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Physics Chapter 18: Electrical Energy and Capacitance Electrical Energy and Capacitance • Electric Field – Surrounds All Charged Particles • Electric Force – Applied by an Electric Field kq1q2 2 F kq r E 2 qo qo r F E qo q1q2 F k 2 r Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Electrical Force Can Move Charged Particles – Movement of a Mass Over a Distance is Work – Electrical Force Does Work in the Form of Electrical Potential Energy ME KE PEg PEelastic PEelectric Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Uniform Electric Field – How about something other than particles? Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Uniform Electric Field ++++++++++++++++ Charged Plates - - - - - - - - - - - - - - - - Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Uniform Electric Field ++++++++++++++++ Direction of E Field - - - - - - - - - - - - - - - - Charged Plates Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Uniform Electric Field ++++++++++++++++ +q0i E Field - - - - - - - - - - - - - - - - Charged Plates Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Uniform Electric Field ++++++++++++++++ +q0i Displacement Due to Applied Force E Field +q0f - - - - - - - - - - - - - - - - Charged Plates Electrical Energy and Capacitance • Electrical Potential Energy (PE) – In the Same Way that Work is done by Gravitational Force…Wg=DPEg – Electric Force does Work as a Force Vector on a Test Charge (q0) DW DPE E field Felectric q0 Electrical Energy and Capacitance • Electrical Potential Energy (PE) DW DPE q0 q0 E field Felectric q0 DPEelectric qEd PE Decreases for a + Charge PE Increases for a - Charge Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Also Applies to Displacement of Charged particles Due to Other Charged Particles q1q2 DPEelectric k d DPEelectric qEd Electrical Energy and Capacitance • Electrical Potential Energy (PE) – Units • Energy, so… – Joules q1q2 DPEelectric k d DPEelectric qEd Electrical Energy and Capacitance • Electric Potential Difference (V) – As the Positive Charge Moves from the Positive Plate to the Negative Plate the PE Decreases – At Any Point in the Field, the PE will Increase with Increased Charge ++++++++++++++++ +q0i +q0f - - - - - - - - - - - - - - - - Electrical Energy and Capacitance • Electric Potential Difference (V) – This Potential Difference is Measured in Joules/Coulomb (Energy/Charge) – The Units of Potential Difference are Volts (V) ++++++++++++++++ DPE V q0 +q0i +q0f - - - - - - - - - - - - - - - - Electrical Energy and Capacitance • Electric Potential Difference (V) DPE V q0 DPEelectric qEd ++++++++++++++++ V Ed +q0i +q0f - - - - - - - - - - - - - - - - Electrical Energy and Capacitance • Electric Potential Difference (V) DPE V q0 q1q2 DPEelectric k d q V k r ++++++++++++++++ +q0i +q0f - - - - - - - - - - - - - - - - Electrical Energy and Capacitance • Electric Potential Difference – Problem “PE Difference” • q0 = 3x10-9C • Wa-b = 6x10-8J – What is DEPE? – What is DV? ++++++++++++++++ DEPE Wab DV q0 q0 q0a E q0b ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Solution “PE Difference” • q0 = 3x10-9C • Wa-b = 6x10-8J – What is DEPE? DEPE = -Wa-b = -6x10-8J ++++++++++++++++ DEPE Wab DV q0 q0 q0a E q0b ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Solution “PE Difference” • q0 = 3x10-9C • Wa-b = 6x10-8J – What is DV? 8 DEPE 6 x10 J DV 20V 9 q0 3x10 C ++++++++++++++++ q0a E q0b ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Note in the Previous Problem • q0 had a Positive Charge • A Positive Charge Moves from Higher PE to Lower PE • A Negative Charge Moves from Lower PE to Higher PE ++++++++++++++++ q0a E q0b ---------------- ++++++++++++++++ -q0b E -q0a ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Problem “The Light Will Come On” • • • • Electron Particle: q1 = 1.6x10-19C System Voltage: V = 12 J/C System Power (Light) = 40 W Time = 1 minute – How Many Electrons Will Pass, and in Which Direction? ++++++++++++++++ -q0 E -q0 ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Solution “The Light Will