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Lecture 2 Acceleration due to gravity Forces Newton’s Laws Free Falling Objects We have worked out mathematical relationships arising from the definitions of velocity and acceleration. v v0 at 1 2 s v0t at 2 v v 2as 2 2 0 Probably the most familiar system where we observe acceleration is that due to gravity. Free Fall Definition: Freely falling object is one moving freely under the influence of gravity alone, independent of its initial motion. Objects considered to be freely falling propelled upwards propelled downwards released from rest The “free fall condition” considers gravity only: •neglects other effects such as air resistance Hammer and a paper tissue Dropped from same height, Hammer will hit the ground first Air resistance will slow the tissue down. However if we neglect air resistance both objects will hit the ground at the same time Free Falling Objects A time delay image of two spheres of very different mass falling in a vacuum. . It can be seen that, in the absence of air resistance both accelerate at the same rate, independent of mass. The acceleration due to gravity near the earths surface is known as g. This has been measured to be g = 9.80 ms-2. Free Falling Objects If we assume objects falling near the earths surface are affected only by gravity (air resistance is negligible) two basic facts govern their motion: 1. Objects accelerate at the same rate, independent of their mass, size composition. 2 . This gravitational acceleration is constant and so does not change as the object falls. Acceleration due to gravity Ignoring air resistance, an object in free fall experiences an acceleration of magnitude 9.8 ms-2. In other words the downward directed velocity increases by 9.8 ms-1 each second. So if released from rest an object has a velocity downwards after 1 second of 9.8m/s. after 2 seconds of 19.6m/s after 3 seconds of 29.4m/s v v0 at Since by convention displacement upwards is positive, but gravity acts downwards, then g = -9.8 ms-2. Acceleration due to gravity Since acceleration due to gravity is constant, motion under the action of gravity is uniformly accelerated motion, so we can use the equations relating position, displacement, velocity and acceleration already derived Example: A ball is thrown out of the window 10m above ground. What will be its velocity just before it hits the ground? 2 2 0 v v 2as v v02 2as v 02 (2) (9.8ms 2 )(10m) v 14ms 1 v 14ms 1 EXAMPLE In the absence of air resistance, you drop an object and it accelerates downward at 9.8ms-2. If instead you throw it downward, what will be the magnitude of its downward acceleration after release? 1. Less than 9.8ms-2. 2. More than 9.8ms-2. 3. 9.8ms-2. Acceleration due to gravity is constant, independent of initial velocity. Force, Acceleration & Newton’s Laws Up to now we have discussed kinematics i.e. methods for describing motion (without reference to the causes). We will now study motion and the causes of motion – dynamics. The basic physical quantities used in dynamics are force, mass and acceleration. Force: push or a pull Characteristics: •Strength or magnitude •Direction Force is a vector quantity Force A force resulting from direct contact with another object is called a contact force. For example when you push or pull an object you exert a force on it. Orthodontics: contact force applied Force is a vector quantity: magnitude and direction Force pushes or pulls teeth in a particular direction There are also non-contact forces. Gravitational, electrical and magnetic forces act through empty space. You don’t have to be standing on the surface of the earth to experience the effects of gravity. Force The force due to gravity exerted on an object is known as its weight. The SI unit of force is the Newton, N. Force can be measured with a spring balance. When a force pulls on the spring, the spring extends. A pointer attached to the end of the spring can indicate the force on a scale. Force causes Acceleration Questions: 1/ What happens to an object when there is no net force exerted on it.? 2/ What links force and acceleration? 3/ What happens to an object that exerts a force on another object? Answers are contained in NEWTON’S three LAWS. Isaac Newton ( 1643-1727) Credited with establishing a mathematical basis for the laws of motion Earlier Galileo Galilei (1564 –1642) established theories concerning moving (falling) objects Newton’s Laws All dynamics is based on Newton’s Laws. These are three empirical laws which cannot be derived from anything more fundamental. 1. When the vector sum of forces on an object is zero then the acceleration of that object is zero. Force must be applied to an object to change its velocity. 2. When the vector sum of forces is NOT zero force is related to acceleration. Force = mass x acceleration. 