Physical Chemistry Third Edition

(C. Jardin) #1

28.9 Rubber Elasticity 1201


after polymerization. Natural rubber has thecisconfiguration at each of these bonds.
A portion of the structural formula for a rubber molecule is (hydrogens have been
omitted):

C

C

C

C C

C
C

C

C C

C
C

C

C C

C
C

v

C

C

Natural rubber is a sticky, semifluid substance. In 1839, after 10 years of trial-and-error
experimentation in his kitchen, Charles Goodyear inventedvulcanization, a process in
which sulfur is reacted with natural rubber. In this process, sulfur reacts with double
bonds in two adjacent chains, forming short chains of sulfur atoms between the polymer
chains, producing a more nearly solid and elastic product than natural rubber. The extent
of this cross-linking and the presence of various additives such as “carbon black” (finely
powdered carbon) determine the physical properties of the rubber. Vulcanized rubber
can be made in varying degrees of hardness, from flexible rubber like that in inner
tubes, through the less flexible rubber used in tires, to the hard rubber used in combs.

Charles Goodyear,1800–1860,wasan
Americaninventor whose patentwas
widely infringedupon,andwhodiedin
debt.


Before 1955, various synthetic rubbers were invented, but were found to be inferior
to natural rubber. It was possible to make polyisoprene, but the double bonds were in a
random mixture of thecisandtransconfigurations. In 1955, catalysts were developed
that can produce a synthetic rubber that is identical to natural rubber, and automobile
tires made of synthetic rubber are now common.^42

The Thermodynamics of Rubber


A piece of vulcanized rubber is not a simple system in the thermodynamic sense,
because work other than compression work can be done on it. When it is stretched
reversibly, the total work in an infinitesimal displacement is given by

dw−PdV+fdL (28.9-1)

whereLis the length of the piece of rubber andfis thetension force.
It is found experimentally that the stretching of a rubber object approximately obeys
three properties: (1) the volume remains constant; (2) the tension force is proportional
to the absolute temperature; and (3) the energy is independent of the length at constant
temperature. Anideal rubberexactly conforms to these three properties. Since the
volume is constant, the first term on the right-hand side of Eq. (28.9-1) vanishes for an
ideal rubber. For reversible processes in a closed system made of ideal rubber, the first
and second laws of thermodynamics give the relation:

dUdq+dwTdS+fdL (ideal rubber) (28.9-2)

We define an enthalpy-like variable,K

KU−fL (definition) (28.9-3)

(^42) J. Nattaet al.,J. Am. Chem. Soc., 77, 1708 (1955); K. Ziegleret al.,Angew. Chem., 67 , 426 (1955a).
See the Macrogalleria website (http://www.pslc.usm.edu/macrog) to view an animation of this catalytic
action.

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