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An electric dipole has a dipole moment of 1.6×10−15 Cm. The dipole moment vector is initially oriented at θ = 26.96∘ to the +x-axis. How much work will be done by an electric field 4.66 MN/C(−i^) to bring the dipole to its stable equilibrium position (in nJ)?

An electric dipole has a dipole moment of 1.6×10−15 Cm. The dipole moment vector is initially oriented at θ = 26.96∘ to the +x-axis. How much work will be done by an electric field 4.66 MN/C(−i^) to bring the dipole to its stable equilibrium position (in nJ)?

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An electric dipole has a dipole moment of 1.6 × 10 15 Cm . The dipole moment vector is initially oriented at θ = 26.96 to the + x -axis. How much work will be done by an electric field 4.66 M N C ( i ^ ) to bring the dipole to its stable equilibrium position (in n J ) ?

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