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SPH 4U REVIEW SPH 4U Final Exam Part 1: Multiple Choice, 30 Marks Part 2: Extended Response (Calculations), 46 Marks over 5 questions Part 3: Inquiry, 10 Marks over 5 questions Part 4: Communication, 16 Marks over 5 questions Part 5: Application, 16 Marks over 5 questions Unit # 1: Dynamics Topics covered: Kinematics & Newton’s Laws Review Components and Projectile Motion Relative Motion Components & Projectiles Newton in 2-D Inclined Planes String & Pulley Centripetal Motion 1.9 x 102 m Components & Projectiles A Euro 2012 player, kicks at soccer ball at an angle of 35o above the horizontal, with an initial speed of 100 mph (161 km/h). What is the range, if the ball lands at the same height? 74 m/s2 [E 26o N] Newton in 2-D Three dogs pull on a toy, with mass 0.50 kg. The first dog pulls 25 N [N 30oE]. The second dog pulls 12 N [S]. The third dog pulls 22 N [N 72oE]. Find the acceleration of the toy. 2.7 m/s2 Inclined Planes A 35 kg box is on a ramp, as shown. If the coefficient of kinetic friction between the box and the ramp is 0.12, determine the acceleration of the box. 23o 2 m/s2 String & Pulley Two masses, m1 and m2, are attached to a string, which passes over a frictionless pulley. m1 is 10 kg and m2 is 6 kg. Calculate the tension in the string and the acceleration of the masses. Tt = 1.4 x 102 m; Tb = 1.6 x 102 m Centripetal Motion A 1.2 kg mass is twirled in a circle, on the end of a string of length 0.80 m. The mass completes 2.0 rotations per second. Determine the tension(s) in the string. T = 2.3 x 106 s Orbits The Earth(m = 5.98 x 1024 kg) and the Moon (m = 7.35 x 1022 kg) are separated at their centres by a distance of 3.8 x 108 m. Determine the period of the Moon’s rotation about Earth. Unit # 2: Energy & Momentum Topics covered: Linear Momentum Impulse Conservation of Linear Momentum in 1-D and 2-D Work Kinetic Energy Gravitational Potential Energy Hooke’s Law Elastic Energy Total Energy; Conservation of Energy Elastic and Inelastic Collisions p = 6.4 kgm/s [N] Linear Momentum What is the momentum of a heron, with a mass of 1.2 kg, travelling 5.3 m/s [N]? J = 5.7 kgm/s [up] Impulse A 0.430 kg ball strikes the ground with a velocity of 9.00 m/s [down]. It rebounds with a velocity of 4.23 m/s [up]. Determine the impulse of the ball. v2‘ = 6.94 m/s Conservation of Momentum in 1-D A cue ball with mass (0.17 kg) and velocity of 6.4 m/s [forward] collides with a stationary pool ball with a mass of 0.16 kg. Determine the velocity of the second pool ball, if the cue ball rebounds with a velocity of 0.125 m/s [backward]. v2’ = 16 m/s [W 37o S] Conservation of Momentum in 2-D A car, travelling 28 m/s [N], with mass = 1400 kg, has a glancing collision with a truck, mass 2300 kg, travelling 25 m/s [S]. If the car is deflected [N 55o E] at 26 m/s, find the velocity of the truck. W = 1900 J Work A newspaper carrier pulls a wagon with a force of 250 N at an angle of 45o to the horizontal. Assuming no friction, how much work is required to move the wagon 11 m? x = 0.14 m Conservation of Energy The bumper of a 2200 kg car has a spring constant of 5.1 x 106 N/m. The car is moving 6.7 m/s [forward] when it crashes into a solid bring wall. How much will the bumper be compressed when the car comes to a complete stop? Inelastic Elastic and Inelastic Collisions Two toy trains (m1 = 0.300 kg, m2 = 0.600 kg) collide on a straight section of a model rail track. Train 1 is travelling at 2.5 m/s when it strikes train 2, which