(A) The relationship between electric field $\vec{E}$ and electric potential $V$ is given by the relation: $dV = -\vec{E} \cdot d\vec{r}$.Given $\vec{

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(A) The relationship between electric field $\vec{E}$ and electric potential $V$ is given by the relation: $dV = -\vec{E} \cdot d\vec{r}$.Given $\vec{E} = 30x^2 \hat{i}$ and $d\vec{r} = dx \hat{i}$,we have $dV = -30x^2 dx$.To find the potential difference $(V_A - V_0)$,we integrate from $x = 0$ to $x = 2$:$\int_{V_0}^{V_A} dV = -\int_{0}^{2} 30x^2 dx$.$V_A - V_0 = -[10x^3]_{0}^{2}$.$V_A - V_0 = -(10(2)^3 - 10(0)^3) = -(10 \times 8) = -80 \ V$.

Class 12 Physics Electric Potential and Capacitance Relation between Electric Field and Potential and Potential Gradient

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Assume that an electric field $E = 30x^2 \hat{i}$ exists in space. If $V_0$ is the potential at the origin and $V_A$ is the potential at $x = 2 \ m$,then the potential difference $(V_A - V_0)$ is: (in $V$)

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$-80$
B
$-120$
C
$80$
D
$120$

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Electric Potential and Capacitance

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Relation between Electric Field and Potential and Potential Gradient

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Assume that an electric field $E = 30x^2 \hat{i}$ exists in space. If $V_0$ is the potential at the origin and $V_A$ is the potential at $x = 2 \ m$,then the potential difference $(V_A - V_0)$ is: (in $V$)

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If potential (in volts) in a region is expressed as $V(x, y, z) = 6xy - y + 2yz$,the electric field (in $N/C$) at point $(1, 1, 0)$ is:

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