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RRHS PHYSICS 12 UNIT 1 VECTORS © JIM BURKE RRHS PHYSICS 12 TABLE OF CONTENTS Module 1.1 Displacement and Velocity Vectors ....................................................................... 3 1.1.1 Introduction to 2D Vectors ...................................................................................... 3 1.1.2 Displacement Vectors and Vector Algebra .......................................................... 12 1.1.3 Velocity Vectors.................................................................................................... 24 1.1.4 Module Summary ................................................................................................. 32 Module 1.2 Force Vectors.......................................................................................................... 33 1.2.1 Dynamics Problems in 2D .................................................................................... 33 1.2.2 Inclined Planes ..................................................................................................... 39 1.2.3 Module Summary ................................................................................................. 46 Module 1.3 Equilibrium .............................................................................................................. 47 1.3.1 Translational Equilibrium ...................................................................................... 47 1.3.2 Torque and Rotational Equilibrium ....................................................................... 55 1.3.3 Module Summary ................................................................................................. 65 Module 1.4 2D Collisions ........................................................................................................... 66 1.4.1 Conservation of Momentum ................................................................................. 66 1.4.2 Elastic and Inelastic Collisions ............................................................................. 70 RRHS Physics Page 2 Module 1.1 Displacement and Velocity Vectors 1.1.1 Introduction to 2D Vectors In unit 2, you discussed two kinds of quantities --- vectors and scalars. A scalar is a quantity that has only magnitude (size); it does not have a direction. For example, temperature and mass have no direction associated with them. A vector is a quantity that has both magnitude and direction. For example, displacement, velocity, acceleration, force, and momentum are all quantities for which it is important to know the direction. A vector quantity is denoted by placing an arrow over the symbol ( d ); when typing, a vector quantity can be denoted by using boldface (d). In this manual, we will use the arrow notation. In units 2 and 3, you talked briefly about vectors in one dimension. In one dimension, we assigned directions to vectors using positive and negative signs. In this unit, we will be extending that analysis to two dimensions. A vector in two dimensions is not just a single number. In two-dimensional space a vector is actually represented with two numbers, one for each dimension. You have used an x y coordinate system in math, and you know that two numbers are needed to specify a position on one of these graphs. Likewise, two coordinates are needed to specify a vector in twodimensional space. These coordinates are referred to as components. Consider the diagram below, where east is represented by the positive x direction and north is represented by the positive y direction.1 1 In physics we usually use compass directions in conjunction with a traditional x-y plane since we are dealing with the actual motion of objects in real space. RRHS Physics Page 3 d Figure 1: Vector Components The position vector d in Figure 1 represents a step in space from the origin to some point whose location is given by the ordered pair (d x , d y ) - d x and d y are known as the components of d . As with one dimensional vectors, the direction of components can be specified with a positive or negative sign. The symbol d represents both of these components together. We will use the symbols d x and d y to refer to the magnitude of the components; the symbols d x and d y will be used to include the direction by using a positive or negative sign. Instead of representing a two-dimensional vector by using both of its components, it is often convenient to represent a vector by an arrow that indicates the direction of the vector. The vector d shown in Figure 1 can then be described using a magnitude d (the ``length'' of the vector) and an angle (the direction of the vector). Note that if we know the magnitude d and the angle , we can use sin and cos functions to solve for d x and d y in the above diagram. Trigonometry Review Consider the following right angle triangle: RRHS Physics Page 4 Figure 2: Right Angle Triangle Trigonometry Review Where The hypotenuse is the side across from the right angle (the longest side). The opposite side is the side across from the angle θ. The adjacent side is the side joining the angle θ and the right angle. cos adjacent hypotenuse sin opposite hypotenuse tan opposite adjacent Also, remember that the lengths of the sides can be related to one another using the Pythagorean Theorem c 2 a 2 b2 or c a 2 b2 where c is the hypotenuse of the triangle. Example In Figure 1, assume that the angle in the diagram is 30.0 and the magnitude of the position vector is 7.2 cm. Calculate the components d x and d y . Solution RRHS Physics Page 5 By definition, components must be perpendicular to one another 2 ; therefore, the above diagram is a right angle triangle and we can apply the basic trigonometric functions. Since we know the hypotenuse of