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Questions to think about • Why do balls fall • What pushes a flying ball in an upwards direction • Do objects fall sideways • Is the moon falling What pulls things down? Every object in the Universe attracts every other object due to g r a v i t y . • • • Gravity is a type of interaction. The effect is proportional to the mass of each object. The effect depends on the distance between the objects. Near the earth’s surface, the gravitational force (Fg), exerted on an object is proportional to the mass (m) of the object only Fg = m ⋅ g Geeee ! Fg = m ⋅ g g • Vector g, describes the local strength of gravity (the gravitational field). • At the surface of the earth, vector g is directed toward the center of the earth and its magnitude has a value of 9.8 m/s2. g • If the object does not interact with other objects besides the earth, its acceleration (with respect to the ground) has a value equal to g. Consistently, g is often referred to as the acceleration due to gravity. g Warning! Do not confuse acceleration due to gravity with the acceleration of the object. g Weight The same symbol g, is traditionally used for the actual acceleration due to gravity in any reference frame (not necessary inertial). The weight of an object is defined as the product of the mass of an object and the acceleration due to gravity W=m⋅g Puzzle 1. Compare your weight on earth with the gravitational force exerted on you. W = 0 ≠ Fg Puzzle 2. Compare your weight in space (earth’s orbit) with the gravitational force exerted on you. W = Fg free fall (from 60 m) vg t [s] a [m/s2] v [m/s] x [m] 0.00 0.0 -9.8 0.0 60.0 1.0 1.00 -9.8 -9.8 55.1 acceleration a=g velocity v = v0+a⋅t 2.00 -9.8 -19.6 40.0 2.0 3.00 3.0 -9.8 -29.4 15.9 position x = x0+v0⋅t+½⋅a⋅t upward throw vg t [s] a [m/s2] v [m/s] x [m] 3.00 3.0 -9.8 0.0 60.0 2.0 2.00 -9.8 -9.8 55.1 acceleration a=g velocity v = v0+a⋅t 1.00 -9.8 -19.6 40.0 1.0 0.00 0.0 -9.8 29.4 15.9 position x = x0+v0⋅t+½⋅a⋅t projectile motion The initial velocity has both a non-zero horizontal component and a non-zero vertical component. Vertical acceleration affects the vertical component of velocity. The horizontal component of velocity is constant. vertical component y v v g g v v g g horizontal component x The object moves along a parabolic trajectory (path), dependent on the initial position, initial velocity, and acceleration. Why doesn’t the moon fall? Orbit: 384,403 km Speed: 1.03 km/s With zero initial velocity, an object falls straight down. 7.9 km/s With a small horizontal velocity (so that the surface of the earth might be considered flat), objects fall down along a parabolic trajectory. With a greater horizontal component, the trajectory becomes elliptical with the acceleration always directed toward the earth’s center. With a precise horizontal velocity, the object will move along a circular orbit.
