38.2: Rotational Version of Hooke’s Law

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There is a rotational counterpart of Hooke's law:

\[\tau=-\kappa \theta\]

where \(\kappa\) is the spring constant, in units of \(\mathrm{N} \mathrm{m} \mathrm{rad}{ }^{-1}\). This version of Hooke's law applies to something like a torsional pendulum, in which a mass suspended by a wire is allowed to twist back and forth.

Couples

A couple is two forces, equal in magnitude and opposite in direction, but which are separated by some distance (Figure \(\PageIndex{1}\)). Since the two forces are equal and opposite, a couple results in zero net force on the body. However, it does result in a torque on the body. If the forces act along lines separated by a distance \(l\), then the torque \(\tau\) acting on the body due to the couple is given by

\[\tau=F l\]

Figure \(\PageIndex{1}\): A couple. The torque here is \(F x_{2}-F x_{1}=F\left(x_{2}-x_{1}\right)=F l\).

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