3.The third law describes the pairs of forces that interacting objects exert on each other. If we push an object it pushes back with an equal force but in the opposite direction. NEWTON’S FIRST LAW “Any object will remain at rest or in motion in a straight line with constant velocity unless acted upon by an outside force” There is no distinction between an object at rest and an object moving with constant velocity. v=0 v = const. } No net Force Constant velocity means both constant magnitude (speed) and constant direction. In uniform circular motion, magnitude of the velocity is constant but direction is changing. object is acccelerating There is a force acting on an object in circular motion. Force Newton’s First Law “Any object will remain at rest or in motion in a straight line with constant velocity unless acted upon by an outside force” This is not as self evident as it may seem. It actually seems counter intuitive because it means that: once an object is set in motion with uniform velocity, no force is needed to keep it moving. This seems contrary to everyday experience. For example, If you push a book across a table, the book does not keep moving indefinitely after it has left your hand. It slows down. BUT as we will see later, this is due to frictional forces slowing it down. Equilibrium and Newton’s First Law Imagine a tug of war match with each team equally matched. Both teams pull on the rope with equal strength they each exert the same magnitude of force on it, but in opposite directions. Fleft Fright In this case the knot in the middle of the rope does not move. It does not accelerate. The rope is in equilibrium. We can write - Fleft = Fright This means Fleft + Fright = 0 In equilibrium ΣF=0 Greek letter “S” represents the sum Newton’s Second Law “The acceleration produced by forces acting on an object is directly proportional to and in the same direction as the net external force inversely proportional to the mass of the object” a Fextnet m Fextnet ma Newtons (N) m = mass of the object F a=F/m (kg) (ms-2) Newton’s Second Law Equation F=ma means that mass, in addition to being a measure of the amount of matter in an object, is a measure of how difficult it is to move an object or its inertia. Inertia is the tendency of an object at rest to remain at rest of an object in motion to remain in motion with its original velocity. The greater the mass of a body, the less effect a given force has. The unit of force, the Newton, is defined as follows: A force of 1N acting on a mass of 1kg produces an acceleration of 1m/s2. F = ma so (1N) = (1kg)(1ms-2) = 1kgms-2 Newton’s Second Law If a number of forces act on an object at the same time, Newton’s second law applies to the sum of the forces and is written. SF ma Thus when working out problems involving a number of forces, it is best to calculate the resultant force and then set that equal to ma. Mass and Weight Mass is a measure both of how much matter an object contains how difficult it is to move. Weight however is the force exerted by gravity on a body. Thus a heavy truck is difficult to push because of its mass difficult to lift due to its weight. When an object falls under the influence of gravity it accelerates downwards at the rate: a = g = 9.80 m/s2 Force produces an acceleration given by F = ma Mass and Weight But if the force on an object due to gravity is weight, w, and it accelerates at g = 9.8 ms-2 then, we can write, w mg This equation gives the gravitational force on an object whether it is in freefall or not. Any object with mass “near” the surface of the earth feels a gravitational force (weight), w = mg. Newtonian Gravity m1m2 F G 2 r G = 6.67 10-11 N m2 kg-2 MEm F G 2 ma mg r g 9.81ms 2 ME g G 2 RE Example Mass of a person is 65kg. What is his weight? His weight is given by w =mg w = 65kg * 9.8m/s2 = 637kg m/s2 = 637N Example On the surface of the moon the force of gravity is approximately 1/6 of that on earth. What is the weight of the same person on the moon. Mass of a person on Earth is 65kg Weight of this person on the moon is w = mgm weight (w) = 65kg * {(1/6) 9.8m/s2} w =106.2kg.m/s2 = 106.2N Example. A tennis ball and a golf ball are simultaneously dropped from a tall building of height 120m. Neglecting air resistance, determine (a) the speed with which each ball hits the ground. (b) The time taken for each to reach the ground (g = 9.8 ms-2) all objects regardless of their mass or size fall freely with an acceleration g = 9.8ms-2 v v 2as 2 2 0 v0 = 0 Acceleration and displacement are in the direction such that a = -g and s = -120m Example A car has a maximum acceleration of 4 ms-2. What will its maximum acceleration be while towing a second car of the same mass. F=ma a = 4ms-2 F=MaN where M is the combined mass of the cars F F aN M 2m ma a aN 2m 2 4ms 2 aN 2ms 2 2 EXAMPLE A ball is thrown upward at 20m/s from a window 60m above the ground. (a) How high does it go? (b) When does it reach its highest point? (c) When does it hit the ground? Here we will take the upward direction as the positive direction. This means any vector quantities pointing upward (initial velocity) are positive while vector quantities pointing down (acceleration due to gravity) are negative.