Burn” • • • • Electron Particle: q1 = 1.6x10-19C System Voltage: V = 12 J/C System Power (Light) = 40 W Time = 1 minute – Energy = Power x Time DEPE = 40W x 60s = 2400 w/s (J) q0 = DEPE/DV = 2400J/12V = 2x102C ++++++++++++++++ -q0 E -q0 ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Solution “The Light Will Burn” q0 = DEPE/DV = 2400J/12V = 2x102C – Total Particles: • q0 / q (-e) = (2x102C) / (1.6x10-19C) • = 1.3x1021 – Direction? • “A Negative Charge Moves from Lower PE to Higher PE” ++++++++++++++++ -q0b E -q0a ---------------- Electrical Energy and Capacitance • Electric Potential Difference – Energy, The Big Picture • • • • • Translational KE Rotational KE Gravitational PE Elastic PE Electric PE 1 2 1 2 1 2 E mv I mgh kx EPE 2 2 2 Electrical Energy and Capacitance • Electric Potential Difference – Problem: “Energy Conserved?” • Particle Moves from Point “a” to Point “b” by Electric Force – Mass = 3.6x10-3kg – Charge (q0) = 6x10-3C • DV = 25V • V0 = 0 – What is the Particle Speed at Point “b”? + + + + + + a b - Electrical Energy and Capacitance • Electric Potential Difference – Solution: “Energy Conserved?” – Mass = 3.6x10-3kg – Charge (q0) = 6x10-3C • DV = 25V • V0 = 0 – Rotation = 0 – Elasticity = 0 – Enet = Translational KE + Gravitational PE + EPE Electrical Energy and Capacitance • Electric Potential Difference – Solution: “Energy Conserved?” – Mass = 3.6x10-3kg – Charge (q0) = 6x10-3C • DV = 25V • V0 = 0 – ha = hb (Horizontal Movement Only) – EPEa – EPEb = q0(va-vb) – So… 1 1 2 2 mvb mva q0 (va vb ) 2 2 Electrical Energy and Capacitance • Electric Potential Difference 1 1 2 2 mvb mva q0 (Va Vb ) 2 2 – Solution: “Energy Conserved?” – Mass = 3.6x10-3kg – Charge (q0) = 6x10-3C • DV = 25V • V0 = 0 2q0 (Va Vb ) vb m Electrical Energy and Capacitance • Electric Potential Difference – Solution: “Energy Conserved?” – Mass = 3.6x10-3kg – Charge (q0) = 6x10-3C 2q0 (va vb ) vb m • DV = 25V • V0 = 0 2(6 x103 C )( 25V ) vb 9.1m / s 3 3.6 x10 kg Electrical Energy and Capacitance • Homework –Pages 683-685 • Problems: –12 (2.6x104V) –13 (-154V) –32 (4000V/m) Electrical Energy and Capacitance • Capacitors – Two Conductors Placed Near Each Other but Not Touching – The Area Between the Conductors is Filled With an Insulating Material (Dielectric) Electrical Energy and Capacitance • Capacitors – Dielectric • Contains Dipolar Molecules + Charge on One End - Charge on the Other End E + + + + + + + Dielectric Material - Electrical Energy and Capacitance • Capacitors – Dielectric • Each Molecule Accepts Charge (q) E + + + + + + + + Dielectric Material - + - Electrical Energy and Capacitance • Capacitors – Dielectric • Each Molecule Accepts Charge (q) • Entire Dielectric Material Becomes Charged E + + + + + + + - + + + Dielectric + Material + + + - Electrical Energy and Capacitance • Capacitors – Store Electric Charge – Positive and Negative Terminals Carry the Same Charge Magnitude Electrical Energy and Capacitance • Capacitors – Capacitance (C) • The Ability of the Capacitor to Store Charge E q C DV + + + + + + + Dielectric Material - Electrical Energy and Capacitance • Capacitors – Units • coulomb/volt • Farad – (after Michael Faraday) q C DV E + + + + + + + Dielectric Material - Electrical Energy and Capacitance • Capacitance – Varies with Type, Size, and Shape • Parallel Plate – Permittivity of Free Space – 8.85x10-12C2/Nm2 A C 0 d E + + + + + + + Dielectric Material - Electrical Energy and Capacitance • Capacitors – Due to the Charged Molecules of the Dielectric, the Electric Field (E) is Reduced E + + + + + + + - + + + Dielectric + Material + + + - Electrical Energy and Capacitance • Capacitors and Electric PE – Stored Charge is Stored Electric Potential Energy 1 PE qDV 2 E + + + + + + + - + + + Dielectric + Material + + + - Electrical Energy and Capacitance • Capacitors and Electric PE – Stored Charge is Stored Electric Potential Energy q 1 C PE qDV D V 2 1 2 PE C (DV ) 2 2 q PE 2C Electrical Energy and Capacitance • Homework –Pages 684-686 • Problems: –26 (7.2x10-11C) –27 (a, 1.3x10-3C b, 4.2J) –43 (4x10-6F)
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