is at rest. After the collision, train 1 has a speed of -0.7 m/s. Determine whether the collision is elastic or inelastic. Unit # 3: Gravitational, Electric, Magnetic Fields Topics covered: Coulomb’s Law Electric Fields Electric Potential Charged Particles in Electric Fields Parallel Plates Millikan Magnetic Fields (Right Hand Rules) Magnetic Force; The Motor Principle Faraday’s and Lenz’s Laws Charged Particles in Magnetic Fields 5.83 x 10-1 N towards q2 Coulomb’s Law Three point charges, q1 = 3.6 x 10-6 C, q2 = 2.7 x 10-6 C, q3 = 4.5 x 10-6 C, are arranged on the x-axis. The distance between q1 and q2 is 30 cm, and the distance between q2 and q3 is 20 cm. Find the total force on q3. Electric Fields Draw the electric field created by the point charges below. 1 x 109 N/C, 1.2 x 108 N/C, 1.1 x 107N/C Electric Fields A point charge of +3.0 x 10-6 C creates an electric field. What is the electric field strength 0.5 cm away? 1.5 cm away? 5.0 cm away? V = 16 V Electric Potential 2.1 x 10-5 J of work are done in moving a point charge, q = 1.3 x 10-6 C, against an electric field. Determine the potential difference between the initial and final positions. Parallel Plates Draw the electric field around the parallel plates. + + + + - - - - v = 6.9 x 105 m/s Charged Particles in Electric Fields A set of parallel plates with a potential difference of 2.5 x 103 V is used to accelerate a proton from rest. Determine the velocity of the proton when it has reached the negative plate. Magnetic Fields Draw the magnetic field around the objects below. N Earth S Magnetic Fields A current-carrying wire Magnetic Fields A solenoid Magnetic Fields Force on a current-carrying wire in a magnetic field 3.3 x 10-5 T Magnetic Fields Find the strength of a magnetic field 1.5 cm away from a straight conductor carrying a current of 2.5 A. 4.7 x 10-3 T Magnetic Fields Find the magnetic field strength of a solenoid that is 30 cm long with 1500 turns, carrying a current of 0.75 A. F = 64 N Magnetic Force A wire, carrying a current of 15 A is in a magnetic field of 2.5 T, at an angle of 90o, for a length of 1.7 m. Determine the force on the wire. 4.1 x 10-4 N/m Magnetic Force Two wires are 1.4 cm apart. Wire one is carrying a current of 3.0 A, wire two is carrying a current of 9.5 A. Find the force per unit length. B = 0.28 T [into the page] Charged Particles in Magnetic Fields A proton enters a magnetic field with a velocity of 1.0 x 106 m/s [down], and experiences a force of 4.5 x 10-14 N [right]. Determine the magnitude and direction of the magnetic field. Unit # 4: The Wave Nature of Light Topics covered: Wave Theory Types of Waves Electromagnetic Waves Universal Wave Equation Refraction; Snell’s Law Dispersion Polarization Interference Theory Young’s Double Slit Equation Thin-Film Interference Diffraction 0.15 m Universal Wave Equation Microwaves have a frequency of 2.0 x 109 Hz. Determine the wavelength of a microwave. 13o Snell’s Law Find the angle of refraction for light travelling from air (n = 1.00) to diamond (n = 2.42) if the angle of incidence is 32o. 5.6 x 10-7 m Young’s Double Slit Experiment Find the wavelength of light used if the third order minimum is located 21 cm from the central maximum on a screen 90 cm away. The separation between the double slits is 6.0 x 10-6 m. Bright: 1.45 x 10-7 m; Dark: 2.9 x 10-7 m Thin Lens Interference Light of wavelength 580 nm strikes a soap film, which is surrounded by air. What is the minimum thickness needed to produce a light spot? A dark spot?