the triangle (7.2 cm), we can use the cosine function to calculate the adjacent side of the triangle ( d x ) and the sine function to calculate the opposite side of the triangle ( d y ): adj hyp d cos x d d cos 30.0 x 7.2 d x 6.2cm cos sin sin sin 30.0 opp hyp dy d dy 7.2 d y 3.6cm In other words, the location identified by the position vector identified by d can also be reached by going 6.2 cm to the east and 3.6 cm to the north. When calculating components, we will often need to identify the direction of the components using positive or negative signs. East (positive x-direction) and north (positive y-direction) will be considered positive. West (negative x-direction) and south (negative ydirection) will be considered negative. For the example above, since the directions of the components are east and north, both should be positive. In the above example, we drew a sketch of the vector and used trigonometry to calculate the components. Vectors can also be drawn using scale diagrams, where a protractor can be used to orient the vector correctly and an appropriate scale can be used to represent the vector. For example, a scale of 1 cm for every 5 m can be used; a 30 m displacement vector would then be drawn with an arrow that is 6 cm long. The components can then be drawn in and measured with a ruler. When drawing a vector, the arrow indicates the direction of the vector. The arrow is referred to as the head of the vector and the tail is at the other end. 2 Since they are parallel to the axes in the coordinate system. RRHS Physics Page 6 Figure 3: Vector head and tail RRHS Physics Page 7 Check Your Learning Calculate the components for each of the following vectors: RRHS Physics Page 8 Expressing Direction There are different conventions for describing the direction of a vector. For the examples that follow, assume that 30o in Figure 1. 1. In math, you may have described vector directions as a counterclockwise rotation from the positive x-coordinate (east using compass directions). In Figure 1, the direction of the vector would then be 30o . Using this convention, north would be 90o and south would be 270o . 2. Bearings are another way of expressing directions and are often used in navigation. In this system, north is 0o and all directions are measured clockwise from this reference direction. In this system, the direction of the vector in our diagram would be 60o . 3. The last convention we will discuss is the one that we are going to use. This convention describes a direction as a rotation from one of the four reference directions (north, east, south, west). The direction of the vector in our diagram would now be 30o north of east. (or 30o N of E) This means that a vector that was pointed east was rotated 30o toward the north. This convention is convenient because there is no ambiguity about what the reference direction ( 0o ) is. The direction in the diagram could also be expressed as 60o east of north. A slightly different way of expressing 30o north of east would be to say E 30o N - this can be interpreted as “go east and then rotate 30o toward the north” for the proper vector direction. The textbook that accompanies this manual uses this last convention. RRHS Physics Page 9 Check Your Learning State the direction for each of the following vectors: RRHS Physics Page 10 1.1.1 In Class or Homework Exercise 1. Break the following vectors into components: a. 45 km in a direction 25 S of E; b. 74 km, 35 E of N 2. A bug crawled 34.0 cm E, then 48.5 cm S. What is the bug’s displacement from his starting point? 3. A ship leaves its home port expecting to travel to a port 500. km due south. Before it can move, a severe storm comes up and blows the ship 100. km due east. How far is the ship from its destination? In what direction must the ship travel to reach its destination? RRHS Physics Page 11 1.1.2 Displacement Vectors and Vector Algebra Since position and displacement vectors can be easily visualized and directly represented using vector diagrams, it is these types of vectors that will be used in this section to introduce vector addition and subtraction; the information here can, however, be applied to any kind of vector. Since vectors are not single numbers, our usual laws of algebra cannot be applied to them; in other words, we cannot simply add the magnitude of two vectors together to obtain a total magnitude. Vector algebra requires the use of a vector diagram. Vector Addition What does it mean to add two vectors? Consider displacement vectors a and b which represent successive displacements of a person walking. a 3 b The addition of these two displacements (the total displacement) should tell us where the person is at the end of his journey relative to where he started. We will use c to represent the total displacement: c a b To help visualize this, we must draw a vector addition diagram. Since the person completed displacement a and then completed displacement b , we draw the second vector where the first one ends. 3 To simplify notation, a and represent displacement. RRHS Physics b are being used here instead of the standard d with subscripts to Page 12 b a Figure 4: a b Vectors can always be moved around (by sliding them) when drawing a vector diagram, as long as their direction remains the same. The total displacement c (from where he started to where he ended) can then be drawn. c b a Figure 5: a b c This diagram represents the vector equation a b c . When we add two scalars together, the answer that we get is referred to as a sum. When we add two vectors together we get what is referred to as a resultant vector. So when we say that a b c , c is the resultant vector that goes from where we started to where we ended. It is important to note that the vector equation a b c tells us how to