- Diluent or plasticizer. The mixture of polymer (labeled with the subscript p)
and diluent (labeled with the subscript d) can be regarded as a polymer solution
system. The expansion coefficient of free volume is af. Assuming the
contributions of each component in the system to the free volume are propor-
tional to their volume fractionf, one can obtain according to the equivalence
phenomenon of free volume
afpðTgTgpÞfpþafdðTgTgdÞfd¼ 0 (6.72)Two contributions compensate to each other, andfpþfd¼1; thereforeTg¼afpfpTgpþafdfdTgd
afpfpþafdfd(6.73)
Ifafpafd,(6.73) can be simplified asTg¼fpTgpþfdTgd (6.74)Replacing the volume fractions above with weight fractions, one obtains the
so-called Wood Equation, which is often used for random copolymer systems
(Wood 1958 ).
IfTgpafpTgdafd,(6.73) can be simplified as1
Tg¼
fp
Tgpþfd
Tgd(6.75)
Replacing the above volume fractions with weight fractions, one obtains the so-called
Fox Equation, which is often used for polymer-diluent mixtures (Fox 1956 ).- Random copolymer. Considering the mass fractionsWAandWBproportional to
the contributions of free volume, according to the equivalence phenomenon of
free volume,
afAðTgTgAÞWAþafBðTgTgBÞWB¼ 0 (6.76)AssumingK¼afB/afA,Tg¼
TgAþðKTgBTgAÞWB
1 þðK 1 ÞWB(6.77)
This equation is known as Gordon-Taylor equation (Gordon and Taylor 1952 ).- Cross-linking. The cross-links restrict the mobility of network chains. Thus,
Tgrises with the crosslink densityr(crosslink points per gram) (Ueberreiter and
Kanig 1950 ; Fox and Loshaek 1955 ),
6.3 Glass Transition and Fluid Transition 117