The given data can be listed below as,

• The length of wire is, \(L = 80.0\;{\rm{cm}} = 0.80\;{\rm{m}}\).
• The frequency is, \(f = 60\;{\rm{Hz}}\).

 To determine the velocity, first apply the equation for wave velocity and substitute fundamental wavelength in terms of wire length.

The relation between frequency, wavelength, and speed is expressed as,

\(f=\frac{v}{\lambda}\)                …(2)

Here \(\lambda \) is the wavelength, \(f\) is the frequency, and \(v\) is the speed of wave.

The fundamental standing wave is illustrated in the below figure,

From the figure,

\(\begin{array}{c}\frac{\lambda }{2} = L\\\lambda  = 2L\end{array}\)

Substitute \(0.80\;{\rm{m}}\) for \(L\) in the above equation.

\(\begin{array}{c}\lambda=2\times0.80\;{\rm{m}}\\\lambda=1.60\;{\rm{m}}\end{array}\)

The wavelength is, \(\lambda  = 1.60\;{\rm{m}}\).

Substitute \(1.60\;{\rm{m}}\) for \(\lambda \) and \(60\;{\rm{Hz}}\) for \(f\) in the equation (1).

\(\begin{array}{c}60\;{\rm{Hz}} = \frac{v}{{1.60\;{\rm{m}}}}\\v = 60\;{\rm{Hz}} \times 1.60\;{\rm{m}}\\v = 96.0\;{{\rm{m}} \mathord{\left/ {\vphantom {{\rm{m}} {\rm{s}}}} \right. \\} {\rm{s}}}\end{array}\)

Hence the speed of propagation of transverse waves in the wire is, \(96.0\;{{\rm{m}} \mathord{\left/ {\vphantom {{\rm{m}} {\rm{s}}}} \right. \\} {\rm{s}}}\).