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Electricity and Magnetism Review Notes by L. Qian 1 Electric ============================== Charge: Symbol: q Unit: C [Coulomb] Magnetic ============================= Current Element: r Symbol: i ds Unit: A⋅m [Ampere-meter] --------------------------------------------------Electric Field: r Symbol: E Unit: V/m = N/C Current: Symbol: i Unit: A (Ampere) ------------------------------------------------Magnetic Field: r Symbol: B Unit: T = N⋅s /(C⋅m) [T: Tesla] - Electric field due to a static charge q r 1 q E= rˆ 4πε 0 rr 2 r - Magnetic field due to a current element i ds r μ 0 idsr × rˆ μ 0 idsr × rr B= = 4π rr 2 4π rr 3 (from Coulomb’s Law) (Biot-Savart Law) y y r̂ q r ids r r P r̂ r r P x x - Magnetic field due to an infinitely long current-carrying straight wire i μi B= 0 2πR R 1 Notes are for your reference only. Please check with the textbook for accuracy. Notations may be different from that of the textbook. - Electric field in a parallel-plate capacitor: V q E= = d εo A (where A is the area of the plate, and d is the plate separation) --------------------------------------------------Electric Field Lines: - Start from positive charges or ∞ - End at negative charges or ∞ - The denser the lines, the higher the E field magnitude - The tangent of the field line at any point indicates the E field direction - Magnetic field in an ideal solenoid: (where n is the number of turns per unit length) ------------------------------------------------Magnetic Field Lines: - External field lines start from the N-pole - External field lines end at the S-pole - The denser the lines, the higher the B field magnitude - The tangent of the field line at any point indicates the B field direction Sample field lines: Sample field lines: B = μ 0 ni note the right-hand rule - Uniform E field inside a parallel-plate capacitor - Uniform B field inside an ideal solenoid (inductor) V+ r E V− V = Ed --------------------------------------------------- Φ B = BA -----------------------------------------------------Magnetic Flux: Symbol: ΦΒ Unit: Wb = T⋅m [Wb: Weber] Definition: r r Φ B = ∫ B ⋅ dA S Magnetic Flux Linkage (of a solenoid): NΦB (N= number of turns) --------------------------------------------------Electric Force: r Symbol: F Unit: N [Newton] - Force on a charge in an external E field r r F = qE - Force between two charges q1 and q2 F = q1q 2 4πε 0 rr 2 1 -----------------------------------------------------Magnetic Force: r Symbol: F Unit: N [Newton] - Force on a moving charge in an external B field r r r F = qv × B - Force on a current element in an external B field r r r F = idL × B - Force between two current-carrying wires ia and ib μii Fba = 0 a b L 2π d (note, above formula is the force exerted on wire b over length L) ib ib d ia ia --------------------------------------------------Electric Potential: Symbol: V Unit: V = J/C [V: Volt] - Electric potential due to a single charge q: 1 q V= 4πε 0 r - Potential created by multiple point charges: 1 qi V= ∑ 4πε 0 i ri - Potential difference between capacitor plates: V = q/C ------------------------------------------------------ - Equal potential lines are perpendicular to field lines --------------------------------------------------Electric Potential Energy: Symbol: UE Unit: J [Joule] U E = qV or ΔU E = q ΔV --------------------------------------------------- ------------------------------------------------------ -----------------------------------------------------Induction (Faraday’s Law): - Induced emf by one turn of coil: dΦ B unit: V E=− dt - Induced emf by a solenoid of N turns: dΦ B unit: V E = −N dt --------------------------------------------------Capacitance: Symbol: C Unit: F = C/V [F: Farad] Definition: q C= V - Parallel-plate capacitor ε A C= 0 d (where A is the area of the plate, and d is the plate separation) -----------------------------------------------------Inductance: Symbol: L Unit: H = Wb/A [H: Henry] Definition: NΦ B i 1 or L = = L NΦ B i - Ideal solenoid of length l - Capacitance is a geometry- and materialrelated parameter - Inductance is a geometry- and materialrelated parameter --------------------------------------------------Capacitors in parallel -----------------------------------------------------Inductors in parallel 1 1 1 = + + ... Leq L1 L2 (Flux linkage is the same for all inductors) Ceq = C1 + C2 + ... (Voltage is the same for all capacitors) L = μ 0 n 2 Al (where n is the number of turns per unit length, A is cross-sectional area) Capacitors in series 1 1 1 = + + ... Ceq C1 C 2 (Charge is the same for all capacitors) Inductors in series --------------------------------------------------Energy stored in a capacitor q2 1 UE = = CV 2 2C 2 -----------------------------------------------------Energy stored in an inductor 1 U B = Li 2 2 Electric energy density Magnetic energy density UE 1 = εoE2 volume 2 ============================== UB 1 2 B = volume 2 μ o ============================= uE = Leq = L1 + L2 + ... (Current is the same for all inductors) uB =
