properties that are not explainable with spectroscopic or chromatographic characterization data. Rheological characterization becomes the method of last resort, but when the rheological data are in hand, we often still wonder what molecular structures gave rise to those results.” Janzen and Colby, J. Molecular Structure, 1999 Innovation through Partnerships 2 6 10 5 10 4 10 G' (Pa) WHERE DISCOVERIES BEGIN National Science Foundation Rheology, Processing and LongChain Branching TM AFFINITY PL1880 PL1880_80 PL1880_60 PL1880_40 PL1880_20 PL1880_05 PL1880_02 Exact 3128 3 10 2 10 1 10 -2 10 -1 10 0 10 (rad/s) 1 10 2 10 < 1 LCB’s per million carbons significantly affects rheology! branched polymers branched thread-like micelles Innovation through Partnerships 3 WHERE DISCOVERIES BEGIN National Science Foundation Project Goals • Develop industrially useful tools for inferring long-chain branching levels from rheology • Develop optimization strategies for improving processing and product properties through control of long-chain branching • Provide software tools and training as needed for industrial applications Innovation through Partnerships 4 WHERE DISCOVERIES BEGIN National Science Foundation Objectives & Research Methods • Measure rheology of commercial polymers • Combine this with conventional characterization by SEC, light scattering, and knowledge of reaction kinetics • Use “Hierarchical model”, a computational tool, to determine a long-chain branching profile of commercial polymers. • Determine how changes in the long-chain branching profile could alter rheological properties in desirable ways. Innovation through Partnerships 5 WHERE DISCOVERIES BEGIN National Science Foundation Hierarchical Model comb H star linear Relaxation of each molecule is tracked in the time domain, as it relaxes from the tips of the branches, inwards towards the backbone. At long times, branches act as drag centers, slowing down motion of the branch or backbone to which they are attached. The contributions of all molecules in the ensemble to the rheology are combined, and converted to the frequency domain to predict G’ and G’’. • A complex commercial branched polymer is represented by an ensemble of up to 10,000 chains. • This ensemble represents the range of branching structures and the molecular weight distribution of the commercial polymer. •The ensemble is generated from a combination of GPC characterization, knowledge of reaction kinetics, and rheology. •The ensemble is fed into the “Hierarchical Code,” and a prediction of the linear rheology (G’ and G”) emerges. Larson et al., (2001, 2006, 2011) Das, Inkson, Read, Kelmanson, J. Rheol. (2006) Titration s-BuLi Butadiene Example 1: Characterization of Anionically Synthesized “H” Polymer Cl WHERE DISCOVERIES BEGIN National Science Foundation Li Si Si Cl CH3 CH3 (CH3)2SiCl2 Li Linear Mw/Mn =1.01 Star Mw/Mn =1.03 H Mw/Mn =1.07 Synthesized by Rahman and Mays WHERE DISCOVERIES BEGIN National Science Foundation Chemically Likely Structures Unfractionated Star Fractionated H 22 114k 54.8k 32 30 21 28 95k 22 129k o n (a.u.) 24 20 Mw 38.5k 71k 18 73.6k T ( C) 19 n (a.u.) 26 20 o WHERE DISCOVERIES BEGIN Using TGIC: Temperature Gradient Interaction Chromatography T ( C) National Science Foundation Identification of Structures 18 16 0 5 10 15 20 tR (min) Star (SemiH): H: 25 30 17 35 0 5 10 15 20 25 14 30 tR (min) TGIC from Hyojoon Lee and Taihyun Chang Fractionated H 22 114k 54.8k 32 30 21 28 95k 22 129k o n (a.u.) 24 20 Mw 38.5k 71k 18 73.6k 18 16 0 5 10 15 20 tR (min) Star (SemiH): H: 25 30 17 35 0 5 10 15 20 T ( C) 19 n (a.u.) 26 20 o WHERE DISCOVERIES BEGIN Unfractionated Star T ( C) National Science Foundation Identification of Structures 25 