draw the vector diagram shown in Figure 5, but that is all it should be used for. Numbers cannot be substituted into a vector equation to be solved algebraically. When drawing a vector addition diagram, it is important to remember two things: 1. The vectors being added must be drawn head to tail. 2. The resultant vector goes from the tail of the first vector to the head of the second vector (from where you started to where you ended). RRHS Physics Page 13 Check Your Learning Given the following vectors, draw a vector diagram to represent each of the following vector equations (where x is an unknown vector in each case): c a b a. a b x b. b c x c. a b c 0 d. a x b e. x c a RRHS Physics Page 14 It is possible to obtain the magnitude and direction of the resultant from the diagrams that were completed in the Check Your Learning by drawing scale diagrams with a ruler and protractor; however, we will be using an algebraic approach to solve this type of problem by looking at the components of the vectors. If we redraw Figure 4 and add the components (as dotted lines) of each vector, we get b a Figure 6: Vector Addition Remember that the vector a actually represents the components (ax , a y ) ; the other vector b represents the components (bx , by ) . If we add these two vectors, we are actually adding their components. So a b will give (ax bx , ay by ) , and the diagram can be redrawn to look like this: b a Figure 7: Vector Addition The only difference between these two diagrams is that the component vectors have been moved to show the x components together and the y components together – the original vectors a and b have not been changed. If we add the resultant vector c to the diagram we get c b a Figure 8: Vector Addition with Resultant RRHS Physics Page 15 Notice that the vector c represents the sum of the components (ax bx , ay by ) . We now have one large right angle, so we can again use the Pythagorean theorem and our trigonometric functions to find the magnitude and direction of c . c Figure 9: Resultant Vector with Components Since we now have a single right angle triangle, we can use the Pythagorean theorem c (x)2 (y)2 to find the magnitude of c and the angle can be found using tan y x Example A person walks 5.0 km east and then 8.0 km in a direction 75 N of E. What is his displacement? Solution d1 5.0km E d 2 8.0km, 75 N of E dt ? We know that the total displacement is the sum of the individual displacements, dt d1 d2 This is a vector equation which will be used to draw the vector diagram: RRHS Physics Page 16 dt d 2 y d 2 d 2 x d1 The vector d1 is already in one of our 4 component directions (east), so we do not need to break this vector up into components. We do have to break d 2 into components, since it has both north and east components: d 2 x 8.0 d 2 x 2.1km cos 75 sin 75 d 2 y 8.0 d 2 y 7.7 km dt d 2 Since we know that the resultant vector has an x-component of 7.1 km and a ycomponent of 7.7 km, we can now find the magnitude and direction: dt dtx2 dty2 (7.1) 2 (7.7) 2 using Pythagorean theorem 10. km and RRHS Physics Page 17 tan dty dtx 7.7 7.1 47 The total displacement is dt 10. km, 47 N of E RRHS Physics Page 18 Check Your Learning A person walks 4.0 km south and then 7.2 km in a direction 21 o W of N. What was the person’s displacement? RRHS Physics Page 19 Vector Subtraction Just like subtraction of two scalars is really the same as adding a negative scalar ( 5 3 is the same as 5 (3) ), the subtraction of two vectors a b is the same as a (b ) ; but (b ) just means (bx , by ) ; in other words, we are just changing the direction of the vector b and instead of adding the components of the two vectors we subtract them. Using the same vectors as our previous example, a b a and b Figure 10: Vectors a b c is the same as a (b ) c so the two vectors that we must add are a and b : b a Figure 11: Vectors a and b Notice that b is simply pointing in the direction opposite that of b . The vector diagram for a (b ) c now looks like a c b Figure 12: a (b ) c RRHS Physics Page 20 The vector diagram can now be analyzed using components in the same way that it was for the vector addition problems. The resultant vector c can also still be represented in component form ax ay a b y b c bx Figure 13: a (b ) c with components where, in this case, x ax bx and y a y by . RRHS Physics Page 21 Check Your Learning Given the following vectors, draw a vector diagram to represent each of the following vector equations (where x is an unknown vector in each case): c a b a. a b x b. b c x c. a x b d. x c a RRHS Physics Page 22 1.1.2 In Class or Homework Exercise 1. A delivery truck travels 18 blocks north, 16 blocks east, and 10 blocks south. What is its final displacement from the origin? 2. A hiker leaves camp and, using a compass, walks 4 km E, 6 km S, 3 km E, 5 km N, 10 km W, 8 km N, and 3 km S. At the end of three days, the hiker is lost. Compute how far the hiker is from camp and which direction should be taken to get back to camp. 3. A car is driven 30.0 km west and then 80.0 km southwest. What is the displacement of the car from the point of origin (magnitude and direction)? 4. An explorer walks d 2 x d1 22.0 km north, and then walks in a direction 60.0 south of east for 47.0 km. d 2 y d 2 a. What d ty dt distance has he travelled? b. What is his displacement from the origin? d tx c. What displacement vector must he follow to return to his original location? 5. A man walks 3.0 km north, 4.5 km in a direction 40. east of north, and 6.0 km in a direction 60. south of east. What is his displacement vector? 