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Motion in Electric Fields

Motion in Electric Fields. SACE Stage 2 Physics. B. A. 10 m. q = +2 C. q = +4 C. Energy Changes in Electric Fields. Consider the movement of a small charge in a uniform electric field. To lift a charge towards the top (positive) plate we exert an external force

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Motion in Electric Fields

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  1. Motion in Electric Fields SACE Stage 2 Physics

  2. B A 10 m q = +2 C q = +4 C Energy Changes in Electric Fields Consider the movement of a small charge in a uniform electric field To lift a charge towards the top (positive) plate we exert an external force Fext= FE in size (opposite direction).Increase in electrical Potential Energy (EP) = Work Done by external Force = Fext x S = qE h (since F = E.q) E= 10 N C-1

  3. B A E= 10 N C-1 10 m q = +2 C q = +4 C Energy Changes in Electric Fields The work done on each charge is,

  4. Energy Changes in Electric Fields We define the Work done (in moving a small positive test charge from one position to another) per unit positive charge as the change in electric potential, V. Work done in moving each charge, +2C Charge, +4C Charge,

  5. B A E= 10 N C-1 10 m q = +2 C q = +4 C Energy Changes in Electric Fields We say the top plate is 100J/C higher in potential than the bottom plate. A potential difference of 1J/C is also referred to as 1 volt. ie. we define the unit of potential difference as, one volt (V) equals one joule per coulomb (J.C-1)

  6. 100V 0V +4 C Energy Changes in Electric Fields Both charges are at the same potential compared to the bottom plate. They are on an equipotential line. The electric field is affecting the potential of the charges in a similar way. Each charge is at the same potential relative to the bottom plate. The larger charge has the higher potential energy. Eg, consider the 4 C charge

  7. Electron Volt Work done when a charge of one electron moves through a potential difference of 1 V is one electron volt (e.V). (Is a unit of energy) The equivalent energy is: q = e = 1.6 x 10-19C, and 1 V = 1 J C-1 hence 1 eV = 1.6 x 10-19C x 1 J C-1 ie. 1 eV = 1.6 x 10-19 J

  8. V2 s Separation between the plates = d DV FE = qE V1 Relationship Between E and ΔV Calculate the work done by considering the force that needs to be exerted to move the charge against the field. W = Fs =qEs Calculate the work done using voltage W = qV

  9. Relationship Between E and ΔV These expressions for the Work Done should be the same. Therefore qEs = qV ie. Electric field strength is equal to the number of volts potential difference per metre of distance in the field

  10. Electric Field Strength Between Parallel Plates For parallel plates separated by a distance d, with a potential difference V, the uniform electric field within the plates has strength: We sometimes use an alternate unit for E.

  11. Electric Field Strength Between Parallel Plates Example – 2 parallel plates separated by 0.1m have a potential difference ΔV = 100V. What is the Electric Field strength between the plates?

  12. Motion in an Electric Field Charged particles that move through electric fields behave the same way as mass does in a gravitational field. The corolation is as follows,

  13. Electric Field + + + + + + + + + + + + + 1000V q=10μC M=0.1g 0.1m 0V FE - - - - - - - - - - - - Motion in an Electric Field Consider a positive charge placed in a uniform electric field, as shown in the diagram below. (Note the direction of the Electric field is the direction that a positive charge would move in that field) Find the velocity of the charge after it has travelled a distance of 5 cm. Use the following information:

  14. Electric Field + + + + + + + + + + + + + 1000V q=10μC M=0.1g 0.1m 0V FE - - - - - - - - - - - - Motion in an Electric Field

  15. Motion in an Electric Field Can use the equations of motion to determine the speed of particle after travelling for 5cm.

  16. Electric Field + + + + + + + + + + + + 1000 V A 0.05 m 0.1 m B 0 V - - - - - - - - - - - - Motion in an Electric Field Can also determine the velocity by using the change in kinetic energy of the particle.

  17. Electric Field + + + + + + + + + + + + 1000 V A 0.05 m 0.1 m B 0 V - - - - - - - - - - - - Motion in an Electric Field To find the potential difference between A and B, rearrange the equation,

  18. Motion in an Electric Field Now calculate the kinetic energy at point B. If the charge is released at rest K at B (Gain in K) = electric Ep lost

  19. Motion in an Electric Field The work done by the field on the charge can be calculated easily because it is equal to the gain in kinetic energy by the charge.

  20. Motion Perpendicular to the Electric Field Assumptions - ignore fringe effects (ie. assume that the field is completely uniform) - ignore gravity (it is quite easy to show that the acceleration due to gravity is insignificant compared with the acceleration caused by the electric field). -Before entering electric field, the charge follows a straight line path (no net force) -As soon as it enters the field, the charge begins to follow a parabolic path (constant force always in the same direction) - As soon as it leaves the field, the charge follows a straight line path (no net force)

  21. Straight line parabola Straight line +q Motion Perpendicular to the Electric Field Horizontal Component of the velocity(H component)

  22. Motion Perpendicular to the Electric Field Vertical Component of thevelocity (v component) As it is initially travelling horizontally, vy1 = 0 m/s

  23. Electric Field + + + + + + + + + + + + v Direction of F on + Direction of F on - +q -q v - - - - - - - - - - - - - - - Motion Perpendicular to the Electric Field The direction of the force depends on the charge on the particle. However, the force at all times is parallel (or "anti-parallel') to the field.

