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Transcript
Electric Fields and Electric Potential SPH4U Fields Field: a region surrounding an object in which a force exists that will affect certain objects in that region Objects with mass generate gravitational fields. Objects with charge generate electric fields. Electric Field Lines Electric field lines indicate the direction and strength of the field at any point in the region. Electric Field Lines The direction is the direction of the force vector on a positive charge. The arrows therefore always point away from positive charges and toward negative charges. Electric Field Lines The direction is the direction of the force vector on a positive charge. The arrows therefore always point away from positive charges and toward negative charges. Electric Field Lines The strength is indicated by the density of the lines. The field is stronger in here than out here e Electric Field Strength (or Intensity) is the electric force per +1 C unit charge: Fe e q It has units of N/C (or V/m). e Electric Field Strength (or Intensity) is the electric force per +1 C unit charge: Fe e q qe Fe It has units of N/C (or V/m). e for a Point Charge So if a point charge of q2 is placed in the field generated by a point charge of q1: kq1q2 2 Fe kq1 r e 2 q2 q2 r e for a Point Charge So if a point charge of q2 is placed in the field generated by a point charge of q1: kq1q2 2 Fe kq1 r e 2 q2 q2 r e for a Point Charge So if a point charge of q2 is placed in the field generated by a point charge of q1: kq1q2 2 Fe kq1 r e 2 q2 q2 r Parallel Plates Between two charged parallel plates, the field between the plates is constant, with field lines equally spaced and perpendicular to the plates. Parallel Plates Between two charged parallel plates, the field between the plates is constant, with field lines equally spaced and perpendicular to the plates. The strength of the field depends only on the charge/unit area on the plates. Parallel Plates (The field outside the plates is zero, other than a slight “bulging” distortion on the end.) Parallel Plates (The field outside the plates is zero, other than a slight “bulging” distortion on the end.) constant e So force is also constant: Fe qe Electric Potential Energy Recall that Gm1m2 Gm1m2 FG EG 2 r r Electric Potential Energy Recall that Gm1m2 Gm1m2 FG EG 2 r r So kq1q2 kq1q2 Fe 2 Ee r r Electric Potential Energy Recall that Gm1m2 Gm1m2 FG EG 2 r r So kq1q2 kq1q2 Fe 2 Ee r r Where’s the negative? In the signs of the charges. Electric Potential Energy kq1q2 Ee r Note that Ee is negative for opposite charges that attract and positive for like charges that repel. Electric Potential Electric Potential is the is the energy per +1 C unit charge: Ee V q It has units of J/C or Volts. Electric Potential Electric Potential is the is the energy per +1 C unit charge: Ee V q qV Ee It has units of J/C or Volts. Electric Potential Difference Consider a positive point charge q being moved from position A to position B in a uniform electric field: Electric Potential Difference Consider a positive point charge q being moved from position A to position B in a uniform electric field: W Ee qVB qVA qVB VA qV V is the potential difference. Electric Potential Difference Also: W Fd qed where d is the straight-line distance parallel to the field Electric Potential Difference Also: W Fd qed where d is the straight-line distance parallel to the field (If we are moving the charge from one plate to another, d is the plate separation.) Electric Potential Difference q V q ed V e d V e d Electric Potential Difference voltage across the plates separation between the plates q V q ed V e d V e d Electric Potential Difference q V q ed V e d V e d Note the units: 1 V/m = 1 N/C More Practice “pHet Electric Field Simulation Activity” Textbook Questions • p. 343 #1, 2, 3, 4 • p. 354 #1, 2, 3 • p. 356 Practice #6