6. After the end of a long day of travelling, Slimy the Slug is 255 cm east of his home. If he started out the day by travelling 90.0 cm in a direction 25o east of north in the morning, how far did he travel in the afternoon (and in what direction) to get to his final location? RRHS Physics Page 23 1.1.3 Velocity Vectors You saw in the previous section that an object's position in two dimensions is given by two coordinates (d x , d y ) . Remember from Unit 2 that velocity is the change in position, or displacement, over time: v d t Since velocity is calculated using displacement and has the same direction as the displacement, velocity is also a vector which has two components (vx , v y ) . vx d x t vy d y t As was discussed in Unit 2, there is no such thing as absolute velocity; the velocity of an object is always relative to some frame of reference. Consider the example of a dog on a boat. The boat is moving north at 7 m/s relative to the shore. Now suppose that the dog is moving north at 2 m/s relative to the boat. In other words, the dog is moving 2 m/s faster than the boat. How fast is the dog actually moving? It depends on your point of view. To someone on the boat, the dog is moving at 2 m/s; however, to somebody on the shore, the dog is moving its 2 m/s plus the boat's 7 m/s (since they are moving in the same direction), which is 9 m/s. The situation is similar in two dimensions. Suppose that a boat is crossing a body of water at 5.0 m/s relative to the water (we will use the symbol vbw to represent the velocity of the boat with respect to the water).4 If the water is not moving, a person on the shore sees the boat moving at 5.0 m/s relative to the shore as well. Now suppose that the body of water is a river flowing perpendicular to the boat at 3.5 m/s as measured by someone on the shore ( vws ). The person on the shore now sees the river carrying the boat downstream at 3.5 m/s, but also sees the boat moving across the river at 5.0 m/s. Just like the dog on the boat, the person on the shore sees the addition of the two velocities, so the velocity of the boat with respect to the shore is given by 4 Using this notation, the first subscript identifies the object that is moving, the second subscript identifies the frame of reference with respect to which it is moving RRHS Physics Page 24 vbs vbw vws Remember, however, that these quantities are vectors and must therefore be added as vectors! (as was described in the last section – in other words, we must draw a vector diagram). By using subscripts according to the convention described above we see that the inner subscripts on the right-hand side of the equation are the same as each other (in this case, w) and the outer subscripts on the right-hand side of the equation are the same as the subscripts for the resultant vector on the left vbs . This can be used as a check if you are not sure if you are adding the proper vectors. Since they are vectors, remember, these velocities must be added as vectors – they must be drawn head to tail: vws vbw Figure 14: vbs vbs vbw vws The resultant vector (the velocity actually observed by someone on the shore) is the vector vbs . This resultant velocity has two components (one across the river and one down the river). Note that the component across the river is the same as the original velocity of the boat that was directed across the river; therefore, the boat will cross the river in the same amount of time with the river flowing as without! Example A boat that has a speed of 5.0 m/s in still water heads north directly across a river that is 250 m wide. The velocity of the river is 3.5 m/s east. a. What is the velocity of the boat with respect to the shore? b. How long does it take the boat to cross the river? c. How far downstream does the boat land? d. What heading (direction) would the boat need in order to land directly across from its starting point? Solution a. RRHS Physics Page 25 vbw 5.0m / s N vws 3.5m / s E vbs ? To find the velocity of the boat with respect to the shore, we must add the velocity of the boat with respect to the water and the velocity of the water with respect to the shore: vbs vbw vws vws vbw 3.5m / s 5.0m / s vbs vbs or Using the Pythagorean Theorem, 2 2 vbs vbw vws (5.0) 2 (3.5) 2 6.1m / s Since we are finding velocity, we must also find the direction 3.5 5.0 35 tan vbs 6.1m / s,35 E of N b. Since the boat is going at a constant velocity, we can use d t Notice that both the displacement and velocity are vectors, and must have the same direction; therefore, if we use the displacement of 250 m (which is north) than we must also use the component of the velocity that is north, which is the boat’s velocity with respect to the water. v RRHS Physics Page 26 d 250m N vbw 5.0m / s N t ? d t 250 5.0 t t 50. s v c. Similarly, if we want to know how far downstream (east) the boat travels we must use the component of the velocity in this direction. The boat will be travelling for the same amount of time downriver that it took to cross the river. vws 3.5m / s E t 50. s d ? d t d 3.5 50. d 180m v d. If the boat is to land directly across from its starting point, than the velocity of the boat with respect to the shore must be north. vbs vbw vws Using this equation, and knowing that the resultant vector our vector diagram will look like this vbs must be north, vws vbw RRHS Physics vbs Page 27 sin vws vbw 3.5 5.0 44 The boat must head 44 W of N . Notice that this is not the same as the angle that the boat would travel downstream if no corrective action is taken. RRHS Physics Page 28 Check Your Learning In the example just completed, how long will it take the boat to cross the river in part (d)? In other words, how long will it take to cross the river when corrective action is taken so that the boat lands directly across from its starting point? How does this answer compare with the time obtained in part (a) of the example? RRHS Physics Page 29 1.1.3 In Class or Homework Exercise 1. An airplane is travelling 1000. km/h in a direction 37 o east of north. a. Find the components of the velocity vector. b. How far north and how far east has the plane travelled after 2.0 hours? 