14 30 tR (min) TGIC from Hyojoon Lee and Taihyun Chang 1.E+06 1.E+05 H 1.E+04 G', G'' (Pa) WHERE DISCOVERIES BEGIN National Science Foundation Comparisons of theoretical predictions and experimental measurements Xue Chen 1.E+03 Star (semi-H) 1.E+02 1.E+01 blend Me=1620,Gn0=1.095MPa, tau_e=5E-7 from Chen, Rahman, Mays, Lee, Chang, Larson 1.E+00 1.E-04 1.E-03 1.E-02 1.E-01 1.E+00 1.E+01 1.E+02 1.E+03 1.E+04 11 Freq (rad/s) National Science Foundation WHERE DISCOVERIES BEGIN 12 Example 2: Blends of Linear Exact 3128 and Branched PL1880 Polyolefins Sample name AFFINITY™ PL 1880 PL1880_80 PL1880_60 PL1880_40 PL1880_20 PL1880_05 PL1880_02 Exact 3128 AFFINITY™ PL1880 (branched) Exact LCB 3128 (n/1000C) (linear) nc Mw (kg/mol) 100% 0% 0.0177 0.0482 116 80% 60% 40% 20% 5% 2% 100% 20% 40% 60% 80% 95% 98% 0% 0.0142 0.0106 0.00709 0.00355 0.000887 0.000355 0 0.0502 0.0521 0.0541 0.0560 0.0575 0.0578 0.0580 116 116 116 115 115 115 115 X.Chen, C. Costeux, R. Larson. J. of Rheology 54(6) 1185-1206, 2010 6 10 T=150C 5 10 4 10 G' (Pa) WHERE DISCOVERIES BEGIN National Science Foundation Rheology of Blends of Linear Exact 3128 and Branched PL1880 Polyolefins Increasing LCB TM AFFINITY PL1880 PL1880_80 PL1880_60 PL1880_40 PL1880_20 PL1880_05 PL1880_02 Exact 3128 3 10 2 10 0.3 LCB’s per million carbons! 1 10 -2 10 13 -1 10 0 10 (rad/s) 1 10 2 10 Algorithm for Monte Carlo simulation of LCB PE using single-site catalyst Reaction kinetics of LCB PE using single-site catalyst WHERE DISCOVERIES BEGIN National Science Foundation Generating an Ensemble of Chains for a Commercial Single-Site Metallocenes k Px,n + M ¾ ¾p ® Px+1,n Start monomer addition = Px,n + Dy,m ¾ k¾LCB ¾ ® Px+y,n+m+1 Generate random number R: U(0,1) addition of unsaturated chain + CTA Px,n + CTA ¾ k¾ ¾ ® Dx,n + P1,0 NO Propagation generation of dead structured chain = Px,n ¾ ¾b ® Dx,n + P1,0 YES R>pp Termination k Generate random number R: U(0,1) -hydride elimination NO Monte Carlo probabilities pp = Rp + RLCB Rp + RLCB + RT propagation probability lp = Rp R>lp Add monomer Save molecule YES Add macromonomer Rp + RLCB monomer selection probability Costeux et al., Macromolecules (2002) 8 8 10 7 10 10 TM AFFINITY 7 10 PL1880 G' & G'' (Pa) 6 10 5 5 10 10 4 4 10 10 3 10 3 PL1880_80 10 2 1 1 10 -2 10 8 10 8 10 7 PL1880_20 1 10 2 10 PL1880_02 6 10 5 5 10 4 4 10 10 3 3 10 PL1880_05 2 10 Exact3128 2 10 10 1 15 0 10 10 10 10 -2 10 -1 10 7 10 6 PL1880_40 2 10 10 10 PL1880_60 6 10 10 G' & G'' (Pa) WHERE DISCOVERIES BEGIN National Science Foundation A Priori Predictions of Commercial Branched Polymer Rheology 1 -1 10 0 10 (rad/s) 1 10 10 2 -2 10 10 -1 10 0 10 (rad/s) 1 10 2 10 WHERE DISCOVERIES BEGIN National Science Foundation Outcomes/Deliverables • Measurements of rheological properties of commercial polymers • Measurement of SEC curves for select commercial polymers • Computer software and training for predicting rheological properties • Assessment of impact of changing • branching structure on rheology Innovation through Partnerships 16 WHERE DISCOVERIES BEGIN National Science Foundation Impact • Improved ability to design and control polymer processing properties • Ability to infer likely branching characteristics from rheology • Develop methods of extracting “hidden” features of molecular structure through rheology of samples blended with simpler linear polymers Innovation through Partnerships 17 WHERE DISCOVERIES BEGIN National Science Foundation Project Duration and Proposed Budget • 1-4 years, depending on polymer to be tackled, number of samples to be studied, availability of industrial data, such as GPC data, and the solvents/conditions required for characterization • Budget: $75,000/year Innovation through Partnerships 18