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(C) The relation between electric field $E$ and electric potential $V$ is given by $E = -
abla V = -\left( \frac{\partial V}{\partial x} \hat{i} + \f

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$-8$

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(C) The relation between electric field $E$ and electric potential $V$ is given by $E = -
abla V = -\left( \frac{\partial V}{\partial x} \hat{i} + \frac{\partial V}{\partial y} \hat{j} ight)$.Given $E = 3 \hat{i} + 4y \hat{j}$,we have:$-\frac{\partial V}{\partial x} = 3 \implies \frac{\partial V}{\partial x} = -3$$-\frac{\partial V}{\partial y} = 4y \implies \frac{\partial V}{\partial y} = -4y$Integrating these partial derivatives:$V(x, y) = \int -3 \ dx = -3x + f(y)$$V(x, y) = \int -4y \ dy = -2y^2 + g(x)$Combining these,the general potential function is $V(x, y) = -(3x + 2y^2) + C$.Given that the potential at the origin $(0, 0)$ is $0$,we have $V(0, 0) = -(3(0) + 2(0)^2) + C = 0$,which implies $C = 0$.Thus,$V(x, y) = -(3x + 2y^2)$.At point $(2, 1)$,the potential is $V(2, 1) = -(3(2) + 2(1)^2) = -(6 + 2) = -8 \ V$.

The electric field vector in a region is given by $E = (3 \hat{i} + 4y \hat{j}) \ V \ m^{-1}$. The potential at the origin is zero. Then,the potential at a point $(2, 1) \ m$ is: (in $V$)

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