Potential energy of an electric dipole in electric field

AI Thread Summary
The energy of an ideal dipole in an electric field is expressed as U = -p ⋅ E. The torque on the dipole is given by τ = p × E, and the potential energy calculation involves integrating the work done as the dipole aligns with the electric field. The placement of the zero point for potential energy is crucial, as it affects the integration limits. If the potential energy is defined as zero when the dipole is perpendicular to the electric field, the integration should be from θ to π/2. Understanding these concepts is essential for accurately deriving the potential energy formula.
Sleepycoaster
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Homework Statement


Show that the energy of an ideal dipole p in an electric field E is given by

U = -p ⋅ E

Homework Equations



Work = θτ where τ is torque

τ = p × E

The Attempt at a Solution



U = ∫(p × E) dθ' (from θ to 0, since the dipole will eventually align itself with the magnetic field.)
=∫pE(sinθ')dθ'
=-pE(cosθ') with limits θ to 0
=-pE + pE(cosθ)
=p ⋅ E - pE

That's not what I needed to prove. Help?
 
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The formula for the potential energy depends where the zero of the PE is placed. The potential energy is the work done by the force when the object moves from the initial position to the position of zero potential. If the potential energy of the dipole is zero when it is perpendicular to the electric field, you have to integrate from θ to pi/2.
 
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ehild said:
The formula for the potential energy depends where the zero of the PE is placed. The potential energy is the work done by the force when the object moves from the initial position to the position of zero potential. If the potential energy of the dipole is zero when it is perpendicular to the electric field, you have to integrate from θ to pi/2.
Okay, thanks!
 

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