2. A motorboat whose speed in still water is 8.25 m/s must aim upstream at an angle of 25.5 o (with respect to a line perpendicular to the shore) in order to travel directly across the stream. a. What is the speed of the current? b. What is the resultant speed of the boat with respect to the shore? 3. Kyle wishes to fly to a point 450 km due south in 3.0 h. A wind is blowing from the west at 50.0 km/h. Compute the proper heading and airspeed that Kyle must choose in order to reach his destination on time. 4. Diane aims a boat that has a speed of 8.0 m/s in still water directly across a river that flows at 6.0 m/s. a. What is the resultant velocity of the boat with respect to the shore? b. If the stream is 240 m wide, how long will it take Diane to row across? c. How far downstream will Diane be? 5. An airplane whose airspeed is 200. km/h heads due north. But a 100. km/h wind from the northeast suddenly begins to blow. What is the resulting velocity of the plane with respect to the ground? 6. An airplane is heading due north at with an airspeed of 300. km/h. If a wind begins blowing from the southwest at a speed of 50.0 km/h, calculate a. the velocity of the plane with respect to the ground, and b. how far off course it will be after 30.0 min if the pilot takes no corrective action. c. Assuming that the pilot has the same airspeed of 300. km/h, what heading should he use to maintain a course due north? d. What is his new speed with respect to the ground? 7. A swimmer is capable of swimming 1.80 m/s in still water. a. If she aims her body directly across a 200.0 m wide river whose current is 0.80 m/s, how far downstream (from a point opposite her starting point) will she land? b. What is her velocity with respect to the shore? c. At what upstream angle must the swimmer aim if she is to arrive at a point directly across the stream? 8. A pilot wishes to make a flight of 300. km northeast in 45 minutes. If there is to be an 80.0 km/h wind from the north for the entire trip, what heading and airspeed must she use for the flight? RRHS Physics Page 30 9. A car travelling at 15 m/s N executes a gradual turn, so that it then moves at 18 m/s E. What is the car's change in velocity? 10. A plane's velocity changes from 200. km/h N to 300. km/h 30.0 W of N. Find the change in velocity. 11. A plane is flying at 100. m/s E. The pilot changes its velocity by 30.0 m/s in a direction 30.0 N of E. What is the plane's final velocity? 12. A ferryboat, whose speed in still water is 2.85 m/s, must cross a 260 m wide river and arrive at a point 110 m upstream from where it starts. To do so, the pilot must head the boat at a 45 o upstream angle. What is the speed of the river's current? RRHS Physics Page 31 1.1.4 Module Summary In this module you have learned: o To represent two dimensional vectors using two methods: components magnitude and direction o How to add and subtract displacement vectors using vector diagrams and components: When adding vectors, they must be drawn head to tail. The resultant vector goes from the tail of the first vector to the head of the last vector. Subtracting vectors is the same operation as adding a negative vector, where a negative vector points in the direction opposite the direction of the original vector. o How to use vector diagrams and components to calculate relative velocities. RRHS Physics Page 32 Module 1.2 Force Vectors 1.2.1 Dynamics Problems in 2D In Unit 3, you solved many problems involving horizontal and vertical forces by applying Newton's 2nd Law to different situations using free body diagrams. This will now be extended to situations where the forces are no longer solely in the horizontal or vertical directions. Remember that Newton's 2nd Law ( Fnet ma ) is a vector equation, since it states the relationship between acceleration and net force, both of which are vectors. This means that the acceleration and the net force will be in the same direction; therefore, if we want to use scalar algebra to solve a problem, we must use this equation in only one dimension at a time ( x or y ). In the diagram below, a man is pulling a box with a rope that makes an angle with the ground. Note that the expected acceleration (horizontal) for this box and the applied force are neither parallel nor perpendicular, so Newton's 2nd Law cannot be applied yet. A free body diagram for this box would look like this: Notice that although the normal, friction, and gravity forces are all solely in the x (horizontal) or y (vertical) directions, the force of the man pulling is not. This can be fixed if we break this force up into its x and y components. RRHS Physics Page 33 In other words, pulling with a force Fp at an angle of is the same as applying two separate forces of Fx to the right and Fy upward. As can be seen in the diagram above, all of the forces are now either in the x or y direction if we replace Fp with its components Fpx and Fpy . We can now analyze the forces in each dimension using Newton's 2nd Law. Vertical: We will take up as the positive direction; therefore, FN and Fpy will both be positive and Fg will be negative. Remember, only vertical forces can be used to calculate a vertical acceleration. ma y Fy ma y FN Fpy Fg may FN Fpy Fg and 0 FN Fpy Fg FN Fg Fpy since the vertical acceleration is zero (the box is not accelerating up or down). Notice that FN Fg . Because we often know Fg and Fpy , we can solve for FN and use it in our calculation of F f (remember that Ff FN , where is the coefficient of friction). Horizontal: We will take the right to be positive; therefore, Fpx will be positive and F f