Answer:
Explanation:
Resistivity and resistance are proportional and depends of the length and the cross-sectional area of the wire:
[tex]R=\frac{L}{A}\rho[/tex]
furthermore, the density is the mass divided by the volume, and the volume can be written as the area multiplyed by the length:
[tex]\rho_m=\frac{m}{A*L}[/tex]
Now you have tw equations and two variables, so you can solve for each of them.
first, solve for A in both equations and replace them:
[tex]\frac{L}{R}\rho=\frac{m}{\rho_mL}[/tex]
[tex]L^2=\frac{mR}{\rho_m \rho} \\L=[/tex]
now replace this into any of the previous equiations:
[tex]R=\frac{\sqrt{\frac{mR}{\rho_m \rho} } \rho}{A} \\A=\sqrt{\frac{mR\rho^2}{\rho_m \rho R^2} }\\A=\sqrt{\frac{m\rho}{\rho_m R} }[/tex]
If you assume the wire has circular cross-sectional area, then the area is:
[tex]A=\pi(\frac{d}{2} )^2[/tex]
solving for d:
[tex]d=2\sqrt{\frac{A}{\pi} }[/tex]
replacing A and simplifying:
[tex]d=2 \sqrt[4]{\frac{m\rho}{\rho_m R \pi^2} }[/tex]
