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Exam II Equation Review Ch. 27 Current and Resistance • i= dq dt • Current density: i = Z ~ J~ · dA • Current and Drift speed: J~ = (nq)v~d and i = nqvd A • Resistance: R = V i ; Resistivity: ρ = E J L • R = ρA Also P = i2 R = V 2 /R • Power in electric circuits: P = iV Ch. 28 DC Circuits • EMF = ε = open circuit voltage of battery. • ∆V = ε − Ir terminal voltage across battery with internal resistance r. • Resistors in series: Req = R1 + R2 + ... • Resistors in parallel: 1/Req = 1/R1 + 1/R2 + ... • Kirchhoff’s Rules. – Junction Rule: Σjunction I = 0 – Loop Rule: Σclosedloop ∆V = 0 • RC Circuits – – – – Charging current: I(t) = I0 e−t/RC Charging charge: q(t) = Qmax (1 − e−t/RC ), where Qmax = Cε Discharging current: I(t) = I0 e−t/RC RC time constant, τ = RC, is time to change by 63%. Ch. 29 Magnetic Fields ~ • F~B = q~v × B ~ + ~v × B) ~ • Electric and Magnetic combined: F~B = q(E • Circulating charged particle: qvB = • Circulating charged particle: ω = mv2 r qB m • Helical paths: v⊥ = v sin φ ~ ×B ~ • Force on current carrying wire: F~B = iL • Know mass spectrometer, velocity selector, cyclotron Ch. 30 Magnetic Fields Due to Currents • Biot-Savart Law ~ = dB µ0 id~s × ~r 4π r 3 1 OR ~ = dB µ0 id~s × r̂ 4π r 2 ~ • Right-hand rule for cross products (like d~s × ~r and ~v × B) ~ around wires. • Right-hand rule for finding direction of B • → thumb points in direction of current • B-field for long straight wire: B = • B-field at center of circular arc: B µ0 i 2πR 0 iφ = µ4πR ~ ×B ~a • Force between two parallel currents: F~ba = ib L µ0 ia , 2πd µ0 ia ib L (direction 2πd • → since Ba is • → Fba = determined by RHR or remember ”opposites attract”.) • Ampere’s Law I ~ · d~s = µ0 ienc B • Solenoids and Toroids • B-field in ideal solenoid: B = µ0 in • B-field in toroid: B = µ0 iN 2πr • A current-carrying coil as a magnetic dipole: ~µ = NiA H ~ · dA ~=0 • Gauss’s law of magnetism: B Ch. 31 Faraday’s Law of Induction • Faraday’s Law: ε = −dΦB /dt (EMF around loop of wire.) • Faraday’s Law, N loops: ε = −NdΦB /dt • Motional EMF: ∆V = Blv between top and bottom of conducting bar moving at constant v through uniform ⊥ B H ~ · d~s = −dΦB /dt • Faraday’s Law, general, no wire needed: E • Generators: EMF generated by loop rotating in uniform B: ε = NABω sin ωt • Motors have the same mechanical structure as a generator, but are run “in reverse” (i.e., current pushed through a loop causing the loop to turn). 2
