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Definition of capacitance

Anaya Zafar
Anaya Zafar

1) Capacitance is a measure of the amount of electric charge stored on a conductor for a given potential difference between conductors. The capacitance of a parallel plate capacitor is directly proportional to the area of its plates and inversely proportional to the distance between the plates. 2) When capacitors are connected in parallel, the equivalent capacitance is the sum of the individual capacitances. In series, the equivalent capacitance is less than the individual capacitances. 3) Energy is stored in a capacitor when it is charged, and this energy can be rapidly discharged. Capacitors are used in applications where energy must be stored and quickly released, such as in defibrillators.

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Definition of Capacitance • The capacitance, C, of a capacitor is defined as the ratio of the magnitude of the charge on either conductor to the potential difference between the conductors • The SI unit of capacitance is the farad (F) Q C V  
Capacitance – Parallel Plates • The capacitance is proportional to the area of its plates and inversely proportional to the distance between the plates / o o ε AQ Q Q C V Ed Qd ε A d     
Capacitance of a Cylindrical Capacitor V = -2keλ ln (b/a)  = Q/l • The capacitance is  2 ln /e Q C V k b a    
Capacitance of a Spherical Capacitor • The potential difference will be • The capacitance will be 1 1 eV k Q b a          e Q ab C V k b a    
Capacitors in Parallel, 3 • The capacitors can be replaced with one capacitor with a capacitance of Ceq – The equivalent capacitor must have exactly the same external effect on the circuit as the original capacitors
Capacitors in Parallel • Ceq = C1 + C2 + C3 + … • The equivalent capacitance of a parallel combination of capacitors is greater than any of the individual capacitors – Essentially, the areas are combined
Capacitors in Series • An equivalent capacitor can be found that performs the same function as the series combination • The charges are all the same Q1 = Q2 = Q
Capacitors in Series • The potential differences add up to the battery voltage ΔVtot = V1 + V2 + … • The equivalent capacitance is • The equivalent capacitance of a series combination is always less than any individual capacitor in the combination 1 2 3 1 1 1 1 eqC C C C    
Energy Stored in a Capacitor • Assume the capacitor is being charged and, at some point, has a charge q on it • The work needed to transfer a charge from one plate to the other is • The total work required is q dW Vdq dq C    2 0 2 Q q Q W dq C C  
Energy • The work done in charging the capacitor appears as electric potential energy U: • This applies to a capacitor of any geometry • The energy stored increases as the charge increases and as the potential difference increases • In practice, there is a maximum voltage before discharge occurs between the plates 2 21 1 ( ) 2 2 2 Q U Q V C V C     
Energy • The energy can be considered to be stored in the electric field • For a parallel-plate capacitor, the energy can be expressed in terms of the field as U = ½ (εoAd)E2 • It can also be expressed in terms of the energy density (energy per unit volume) uE = ½ oE2
Some Uses of Capacitors • Defibrillators – When cardiac fibrillation occurs, the heart produces a rapid, irregular pattern of beats – A fast discharge of electrical energy through the heart can return the organ to its normal beat pattern • In general, capacitors act as energy reservoirs that can be slowly charged and then discharged quickly to provide large amounts of energy in a short pulse
Capacitors with Dielectrics • A dielectric is a nonconducting material that, when placed between the plates of a capacitor, increases the capacitance – Dielectrics include rubber, glass, and waxed paper • With a dielectric, the capacitance becomes C = κCo – The capacitance increases by the factor κ when the dielectric completely fills the region between the plates – κ is the dielectric constant of the material
Dielectrics, cont • For a parallel-plate capacitor, C = κεo(A/d) • In theory, d could be made very small to create a very large capacitance • In practice, there is a limit to d – d is limited by the electric discharge that could occur though the dielectric medium separating the plates • For a given d, the maximum voltage that can be applied to a capacitor without causing a discharge depends on the dielectric strength of the material
Dielectrics, final • Dielectrics provide the following advantages: – Increase in capacitance – Increase the maximum operating voltage – Possible mechanical support between the plates • This allows the plates to be close together without touching • This decreases d and increases C
Types of Capacitors – Tubular • Metallic foil may be interlaced with thin sheets of paraffin- impregnated paper or Mylar • The layers are rolled into a cylinder to form a small package for the capacitor
Types of Capacitors – Oil Filled • Common for high- voltage capacitors • A number of interwoven metallic plates are immersed in silicon oil
Types of Capacitors – Electrolytic • Used to store large amounts of charge at relatively low voltages • The electrolyte is a solution that conducts electricity by virtue of motion of ions contained in the solution
Electric Dipole • An electric dipole consists of two charges of equal magnitude and opposite signs • The charges are separated by 2a • The electric dipole moment ( ) is directed along the line joining the charges from –q to +q p 
Electric Dipole, 2 • The electric dipole moment has a magnitude of p ≡ 2aq • Assume the dipole is placed in a uniform external field, – is external to the dipole; it is not the field produced by the dipole • Assume the dipole makes an angle θ with the field E  E 
Electric Dipole, 3 • Each charge has a force of F = Eq acting on it • The net force on the dipole is zero • The forces produce a net torque on the dipole
Electric Dipole, final • The magnitude of the torque is: = 2Fa sin θ pE sin θ • The torque can also be expressed as the cross product of the moment and the field: • The potential energy can be expressed as a function of the orientation of the dipole with the field: Uf – Ui = pE(cos θi – cos θf U = - pE cos θ   p E  U  p E 

