Studies of the Dilute Solution Conformational Dynamics of Styrene-diene Block Copolymers Via Linear Viscoelaticity and Oscillatory Flow Birefrigence, Volume 1 |
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Results 1-3 of 28
Page 27
... component of the velocity of the j bead j ( laboratory coordinates ) , x component of the velocity that the fluid would have at the position of j if the bead were absent ( laboratory coordinates ) x component of the force acting on the ...
... component of the velocity of the j bead j ( laboratory coordinates ) , x component of the velocity that the fluid would have at the position of j if the bead were absent ( laboratory coordinates ) x component of the force acting on the ...
Page 64
... component ( sin wt term ) is 90 ° out of phase ( recall that y = Y cos wt ) . Since An ( w ) is linear in ỷ for the ... component , and S " , the out of phase component , of S * w.r.t. y . Usually it has been found to be more useful to ...
... component ( sin wt term ) is 90 ° out of phase ( recall that y = Y cos wt ) . Since An ( w ) is linear in ỷ for the ... component , and S " , the out of phase component , of S * w.r.t. y . Usually it has been found to be more useful to ...
Page 128
... component in a block copolymer sample , but they cannot examine how each component is distributed spatially along the chain . Calculations have been performed for an A - B - A model symmetric triblock of N = NC ¶A = ac of N A = -1.5 ...
... component in a block copolymer sample , but they cannot examine how each component is distributed spatially along the chain . Calculations have been performed for an A - B - A model symmetric triblock of N = NC ¶A = ac of N A = -1.5 ...
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Studies of the Dilute Solution Conformational Dynamics of Styrene ..., Volume 2 Victor F. Man No preview available - 1984 |
Common terms and phrases
addition angle anisotropy appears approximation Aroclor bead-spring model beads birefringence block copolymer calculated changes characteristic coefficient Comparison component concentration const constant contribution coordinates correction curve dependence derived diene dilute dynamics effective eigenvalues elements Equation exact experimental expressions Figure flow frequency g/ml homopolymer hydrodynamic interaction identical important increasing laboratory length limit linear LIST matrix measured mechanically non-uniform mechanically uniform model chain modes modified molecular weight molecules motion non-zero normal observed obtained OFB properties OFB results optical optical weighting factors phase polarizability polydiene polymer polystyrene positive predictions presented ratio reference relaxation respectively segment selected shown shows solution solvent viscosity spring star submolecule subtraction symmetric triblock Table temperature theoretical curves THEORY treatment values various Wang