will be negative. Remember, only horizontal forces can be used to calculate a horizontal acceleration. max Fx max Fpx Ff max Fpx Ff RRHS Physics Page 34 This can then be used with the horizontal acceleration. These are not equations to be memorized and applied to all problems!!! This is a sample analysis of a typical free body diagram involving forces at an angle. As always when dealing with force problems, analysis should always start with a free body diagram. Example A 52.0 kg sled is being pulled along a frictionless horizontal ice surface by a person pulling a rope with a force of 235 N. The rope makes an angle of 35.0o with the horizontal. What is the acceleration of the sled? Solution First we need a free body diagram: m 52.0kg Fp 235 N 35.0 ax ? We must first calculate the components for the applied force: Fpx Fp cos (235) cos 35.0 193N Fpy Fp sin (235) sin 35.0 135 N Horizontal: RRHS Physics Page 35 max F x max Fpx (52.0)ax 193 ax 3.71m / s 2 Since there was no friction involved in this problem, we did not need a calculation of the normal force; since there was no vertical acceleration and the normal force was not needed, we were not required to do an analysis of the vertical forces. RRHS Physics Page 36 Check Your Learning A 52.0 kg sled is being pulled along a horizontal surface by a person pulling a rope with a force of 235 N. The rope makes an angle of 35.0 o with the horizontal. If the coefficient of friction between the sled and the surface is 0.25, what is the acceleration of the sled? RRHS Physics Page 37 1.2.1 In Class or Homework Exercise 1. A 25.0 kg sled is accelerating at 2.3 m/s2. A force of 300.0 N is pulling the sled along a rope that is being held at an angle of 35o with the horizontal. What is the coefficient of friction? 2. A 15.0 kg sled is being pulled along a horizontal surface by a rope that is held at a 20.0o angle with the horizontal. The tension in the rope is 110.0 N. If the coefficient of friction is 0.30, what is the acceleration of the sled? 3. A man pushes a 15 kg lawnmower at constant speed with a force of 90.0 N directed downward along the handle, which is at an angle of 30.0o to the horizontal. What is the coefficient of friction? 4. A sled is being pulled by a rope that makes an angle of 27 o with the horizontal. The coefficient of friction between the sled and the ground is 0.30. If the tension in the rope is 245 N and the acceleration of the sled is 1.2 m/s 2, what is the mass of the sled? 5. A 55.0 kg rock is being pulled along a horizontal surface at a constant speed. The coefficient of friction between the rock and the surface is 0.76. If the rope pulling the rock is at a 40.0o angle with the horizontal, with what force is the rock being pulled? 6. A 40.0 kg iceboat is gliding across a frozen lake with a constant velocity of 14 m/s E, when a gust of wind from the southwest exerts a constant force of 100. N on its sails for 3.0 s. With what velocity will the boat be moving after the wind has subsided? Ignore any frictional forces. 7. Two tow trucks attach ropes to a stranded vehicle. The first tow truck pulls with a force of 25000 N, while the second truck pulls with a force of 15000 N. The two ropes make an angle of 15.5o with each other. Find the resultant force on the vehicle. RRHS Physics Page 38 1.2.2 Inclined Planes Up until now, we have dealt only with dynamics situations where the motion has been either horizontal or vertical, and where we have calculated all of the components of our vectors in horizontal and vertical planes. We are now going to apply force vectors and Newton's second law to an inclined plane (a ramp). On an inclined plane, the acceleration is neither horizontal nor vertical. It is parallel to the plane. If we place a box on a ramp (ignoring friction for now), as in Figure 15, Figure 15: Ramp it can be observed that there are only two forces acting on the box - the normal force FN (which is perpendicular to the surface of the plane) and the force of gravity Fg . Drawing a free body diagram, we get Figure 16: Ramp Free Body Diagram Notice that these vectors exist in two dimensions and are not in component form (they are not either parallel or perpendicular to one another). In order to apply Newton's second law, we want to analyze the forces one dimension at a time. Instead of using our usual coordinate system containing horizontal and vertical axes, RRHS Physics Page 39 it makes more sense in this situation to rotate our axes so that they are perpendicular and parallel to the surface of the inclined plane (the same direction as the acceleration). In other words, our x direction will be parallel to the plane and the y direction will by perpendicular to the plane. Since the normal force is already perpendicular to the plane (and any applied force along with the force of friction will usually be parallel to the plane), only the force of gravity must be broken up into components. Figure 17: Ramp Free Body Diagram with Components This can be done as shown in Figure 18 (where the Fg vector from the previous diagram has been enlarged). Figure 18: Gravity Components The angle in the top of the triangle is the same angle as the slope of the inclined plane (try showing this using geometry). Using trigonometry, it can be found that the two components are Fgx mg sin (1.1) Fgy mg cos (1.2) and RRHS Physics Page 40 The two components of gravity can be thought of as having different roles in this situation: Fgx is down (and parallel) to the ramp and is trying to accelerate the box down the ramp; Fgy is pushing the box onto the ramp and is responsible for keeping it in contact with the ramp. If we apply Newton’s Second Law to the perpendicular forces we get ma y Fy ma y FN Fgy ma y FN Fgy Since there is no acceleration perpendicular to the