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Definition of capacitance

  • 1. Definition of Capacitance • The capacitance, C, of a capacitor is defined as the ratio of the magnitude of the charge on either conductor to the potential difference between the conductors • The SI unit of capacitance is the farad (F) Q C V  
  • 2. Capacitance – Parallel Plates • The capacitance is proportional to the area of its plates and inversely proportional to the distance between the plates / o o ε AQ Q Q C V Ed Qd ε A d     
  • 3. Capacitance of a Cylindrical Capacitor V = -2keλ ln (b/a)  = Q/l • The capacitance is  2 ln /e Q C V k b a    
  • 4. Capacitance of a Spherical Capacitor • The potential difference will be • The capacitance will be 1 1 eV k Q b a          e Q ab C V k b a    
  • 5. Capacitors in Parallel, 3 • The capacitors can be replaced with one capacitor with a capacitance of Ceq – The equivalent capacitor must have exactly the same external effect on the circuit as the original capacitors
  • 6. Capacitors in Parallel • Ceq = C1 + C2 + C3 + … • The equivalent capacitance of a parallel combination of capacitors is greater than any of the individual capacitors – Essentially, the areas are combined
  • 7. Capacitors in Series • An equivalent capacitor can be found that performs the same function as the series combination • The charges are all the same Q1 = Q2 = Q
  • 8. Capacitors in Series • The potential differences add up to the battery voltage ΔVtot = V1 + V2 + … • The equivalent capacitance is • The equivalent capacitance of a series combination is always less than any individual capacitor in the combination 1 2 3 1 1 1 1 eqC C C C    
  • 9. Energy Stored in a Capacitor • Assume the capacitor is being charged and, at some point, has a charge q on it • The work needed to transfer a charge from one plate to the other is • The total work required is q dW Vdq dq C    2 0 2 Q q Q W dq C C  
  • 10. Energy • The work done in charging the capacitor appears as electric potential energy U: • This applies to a capacitor of any geometry • The energy stored increases as the charge increases and as the potential difference increases • In practice, there is a maximum voltage before discharge occurs between the plates 2 21 1 ( ) 2 2 2 Q U Q V C V C     
  • 11. Energy • The energy can be considered to be stored in the electric field • For a parallel-plate capacitor, the energy can be expressed in terms of the field as U = ½ (εoAd)E2 • It can also be expressed in terms of the energy density (energy per unit volume) uE = ½ oE2
  • 12. Some Uses of Capacitors • Defibrillators – When cardiac fibrillation occurs, the heart produces a rapid, irregular pattern of beats – A fast discharge of electrical energy through the heart can return the organ to its normal beat pattern • In general, capacitors act as energy reservoirs that can be slowly charged and then discharged quickly to provide large amounts of energy in a short pulse
  • 13. Capacitors with Dielectrics • A dielectric is a nonconducting material that, when placed between the plates of a capacitor, increases the capacitance – Dielectrics include rubber, glass, and waxed paper • With a dielectric, the capacitance becomes C = κCo – The capacitance increases by the factor κ when the dielectric completely fills the region between the plates – κ is the dielectric constant of the material
  • 14. Dielectrics, cont • For a parallel-plate capacitor, C = κεo(A/d) • In theory, d could be made very small to create a very large capacitance • In practice, there is a limit to d – d is limited by the electric discharge that could occur though the dielectric medium separating the plates • For a given d, the maximum voltage that can be applied to a capacitor without causing a discharge depends on the dielectric strength of the material
  • 15. Dielectrics, final • Dielectrics provide the following advantages: – Increase in capacitance – Increase the maximum operating voltage – Possible mechanical support between the plates • This allows the plates to be close together without touching • This decreases d and increases C
  • 16. Types of Capacitors – Tubular • Metallic foil may be interlaced with thin sheets of paraffin- impregnated paper or Mylar • The layers are rolled into a cylinder to form a small package for the capacitor
  • 17. Types of Capacitors – Oil Filled • Common for high- voltage capacitors • A number of interwoven metallic plates are immersed in silicon oil
  • 18. Types of Capacitors – Electrolytic • Used to store large amounts of charge at relatively low voltages • The electrolyte is a solution that conducts electricity by virtue of motion of ions contained in the solution
  • 19. Electric Dipole • An electric dipole consists of two charges of equal magnitude and opposite signs • The charges are separated by 2a • The electric dipole moment ( ) is directed along the line joining the charges from –q to +q p 
  • 20. Electric Dipole, 2 • The electric dipole moment has a magnitude of p ≡ 2aq • Assume the dipole is placed in a uniform external field, – is external to the dipole; it is not the field produced by the dipole • Assume the dipole makes an angle θ with the field E  E 
  • 21. Electric Dipole, 3 • Each charge has a force of F = Eq acting on it • The net force on the dipole is zero • The forces produce a net torque on the dipole
  • 22. Electric Dipole, final • The magnitude of the torque is: = 2Fa sin θ pE sin θ • The torque can also be expressed as the cross product of the moment and the field: • The potential energy can be expressed as a function of the orientation of the dipole with the field: Uf – Ui = pE(cos θi – cos θf U = - pE cos θ   p E  U  p E 