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Lecture 5 : Conductors and Dipoles

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1 Lecture 5 : Conductors and Dipoles
Capacitors Electric dipoles

2 Recap Gauss’s Law 𝐸 .𝑑 𝐴 = 𝑄 𝑒𝑛𝑐 πœ€ 0 and Maxwell’s 1st equation 𝛻 . 𝐸 = 𝜌 πœ€ 0 are equivalent integral and differential formulations for the electric field 𝐸 produced by charge density 𝜌 The electric field 𝐸 must also satisfy Maxwell’s 2nd equation 𝛻 Γ— 𝐸 = 0 . This implies that the electric field can be generated by the gradient of an electrostatic potential 𝑉, 𝐸 =βˆ’ 𝛻 𝑉

3 Conductors We’ll now consider the behaviour of 𝐸 in materials, which we divide into conductors and insulators

4 Conductors In a conductor, charges can flow freely
In practice, this usually involves free electrons moving within an ionic lattice

5 Place charge 𝑄 on a conducting sphere
Conductors What can we say about the electric field in and around a charge-carrying conductor in equilibrium? Place charge 𝑄 on a conducting sphere

6 Conductors What can we say about the electric field in and around a charge-carrying conductor in equilibrium? First, all charge must be located on the surface (otherwise it would move under the effect of forces from other charges) Hence from Gauss’s Law, 𝑬 = 𝟎 inside a conductor Hence, all points of the conductor are at constant electrostatic potential

7 Conductors An application of this effect is electrostatic shielding

8 Conductors What about the electric field just outside the conductor? 𝐸
There can be no component of 𝐸 parallel to the surface, otherwise charges would move Consider a Gaussian cylinder of cross- sectional area 𝐴 crossing the surface 𝐸 is perpendicular to the surface and zero inside, such that 𝐸 .𝑑 𝐴 =𝐸×𝐴 Let the charge per unit area at the surface be 𝜎, then 𝑄 π‘’π‘›π‘π‘™π‘œπ‘ π‘’π‘‘ =𝜎𝐴 Applying Gauss’s Law: 𝑬= 𝝈 𝜺 𝟎 𝐸 𝐴 𝐸 = 0

9 Electric field around conductor
Conductors The electric field just outside a conductor is perpendicular to the surface and proportional to the charge density Electric field around conductor Conductor in applied field

10 Capacitors A capacitor is a very useful circuit component formed by two parallel conductors separated by an insulator (or β€œdielectric”) When connected to a battery at potential 𝑉, charge ±𝑄 flows onto the plates. The capacitance is 𝐢=𝑄/𝑉 [unit: Farads, F] +𝑄 𝑉 -𝑄

11 Capacitors Capacitors are useful for storing charge (or, potential energy) and then releasing it

12 Capacitors What is the capacitance of a parallel-plate capacitor, where the plates have area 𝐴 and separation 𝑑? From Gauss’s Law (previous slides), electric field 𝐸= 𝜎 πœ€ 0 Capacitance 𝐢= 𝑄 𝑉 = πœŽΓ—π΄ 𝐸×𝑑 = πœ€ 0 𝐴 𝑑 Area 𝐴 +𝑄 𝐸= 𝜎 πœ€ 0 Separation 𝑑 βˆ’π‘„

13 Capacitors What is the capacitance of a pair of concentric cylinders of radii π‘Ž and 𝑏>π‘Ž? Suppose the charge per unit length on the cylinders is Β±πœ† Applying Gauss’s Law to a cylinder of radius π‘Ÿ and length 𝐿, we find 𝐸× 2πœ‹π‘ŸπΏ=πœ†πΏ/ πœ€ 0 or 𝐸=πœ†/2πœ‹ πœ€ 0 π‘Ÿ Potential difference between the cylinders is 𝑉= π‘Ž 𝑏 𝐸 π‘‘π‘Ÿ = πœ† 2πœ‹ πœ€ 0 π‘Ž 𝑏 1 π‘Ÿ π‘‘π‘Ÿ = πœ† 2πœ‹ πœ€ 0 π‘™π‘œπ‘” 𝑒 𝑏 π‘Ž Capacitance 𝐢= πœ† 𝑉 = 2πœ‹ πœ€ 0 π‘™π‘œπ‘” 𝑒 𝑏 π‘Ž

14 Electric dipoles An electric dipole consists of two charges +π‘ž and βˆ’π‘ž separated by distance 𝑑. It is neutral but produces an 𝐸 -field A dipole is a good model for many molecules! Dipole moment

15 What is the electric field strength along the axis?
Electric dipoles What is the electric field strength along the axis? 𝑃 𝐸 π‘Ÿ Electric potential: 𝑉 𝑃 = π‘ž 4πœ‹ πœ€ 0 (π‘Ÿβˆ’ 𝑑 2 ) + βˆ’π‘ž 4πœ‹ πœ€ 0 (π‘Ÿ+ 𝑑 2 ) β‰ˆ 𝑝 4πœ‹ πœ€ 0 π‘Ÿ 2 Electric field 𝐸 π‘₯ =βˆ’ 𝑑𝑉 π‘‘π‘Ÿ = 2𝑝 4πœ‹ πœ€ 0 π‘Ÿ 3 𝐸∝ 1 π‘Ÿ 2 for a point charge, and 𝐸∝ 1 π‘Ÿ 3 for a dipole

16 Electric dipoles When a dipole 𝑝 is placed in an electric field 𝐸 , it feels no net force (since it is neutral) but it feels a net torque 𝜏 = 𝑝 Γ— 𝐸 𝐸

17 Summary Conductors are materials in which charges can flow freely. All charge will reside on the surface, and 𝐸 = 0 inside Two separated conductors storing charge ±𝑄 form a capacitor 𝐢. If the potential difference is 𝑉, then 𝐢= 𝑄 𝑉 Two charges Β±π‘ž separated by distance 𝑑 form an electric dipole 𝑝 =π‘ž 𝑑 , which produces an electric field 𝐸∝ 1/ π‘Ÿ 3

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