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Reading: Chapter 28 E Q Q k e 2 4πεo r 2 r For r > a Gauss’s Law 1 Chapter 28 Gauss’s Law 2 Electric Flux Definition: • Electric flux is the product of the magnitude of the electric field and the surface area, A, perpendicular to the field • ΦE = EA • The field lines may make some angle θ with the perpendicular to the surface • Then ΦE = EA cos θ E normal E E EA cos E EA 3 Electric Flux: Surface as a Vector Vector, corresponding to a Flat Surface of Area A, is determined by the following rules: the vector is orthogonal to the surface the magnitude of the vector is equal to the area A The first rule A 90 o the vector is orthogonal to the surface normal does not determine the direction of A . There are still two possibilities: Area = A A or 90 o 90 o A You can choose any of them 4 Electric Flux: Surface as a Vector If we consider more complicated surface then the directions of vectors should be adjusted, so the direction of vector is a smooth function of the surface point correct or A2 A1 wrong or A3 5 Electric Flux Definition: • Electric flux is the scalar product of electric field and the vector A • EA A E E EA EA cos 0 or A E E EA EA cos 0 6 Electric Flux E 1 E 1 2 area A1 A1 area A2 A2 90o 2 EA2 EA2 cos(90o ) EA2 sin 2 1 EA1 EA1 sin E EA1 sin EA2 sin E if then A1 flux is positive E A1 E EA1 sin 2 0 A2 E EA1 cos EA2 cos flux is negative A2 A2 and E are orthogonal 7 Electric Flux • In the more general case, look at a small flat area element E Ei Ai cos θi Ei Ai • In general, this becomes E lim Ai 0 E A i i E dA surface • The surface integral means the integral must be evaluated over the surface in question • The units of electric flux will be N.m2/C2 8 Electric Flux: Closed Surface The vectors Ai point in different directions At each point, they are perpendicular to the surface By convention, they point outward E lim Ai 0 E A i i E dA surface 9 Electric Flux: Closed Surface 2 Closed surface E 1 2 3 4 5 6 6 3 5 E is orthogonal to A3 , A4 , A5 , and A6 Then 3 EA3 0 4 EA4 0 5 EA5 0 6 EA6 0 1 E E 1 2 1 EA1 EA1 cos(90 ) EA1 sin o 4 E 90o A1 A3 1 3 2 4 2 EA2 EA2 A4 E E ( A2 A1 sin ) but A2 A1 sin A2 A1 A2 Then E 0 10 (no charges inside closed surface) Electric Flux: Closed Surface • A positive point charge, q, is located at the center of a sphere of radius r • The magnitude of the electric field everywhere on the surface of the sphere is Spherical surface E = keq / r2 • Electric field is perpendicular to the surface at every point, so E has the same direction as A at every point. 11 Electric Flux: Closed Surface E has the same direction as A at every point. q E ke 2 r Then Spherical surface Ei dAi E dAi i i q EA0 E 4 r 4 r ke 2 r q Gauss’s Law 4 ke q 2 2 0 does not depend on r ONLY BECAUSE 1 E 2 12 r Electric Flux: Closed Surface E and A have opposite directions at every point. |q| E ke 2 r Spherical surface Then Ei dAi E dAi i i |q| EA0 E 4 r 4 r ke 2 r q Gauss’s Law 4 ke | q | 2 2 0 does not depend on r ONLY BECAUSE 1 E 13 2 r Gauss’s Law The net flux through any closed surface surrounding a point charge, q, is given by q/εo and is independent of the shape of that surface The net electric flux through a closed surface that surrounds no charge is zero Ai q E Ai q 0 E q q 0 14 Gauss’s Law Gauss’s law states qin E E dA εo qin is the net charge inside the surface E is the total electric field and may have contributions from charges both inside and outside of the surface Ai q E Ai q 0 E q q 0 15 Gauss’s Law Gauss’s law states E E dA qin εo qin is the net charge inside the surface E is the total electric field and may have contributions from charges both inside and outside of the surface q5 q2 q1 q3 q1 q2 q3 q4 0 q4 q6 q7 16 Gauss’s Law Gauss’s law states E E dA qin εo qin is the net charge inside the surface E is the total electric field and may have contributions from charges both inside and outside of the surface q5 q2 q1 0 q3 q4 q6 q7 17 Gauss’s Law Gauss’s law states E E dA qin εo qin is the net charge inside the surface E is the total electric field and may have contributions from charges both inside and outside of the surface q5 q2 0 q q q4 q6 q7 18 Gauss’s