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Transcript
More Fields Electric Fields at a Location vs. Electric Fields around a Point Charge Electric Fields at a Location vs. Electric Fields around a Point Charge • Electric Fields at a Location: Measures force on a test charge at a fixed location. • It is a vector quantity. • Formula: F E q qt Electric Fields at a Location vs. Electric Fields around a Point Charge • Electric Fields around a Point Charge: Measures field intensity in all directions at a given distance from the centre of a point charge. kq1 • Formula: E r 2 • It is a scalar quantity. NOTE • You can use either formula to determine field intensity. If it is at a point/location, it is a vector. If it is around a point, it is a scalar (as it radiates outward). Electric Fields around a Point Charge • This equation allows us to calculate the intensity of an electric field (in N/C) at a known distance “r” from a point charge. • Formula: kq1 E 2 r • k is still 8.99 x 109 Nm2/C2 • r is the distance from the point charge (q) • q1 is the charge of the source of field (C) Example 1 • What is the intensity of the electric field 2.60cm from a charge of 1.50 x 10-6 C? • 1.99 x 107 N/C Example 2 • Find the electric field intensity midway between a +5.0 μC charge and a -3.5 μC charge. Assume they are 5.0cm apart. • ***NOTE: Since these charges are attractive we call this COMPLIMENTARY FIELDS. To find the NET electric field, we ADD the field intensities together (use magnitudes- ignore the “sign” of the field). • 1.22 x 108 N/C Practice Problems • Questions 20-25, page 655 Example 3 • Three charges, A (+6.0 μC), B (-5.0 μC), and C (+6.0μC) are located at three corners of a square as shown below. • What is the net field intensity at the 4th corner? NOTE: The 4th corner is NOT a charge, just a point in space. • Step 1: Create an FBD to represent individual fields as vectors at the 4th corner. (Assume positive test charge) • Step 2: Find the field intensities at each corner. • Step 3: Use vector addition to find the net field intensity at D. (Pythagorean theorem and inverse tan). • Enet = 2.15 x 107 N/C [E45’N] Practice Problems • Questions 26 to 30 • Page 655 Gravitational Field Intensity near a Point Mass Formula: Gm1 g 2 r G is universal gravitation constant: 6.67 x 10-11 Nm2/kg2 r is the distance from centre (m) m1 is the mass of the source of field (kg) Example 1 • Calculate the gravitational field intensity at a height of 300.0 km from Earth’s surface. • ** Convert km into m • ** remember to find height from CENTRE of Earth • g = 8.94 N/kg Practice Problems • Page 657, questions 31, 32, 33, 37 • Can also do page 649, q18 easily now