  24. Electric Field + + + + + + + + + + + 2000 V - - - - - - - - - - - - - d = 10 cm 0 V L = 10 cm Electron Beam v = 5.9 x 107 m/s Motion Perpendicular to the Electric Field Example: Consider a negative charge entering a uniform electric field initially perpendicular to the field. The acceleration will always be in the opposite direction to the electric field lines. Find: (a) The time taken for an electron to pass through the field (b) The sideways deflection of the electron beam in the field. (c) The final velocity of the electrons when they leave the field. (d) The trajectory (path) of the electron beam on exit from the field.

  25. Electric Field + + + 2000 V - - - - - - - - - - - - - d = 10 cm 0 V L = 10 cm Electron Beam v = 5.9 x 107 m/s Motion Perpendicular to the Electric Field • The time taken for an electron to pass through the field. • v (perpendicular) does not change as the force only acts parallel to the field. • The time taken for the beam to pass through the field is given by

  26. Motion Perpendicular to the Electric Field • The sideways deflection of the electron beam in the field. • To find the sideways deflection, we need to consider the component of the velocity || to the field. Need to find the acceleration,

  27. Motion Perpendicular to the Electric Field Can now use the value for acceleration to substitute in to the following equation to determine the deflection. The deflection of the electron beam is 5.1 x 10-3m towards the +’ve plate.

  28. Motion Perpendicular to the Electric Field (c) The final velocity of the electrons when they leave the field. Need to use a vector diagram to calculate Final velocity = final  velocity + final || velocity Need to calculate vparallel,

  29. v v v  Motion Perpendicular to the Electric Field By Pythagoras’ Theorem, The electron beam leaves the field at 5.9 x 107ms-1 at 5.8o towards the +’ve plate.

  30. Motion Perpendicular to the Electric Field (d) The trajectory (path) of the electron beam on exit from the field. As soon as an electron leaves the field there is no force on it and hence the path of the beam is a straight line. (Newton's First Law). ie. Velocity is in the same direction as the final velocity in part (c)

  31. Use of Electric Fields in Cyclotrons The cyclotron is a device for accelerating particles to high velocities, generally for the purpose of allowing them to collide with atomic nuclei in a target to cause a nuclear reaction. The results of these reactions are used in research about the nucleus, but can be used to make short lived radioactive isotopes used in nuclear medicine.

  32. Use of Electric Fields in Cyclotrons Main components of a cyclotron There are 4 main parts to a cyclotron 1. The ion source 2. Two semicircular metal containers called 'dees' because of their shape 3. An evacuated outer container 4. An electromagnet.

  33. Use of Electric Fields in Cyclotrons The ion source Produces the charged particles for the cyclotron. Done by passing the gas over a hot filament where electrons being emitted can ionise the gas. More modern cyclotrons pass the gas to be tested through an electric arc.

  34. Use of Electric Fields in Cyclotrons Semicircular Metal Containers, or 'dees‘ The dees are two hollow dee shaped metal electrodes with their straight edges facing. A large alternating voltage is applied between the dees (~ 1KV and 10 MHz). The high voltage establishes an electric field between the dees which reverses every time the alternating current reverses. Note that there is no electric field within the dees - there is no electric field inside a hollow conductor.

  35. Use of Electric Fields in Cyclotrons Evacuated outer container The dees are placed within an outer evacuated container so that the ions being accelerated do not suffer energy loses due to collisions with air molecules, or that they are not scattered away from their intended paths by the collisions. In addition to reducing the beams intensity, scattered ions may collide with the walls at high energies. This can cause the walls to become radioactive.

  36. Use of Electric Fields in Cyclotrons The electromagnets. The electromagnets produce a strong magnetic field , but unlike the electric field, this field can pass through the dees. This magnetic field causes the ions to move in a circular pathway.

  37. Use of Electric Fields in Cyclotrons Principles of Operation Ions in the cyclotron are accelerated when they cross the electric field between the dees. The magnetic field in the apparatus ensures the ionic particles travel a circular path. The particles will the repeatedly keep crossing the Electric field which only exists between the dees.

  38. Use of Electric Fields in Cyclotrons At position A, the ionic particle is accelerated to the right dur to the electric field. It then enters the dee where there is no electric field (no electric field inside of a conductor). The magnetic field causes the ionic particle to traverse a circular path. While doing so the Electric field changes direction due to the alternating current across the dees.

  39. Use of Electric Fields in Cyclotrons At position B, the ionic particle is accelerated across the gap and then enters the other side of the dee where there is only a magnetic field to keep the ionic particle travelling in a circular path. The Electric field changes again to the opposite direction.

  40. Use of Electric Fields in Cyclotrons The particle is now at C where the whole process is repeated. The radius of the circle is only depended upon the velocity of the ionic particle and as it speeds up the radius becomes bigger.

  41. Use of Electric Fields in Cyclotrons The accelerated ionic particles can be evacuated by placing deflecting electrodes that will cancel the magnetic field in that region so the path of the particles becomes a straight line.

  42. Use of Electric Fields in Cyclotrons The Energy Transfer to the ions by the Electric Field. When the ions pass the gap, their speed increases, hence they have a gain in kinetic energy. Work done on the ion is given by, The work done is equal to the increase in Kinetic Energy. As the particles pass the gap many times, they end up with a large increase of Kinetic Energy.

  43. Use of Electric Fields in Cyclotrons The energetic protons are bombarded with stable atoms of carbon, nitrogen, oxygen, or fluorine to produce certain radioactive forms of these elements. The radioactive forms are combine with elements commonly found n the body such as glucose. After small amounts are administered into a patient, it can then be traced to determine the functions of the body. It can also be used in the treatment of certain kinds of cancer in certain organs where the chemical tends to concentrate.

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