Answer:
[tex]i = 2.84 \times 10^{-3} A[/tex]
Explanation:
As we know that current density is ratio of current and area of the crossection
now we have
[tex]J = \frac{di}{dA}[/tex]
so the current through the wire is given as
[tex]i = \int J dA[/tex]
now we have
[tex]i = \int_{0.921R}^R J dA[/tex]
here we have
[tex]J = (3.25 \times 10^8)r^2[/tex]
now plug in the values in above equation
[tex]i = \int_{0.921R}^R (3.25 \times 10^8)r^2 2\pi r dr[/tex]
now we have
[tex]i = \int_{0.921R}^R 2\pi (3.25 \times 10^8)r^3 dr[/tex]
[tex]i = (2.04 \times 10^9) \frac{r^4}{4}[/tex]
now plug in both limits as mentioned
[tex]i = (2.04 \times 10^9)(\frac{R^4}{4} - \frac{(0.921R)^4}{4})[/tex]
[tex]i = (2.04\times 10^9)(0.07 R^4)[/tex]
here R = 2.11 mm
[tex]i = (2.04 \times 10^9)(0.07 (2.11 \times 10^{-3})^4)[/tex]
[tex]i = 2.84 \times 10^{-3} A[/tex]