plane we now have m(0) FN Fgy FN Fgy where Fgy can be found using equation (1.2). If friction is present, the normal force can then be used in this calculation. Again notice that FN Fg . Similarly, the parallel forces can be used to obtain an expression for the parallel acceleration on the inclined plane max Fx max Fgx where Fgx can be found using equation (1.1). Notice that this is just a simple analysis where friction and other external forces have not been included; if present, these would have to be considered in the force analysis. Again, it is extremely important to draw a free body diagram at the start of the problem! Example A 1200 kg car is on an icy (frictionless) hill that is inclined at an angle of 12 o with the horizontal. What is the acceleration of the car down the hill? Solution Since there is no friction, the only forces involved are gravity and the normal force: RRHS Physics Page 41 Since the acceleration that we are looking for is parallel to the inclined plane, we will rotate our axes so that the x-axis is parallel to the inclined plane. m 1200kg 12 ay 0 ax ? Parallel Forces If we use down the ramp as positive, max F x max Fgx max mg sin ax (9.80)(sin12) 2.0m / s 2 Although we were given the mass of the car, notice that it cancelled out in this problem and was not needed. RRHS Physics Page 42 Check Your Learning A 1200 kg car is on an icy hill that is inclined at an angle of 12 o with the horizontal. As the car starts sliding, the driver locks the wheels. The coefficient of friction between the locked wheels and the icy surface is 0.14. What is the acceleration of the car down the hill? RRHS Physics Page 43 1.2.2 In Class or Homework Exercise 1. An 18.0 kg box is released on a 33.0o incline and accelerates at 0.300 m/s2. What is the coefficient of friction? 2. A box (mass is 455 g) is lying on a hill which has an inclination of 15.0o with the horizontal. a. Ignoring friction, what is the acceleration of the box down the hill? b. If there is a coefficient of friction of 0.20, will the box slide down the hill? If so, at what acceleration? 3. 4. 5. 6. c. How much force is required to push the box up the ramp at a constant speed? A 165 kg piano is on a 25.0 ramp. The coefficient of friction is 0.30. Jack is responsible for seeing that nobody is killed by a runaway piano. a. How much force (and in what direction) must Jack exert so that the piano descends at a constant speed? b. How much force (and in what direction) must Jack exert so that the piano ascends at a constant speed? A car can decelerate at -5.5 m/s2 when coming to rest on a level road. What would the deceleration be if the road inclines 15o uphill? A sled is sliding down a hill and is 225 m from the bottom. It takes 13.5 s for the sled to reach the bottom. If the sled’s speed at this location is 6.0 m/s and the slope of the hill is 30.0 , what is the coefficient of friction between the hill and the sled? A 5.0 kg mass is on a ramp that is inclined at 30o with the horizontal. A rope attached to the 5.0 kg block goes up the ramp and over a pulley, where it is attached to a 4.2 kg block that is hanging in mid air. The coefficient of friction between the 5.0 kg block and the ramp is 0.10. What is the acceleration of this system? Figure 19: Diagram for Question 6 RRHS Physics Page 44 7. A force of 500.0 N applied to a rope held at 30.0o above the surface of a ramp is required to pull a box weighing 1000.0 N at a constant velocity up the plane. The ramp has a base of 14.0 m and a length of 15.0 m. What is the coefficient of friction? Figure 20: Diagram for Question 7 8. If a bicyclist (75 kg) can coast down a 5.6o hill at a steady speed of 7.0 km/h, how much force must be applied to climb the hill at the same speed? RRHS Physics Page 45 1.2.3 Module Summary In this module you learned that o Force vectors can be broken into components so that dynamics situations can be analyzed using free body diagrams and Newton’s Second Law. o Situations involving inclined planes (ramps) can be analyzed by rotating the coordinate system so that the x-axis is parallel to the ramp and the y-axis is perpendicular to the ramp. The components for the force of gravity can then be given by Fgx mg sin Fgy mg cos RRHS Physics Page 46 Module 1.3 Equilibrium 1.3.1 Translational Equilibrium You saw in Unit 3 that if two equal but opposite forces are applied to an object, the net force is zero and the object is said to be in equilibrium. A body in equilibrium at rest in a particular reference frame is said to be in static equilibrium; a body moving uniformly at constant velocity is in dynamic equilibrium. We will be dealing with mainly static equilibrium in this module, although the net force is zero in both cases. We will now extend our discussion of equilibrium to two dimensions. The type of equilibrium discussed in Unit 3 is known as translational equilibrium. Consider a mass being supported in midair by two ropes. Figure 21: Hanging Mass The mass is stationary; therefore, it is obviously not accelerating either sideways or up and down. The net force must therefore be zero and the object is said to be in translational equilibrium. RRHS Physics Page 47 Figure 22: Hanging Mass Free Body Diagram As can be seen by the free-body diagram, there are three forces acting on the mass. As we said, the net force acting on the mass must be zero; therefore, FT 1 FT 2 Fg 0 . Remember, these are vectors so they must add as vectors5 to be zero, as shown in the following vector diagram: Figure 23: Hanging Mass Vector Diagram Note that our vector diagram starts and ends at the same point; therefore, the resultant vector (the net force) is zero. Since force is a vector, the components of the net force on a body in equilibrium must each be zero, so Fx 0 (1.3) and 5 