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Ampere Maxwell's equation
- 1. 4. Ampere-Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. https://www.youtube.com/channel/UC1hrAjhSKGAsWZ7LvR_rbRg Here is a link of Youtube video. You can watch this lecture on Youtube, as well.
- 2. 4. Ampere-Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. Ampere’s law is true for steady currents The Magnetic field inside the loop remains constant I , arising due to flow of charges, is called the ’conduction current’ IC B dl I 0 c
- 3. 4. Ampere and Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. Ampere’s law is true for steady currents The Magnetic field inside the loop remains constant I , arising due to flow of charges, is called the ’conduction current’ IC B dl I 0 c dl I p B Let’s there is a capacitor and the Amperian surface is like a bag and its top is open: L A Ampere’s Law
- 4. 4. Ampere and Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. Ampere’s law is true for steady currents The Magnetic field inside the loop remains constant I , arising due to flow of charges, is called the ’conduction current’ IC B dl I 0 c dl I p B Let’s there is a capacitor and the Amperian surface is like a bag and its top is open: + + + + + - - - - - - - - - - + + + + + L A Ampere’s Law
- 5. 4. Ampere and Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. Ampere’s law is true for steady currents The Magnetic field inside the loop remains constant I , arising due to flow of charges, is called the ’conduction current’ IC B dl I 0 c dl I p B Let’s there is a capacitor and the Amperian surface is like a bag and its top is open: + + + + + - - - - - - - - - - + + + + + L A Ampere’s Law
- 6. 4. Ampere and Maxwell’s Law B dl I 0 Ampere’s Law ‘The line integral of the magnetic field B around any closed loop is 𝜇0 times the net steady current I enclosed by this path” Maxwell’s Equations (1) dl I p dl P B B ds B.dl = B dl cos 0= B dl ds ds As, B is uniform at each point on the field line: ds B.dl = B (2π r) (2) Equating (1) and (2): B = 𝜇0 𝑰 2π r i.e. the magnetic field a distance r from a long straight wire carrying a steady current I. Ampere’s law is true for steady currents The Magnetic field inside the loop remains constant I , arising due to flow of charges, is called the ’conduction current’ IC B dl I 0 c dl I p B Let’s there is a capacitor and the Amperian surface is like a bag and its top is open: + + + + + - - - - - - - - - - + + + + + As there is no current flowing inside the capacitor, hence B.dl = 0. At the same point ‘P’ but with different Amperian surfaces, the B is not same. Conc: There are some gaps in the Ampere’s law. Maxwell corrected and made Ampere’s law consistent in all cases. What happens between the plates while the current I is flowing? L A Ampere’s Law
- 7. Maxwell’s Equations dl I p B + + + + + - - - - - - - - - - + + + + + E Maxwell correction to Ampere’s Law • There has to be some I existing between plates. • There are no conduction electrons between plates BUT • There is time-varying E between plates, which generates I. • The E is directed from +ve plate to –ve plate, because the amount of charge on capacitor increases with time, AND • The E between plates increases with time, as well. • He called this new current as a displacement current, Id .
- 8. Maxwell’s Equations As the amount of charge on the capacitor increases with time, hence the q charge, changes with time, produces a current: Id =dq/dt dl I p B + + + + + - - - - - - - - - - + + + + + E q EA I dq dt d EA dt 0 0 ( ) For a capacitor, , and Maxwell correction to Ampere’s Law • There has to be some I existing between plates. • There are no conduction electrons between plates BUT • There is time-varying E between plates, which generates I. • The E is directed from +ve plate to –ve plate, because the amount of charge on capacitor increases with time, AND • The E between plates increases with time, as well. • He called this new current as a displacement current, Id . ΦE d i.e. Current is produced because of changing electric flux w.r.t time OR Electric flux is generated due to the presence of E between plates.
- 9. Maxwell’s Equations As the amount of charge on the capacitor increases with time, hence the q charge, changes with time, produces a current: Id =dq/dt dl I p B + + + + + - - - - - - - - - - + + + + + E q EA I dq dt d EA dt 0 0 ( ) For a capacitor, , and Maxwell correction to Ampere’s Law • There has to be some I existing between plates. • There are no conduction electrons between plates BUT • There is time-varying E between plates, which generates I. • The E is directed from +ve plate to –ve plate, because the amount of charge on capacitor increases with time, AND • The E between plates increases with time, as well. • He called this new current as a displacement current, Id . ΦE d i.e. Current is produced because of changing electric flux w.r.t time OR Electric flux is generated due to the presence of E between plates. CONC: Current is not ZERO between plates but it is Id AND B is produced by the time varying E or Id
- 10. Maxwell’s Equations As the amount of charge on the capacitor increases with time, hence the q charge, changes with time, produces a current: Id =dq/dt dl I p B + + + + + - - - - - - - - - - + + + + + E q EA I dq dt d EA dt 0 0 ( ) For a capacitor, , and Maxwell correction to Ampere’s Law • There has to be some I existing between plates. • There are no conduction electrons between plates BUT • There is time-varying E between plates, which generates I. • The E is directed from +ve plate to –ve plate, because the amount of charge on capacitor increases with time, AND • The E between plates increases with time, as well. • He called this new current as a displacement current, Id . ΦE d Conc: Bs are produced both by a conduction current and by a time- varying field. A changing electric field induces a magnetic field x x x x x x x x x x x x B B dl d dt I E d 0 0 0 B dl I I B dl I d dt d E 0 0 0 0 ( ) Maxwell correction to Ampere’s Law is: c c i.e. Current is produced because of changing electric flux w.r.t time OR Electric flux is generated due to the presence of E between plates CONC: Current is not ZERO between plates but it is Id AND B is produced by the time varying E or Id
- 11. Maxwell’s Equations As the amount of charge on the capacitor increases with time, hence the q charge, changes with time, produces a current: Id =dq/dt dl I p B + + + + + - - - - - - - - - - + + + + + E q EA I dq dt d EA dt 0 0 ( ) For a capacitor, , and Maxwell correction to Ampere’s Law • There has to be some I existing between plates. • There are no conduction electrons between plates BUT • There is time-varying E between plates, which generates I. • The E is directed from +ve plate to –ve plate, because the amount of charge on capacitor increases with time, AND • The E between plates increases with time, as well. • He called this new current as a displacement current, Id . ΦE d Conc: Bs are produced both by a conduction current and by a time- varying field. A changing electric field induces a magnetic field x x x x x x x x x x x x B B dl d dt I E d 0 0 0 B dl I I B dl I d dt d E 0 0 0 0 ( ) Maxwell correction to Ampere’s Law is: c c i.e. Current is produced because of changing electric flux w.r.t time OR Electric flux is generated due to the presence of E between plates CONC: Current is not ZERO between plates but it is Id AND B is produced by the time varying E or Id