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4 years ago

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Calculate the electric field (magnitude and direction) at the upper right corner of a square 1.22 m on a side if the other three

corners are occupied by 2.40×10−6 C charges. Assume that the positive x-axis is directed to the right.

1 answer:

Luden [163]4 years ago

3 0

Explanation:

It is mentioned that the magnitude of given charge is $2.40 \times 10^{-6} C$ and side of the square is 1.22 m.

Hence, we will calculate the electric field due to charge at point A as follows.

$E_{a} = k\frac{q}{r^{2}}$

= $\frac{9 \times 10^{9} \times 2.4 \times 10^{-6}}{(1.22)^{2}}$

= $14.512 \times 10^{3} N/C$ (acts along y-axis)

Electric field at D due to the charge at C is as follows.

$E_{c} = k\frac{q}{r^{2}}$

= $\frac{9 \times 10^{9} \times 2.4 \times 10^{-6}}{(1.22)^{2}}$

= $14.512 \times 10^{3} N/C$ (acts along y-axis)

Electric field at D due to the charge at B is as follows.

$E_{d} = k\frac{q}{r^{2}}$

= $\frac{9 \times 10^{9} \times 2.4 \times 10^{-6}}{(1.7253)^{2}}$

= $7.2564 \times 10^{3} N/C$

Now, we will resolve it into two components.

$E_{bx} = E_{b} Cos 45 = 5.1318 \times 10^{3} N/C$

$E_{by} = E_{b} Sin 45 = 5.1318 \times 10^{3} N/C$

Now, the resultant x component is as follows.

$E_{x} = (14.512 + 5.1318) \times 10^{3} = 19.6438 \times 10^{3} N/C$

Resultant y component is given as follows.

$E_{y} = (14.512 + 5.1318) \times 10^{3} = 19.6438 \times 10^{3} N/C$

Therefore, resultant electric field at point D is as follows.

$E = \sqrt{E^{2}_{x} + E^{2}_{y}}$

= $\sqrt{(19.6438 \times 10^{3})^{2} + (19.6438 \times 10^{3})^{2}}$

= $27.780 \times 10^{3} N/C$

And, the direction of electric field is

$\theta = tan^{-1} (\frac{E_{y}}{E_{x}})$

= $tan^{-1} (1)$

= $45^{o}$

This means that net electric field makes an angle of $135^{o}$ with positive x-axis in counter clockwise direction.

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Answer: (a) α = $\frac{3I}{2.\pi.R^{3}}$

(b) For r≤R: B(r) = μ_0. $(\frac{I.r^{2}}{2.\pi.R^{3}})$

For r≥R: B(r) = μ_0. $(\frac{I}{2.\pi.r})$

Explanation:

(a) The current I enclosed in a straight wire with current density not constant is calculated by:

$I_{c} = \int {J} \, dA$

where:

dA is the cross section.

In this case, a circular cross section of radius R, so it translates as:

$I_{c} = \int\limits^R_0 {\alpha.r.2.\pi.r } \, dr$

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For these circunstances, α = $\frac{3I}{2.\pi.R^{3}}$

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(i) First, first find $I_{c}$ for r ≤ R:

$I_{c} = \int\limits^r_0 {\alpha.r.2\pi.r} \, dr$

$I_{c} = 2.\pi.\frac{3I}{2.\pi.R^{3}} \int\limits^r_0 {r^{2}} \, dr$

$I_{c} = \frac{I}{R^{3}}\int\limits^r_0 {r^{2}} \, dr$

$I_{c} = \frac{3I}{R^{3}}\frac{r^{3}}{3}$

$I_{c} = \frac{I.r^{3}}{R^{3}}$

Calculating B(r), using Ampere's Law:

$\int\ {B} \, dl =$ μ_0. $I_{c}$

$B.2.\pi.r = (\frac{Ir^{3}}{R^{3}} )$ .μ_0

B(r) = $(\frac{Ir^{3}}{R^{3}2.\pi.r})$ .μ_0

B(r) = $(\frac{Ir^{2}}{2.\pi.R^{3}} )$ .μ_0

For r ≤ R, magnetic field is B(r) = $(\frac{Ir^{2}}{2.\pi.R^{3}} )$ .μ_0

(ii) For r ≥ R:

$I_{c} = \int\limits^R_0 {\alpha.2,\pi.r.r} \, dr$

So, as calculated before:

$I_{c} = \frac{3I}{R^{3}}\frac{R^{3}}{3}$

$I_{c} =$ I

Using Ampere:

B.2.π.r = μ_0.I

B(r) = $(\frac{I}{2.\pi.r} )$ .μ_0

For r ≥ R, magnetic field is; B(r) = $(\frac{I}{2.\pi.r} )$ .μ_0.

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