Law: Problem What is the flux through surface 1 1 2 0 2 EA0 EA0 1 2 EA0 A1 1 E A2 A0 2 A3 19 Chapter 28 Gauss’s Law: Applications 20 Gauss’s Law: Applications Although Gauss’s law can, in theory, be solved to find E for any charge configuration, in practice it is limited to symmetric situations To use Gauss’s law, you want to choose a Gaussian surface over which the surface integral can be simplified and the electric field determined Take advantage of symmetry Remember, the gaussian surface is a surface you choose, it does not have to coincide with a real surface qin E dA εo q5 q1 q2 q3 q4 0 q6 q2 q1 q3 q4 21 Gauss’s Law: Point Charge E q SYMMETRY: E - direction - along the radius E - depends only on radius, r q 0 Gaussian Surface – Sphere Only in this case the magnitude of electric field is constant on the Gaussian surface and the flux can be easily evaluated - Gauss’s Law Ei dAi E dAi EA0 E 4 r 2 i Then - definition of the Flux i q 4 r E 2 q E ke 2 r 22 qin E dA εo Gauss’s Law: Applications • Try to choose a surface that satisfies one or more of these conditions: – The value of the electric field can be argued from symmetry to be constant over the surface – The dot product of E.dA can be expressed as a simple algebraic product EdA because E and dA are parallel – The dot product is 0 because E and dA are perpendicular – The field can be argued to be zero over the surface correct Gaussian surface wrong Gaussian surface 23 Gauss’s Law: Applications Spherically Symmetric Charge Distribution The total charge is Q SYMMETRY: E A E - direction - along the radius E - depends only on radius, r • Select a sphere as the gaussian surface • For r >a qin Q E E dA EdA 4πr E εo εo 2 E Q Q k e 2 4πεo r 2 r The electric field is the same as for the point charge Q 24 Gauss’s Law: Applications Spherically Symmetric Charge Distribution Q Q E ke 2 2 4πεo r r The electric field is the same as for the point charge Q !!!!! Q a For r > a Q For r > a 25 Gauss’s Law: Applications Spherically Symmetric Charge Distribution SYMMETRY: A E E - direction - along the radius E - depends only on radius, r • Select a sphere as the gaussian surface, r < a qin Q 4 3 a 3 4 3 r3 r Q 3 Q 3 a qin E E dA EdA 4πr E εo 2 qin Qr 3 1 Q E ke 3 2 ke 3 r 2 4πεo r a r a 26 Gauss’s Law: Applications Spherically Symmetric Charge Distribution • Inside the sphere, E varies linearly with r E → 0 as r → 0 • The field outside the sphere is equivalent to that of a point charge located at the center of the sphere 27 Gauss’s Law: Applications Field due to a thin spherical shell • Use spheres as the gaussian surfaces • When r > a, the charge inside the surface is Q and E = keQ / r2 • When r < a, the charge inside the surface is 0 and E = 0 28 Gauss’s Law: Applications Field due to a thin spherical shell • When r < a, the charge inside the surface is 0 and E = 0 A1 r1 E 2 the same solid angle E1 r2 q1 A1 q2 A2 A1 r12 A2 r22 q1 A1 r12 E1 ke 2 ke 2 ke ke r1 r1 r12 q2 A2 r22 E2 ke 2 ke 2 ke ke 2 r2 r2 r2 E1 E2 E1 E2 0 A2 Only because in Coulomb law 1 E 2 r 29 Gauss’s Law: Applications Field from a line of charge • Select a cylindrical Gaussian surface – The cylinder has a radius of r and a length of ℓ • Symmetry: E is constant in magnitude (depends only on radius r) and perpendicular to the surface at every point on the curved part of the surface The end view 30 Gauss’s Law: Applications Field from a line of charge dA The flux through this surface is 0 The flux through this surface: qin E E dA EdA E 2πr εo qin λ λ E 2πr ε o The end view λ λ E 2ke 2πεr r o 31 Gauss’s Law: Applications Field due to a plane of charge • Symmetry: E must be perpendicular to the plane and must have the same magnitude at all points equidistant from the plane dA • Choose a small cylinder whose axis is perpendicular to the plane for the gaussian surface The flux through this surface is 0 32 Gauss’s Law: Applications Field due to a plane of charge E2 A2 A4 A3 h A5 h A6 dA A1 E1 E1 E2 E A1 A2 A The flux through this surface is 0 E1 A1 E2 A2 EA EA 2EA A 0 0 qin A 2 EA 0 E 2 0 does not depend on h 33 Gauss’s Law: Applications E 2 0 E 2 ke r 34 Gauss’s Law: Applications 4 3 Q πa ρ 3 4 3 πa ρ 4 Q E ke 3 r ke 3 3 r πk e ρr a a 3 4 E πk e ρr 3 35 Example Find electric field inside the hole R r a 36 4 E πk e ρr1 3 R 4 E πk e ρr2 3 R r a r1 r r2 4 E πk e ρr 3 R r1 r2 a 4 4 4 4 E πk e ρr1 πk e ρr2 πk e ρr ( 1 r2 ) πk e ρa const 37 3 3 3 3 Example The sphere has a charge Q and radius a. The point charge –Q/8 is placed at the center of the sphere. Find all points where electric field is zero. E1 r E2 Q E1 ke 3 r a Q E 2 k e 2 r 8r E1 E2 0 Q Q ke 3 r ke 2 a 8r 3 a r3 8 a r 2 38 Chapter 28 Conductors in Electric Field 39 Electric Charges: Conductors and Isolators Electrical conductors are materials in which some of the electrons are free electrons These electrons can move relatively freely through the material Examples of good conductors include copper, aluminum and silver Electrical insulators are materials in which all of the electrons are bound to atoms These electrons can not move relatively freely through the material Examples of good insulators include glass, rubber and wood Semiconductors are somewhere between insulators and conductors 40 Electrostatic Equilibrium Definition: when there is no net motion of charge within a conductor, the conductor is said to be in electrostatic equilibrium Because the electrons can move freely through the material no motion means that there are no electric forces no electric forces means that the electric field inside the conductor is 0 If electric field inside the conductor is not 0, E 0 then there is an electric force F qE and, from the second Newton’s law, there is a motion of free electrons. F qE 41 Conductor in Electrostatic Equilibrium • The electric field is zero everywhere inside the conductor • Before the external field is applied, free electrons are distributed throughout the conductor • When the external field is applied, the electrons redistribute until the magnitude of the internal field equals the magnitude of the external field • There is a net field of zero inside the conductor 42 Conductor in Electrostatic Equilibrium • If an isolated conductor carries a charge, the charge resides on its surface Electric filed is 0, so the net flux through Gaussian surface is 0 qin E dA εo Then qin 0 43 Conductor in Electrostatic Equilibrium • The electric field just outside a charged conductor is perpendicular to the surface and has a magnitude of σ/εo • Choose a cylinder as the gaussian surface • The field must be perpendicular to the surface – If there were a parallel component to E, charges would experience a force and accelerate along the surface and it would not be in equilibrium • The net flux through the gaussian surface is through only the flat face outside the conductor – The field here is perpendicular to the surface σA σ EA and E • Gauss’s law: E ε o ε o 44 Conductor in Electrostatic Equilibrium E σ σ ε o σ E 0 σ σ σ 45 Conductor in Electrostatic Equilibrium: Example Find electric field if the conductor spherical shell has zero charge r2 r1 q 0 conductor E 0 46 Conductor in Electrostatic Equilibrium: Example Find electric field if the conductor spherical shell has zero charge r2 E 0 r1 The total charge inside this Gaussian surface is 0, so the electric field is 0 q 0 surface charge, total charge is –q<0 surface charge, total charge is q>0 This is because the total charge of the conductor is 0!!! 47 Conductor in Electrostatic Equilibrium: Example Find electric field if the conductor spherical shell has zero charge r2 E 0 r1 The total charge inside this Gaussian surface is q, so the electric field is q 0 q E ke 2 r surface charge, total charge is q>0 This is because the total charge of the conductor is 0!!! total charge is –q<0 48 Conductor in Electrostatic Equilibrium: Example Find electric field if the conductor spherical shell has zero charge r2 E 0 r1 q E ke 2 r q 0 E ke q r2 surface charge, total charge is q>0 This is because the total charge of the conductor is 0!!! total charge is –q<0 49 Conductor in Electrostatic Equilibrium: Example Find electric field if the charge of the conductor spherical shell is Q r2 E 0 r1 Qq E ke 2 r q 0 E ke q r2 surface charge, total charge is Q+q>0 This is because the total charge of the conductor is Q!!! total charge is –q<0 50