When drawn head to tail, they must return to the starting point. RRHS Physics Page 48 Fy 0 (1.4) Looking at the components in the x and y direction separately, this tells us that in the x direction Fx 0 F1x F2 x 0 F1x F2 x 0 F1x F2 x and in the y direction F y 0 F1 y F2 y Fg 0 F1 y F2 y Fg 0 F1 y F2 y Fg The requirement that the net force be zero (which provides translational equilibrium) is only the first condition for equilibrium. The second condition will be discussed in section 5.3.2. Equilibrant Force If the vector sum of all of the forces acting on an object is not zero, there will be a net force in some direction. There is a single additional force that can be applied to balance this net force. This additional force is called the equilibrant force. The equilibrant force is equal in magnitude to the sum of all of the forces acting on the object, but opposite in direction. Example A 20.0 kg sack of potatoes is suspended by a rope. A man pushes sideways with a force of 50.0 N and maintains this force so that the sack is in equilibrium. What is the tension in the rope and what angle does the rope make with the vertical? Solution While the man is pushing sideways, the rope will be at an angle as shown in the picture below: RRHS Physics Page 49 m 20.0kg Fp 50.0 N FT ? Fg mg (20.0)(9.80) 196 N Our free body diagram will look like this: Since the bag is in equilibrium, the net force must be zero; therefore, FT Fg Fp 0 . RRHS Physics Page 50 Since the force of gravity and the force of the person pushing are perpendicular, the Pythagorean Theorem can be used to find the magnitude of the tension and using trigonometry will allow us to calculate the angle. FT Fg2 Fp2 (196) 2 (50.0) 2 202 N RRHS Physics tan Fp Fg 50.0 196 14.3 Page 51 Check Your Learning Joe wishes to hang a sign weighing 750.0 N so that cable A attached to the store makes a 30.0 angle as shown in the picture below. Cable B is attached to an adjoining building and is horizontal. Calculate the necessary tension in cable B. RRHS Physics Page 52 1.3.1 In Class or Homework Exercise 1. Find the unknown mass in the diagram below: 2. A sign with a mass of 165 kg is supported by a boom and a cable, as shown in the diagram below. The cable makes an angle of 36o with the boom. Find the magnitude of the force exerted by the boom and the cable on the sign. Ignore the mass of the boom. 3. Find the tensions FT 1 and FT 2 in the two strings indicated: 4. In the diagram shown below, block A has a mass of 10.5 kg and block B has a mass of 52.6 kg. The string runs from Block B to the wall. The segment of string from block B to point P on the string is horizontal. The friction between block B and the table is unknown. Find the minimum coefficient of friction between block B and the table that would prevent block B from moving. RRHS Physics Page 53 5. Three students are pulling ropes that are attached to a car. Barney is pulling north with a force of 235 N; Wilma is pulling with a force of 175 N in a direction 23o E of N; Betty is pulling with 205 N east. What equilibrant force must a fourth student, Fred, apply to prevent acceleration? 6. Your mother asks you to hang a heavy painting. The frame has a wire across the back, and you plan to hook this wire over a nail in the wall. The wire will break if the force pulling on it is too great, and you don't want it to break. If the wire must be fastened at the edges of the painting, should you use a short wire or a long wire? Explain. 7. When lifting a barbell, which grip will exert less force on the lifter's arms: one in which the arms are extended straight upward from the body so that are at right angles to the bars, or on in which the arms are spread apart so that the bar is gripped closer to the weights? Explain. RRHS Physics Page 54 1.3.2 Torque and Rotational Equilibrium Until now, we have treated all objects as point sources when drawing our free body diagrams; in other words, we were not concerned with the where on the object the force was being applied. In many situations, however, it makes a difference on which part of the object we apply a force. Even if all of the forces acting on an object balance, it is possible for the object not to be in total equilibrium. Consider a board where equal forces are applied at opposite ends of the board, but one up and one down. Obviously, even though the forces are equal and opposite and the board as a whole should not move up or down, the board will begin to spin. It is not in rotational equilibrium. Rotational equilibrium refers to the situation where there is no rotary motion. To examine this more, we must introduce the notion of a torque. Torque A torque has the same relationship to rotation as force does to linear movement. It can be thought of as a twisting force. To measure the rotating effect of a torque, it is necessary to choose a stationary reference point for the measurements (the pivot point). This pivot point can be chosen arbitrarily, since the point of rotation is often not known until the rotation begins.6 The size of a torque depends on two things: 1. The size of the force being applied (a larger force will have a greater effect) 2. The distance away from the pivot point (the further away from this pivot, the greater the effect). A line drawn from the pivot to the force that is providing the torque is known as the torque arm. It is along this torque arm that the distance should be measured. A torque is the product of a force multiplied by a distance from the pivot. 6 If there is a natural pivot point (for example, on a see-saw) then it usually makes sense to choose this as the pivot point. However, it is not necessary to do so. RRHS Physics Page 55 F r (1.5) where it is only the component of the force that is perpendicular to the torque arm that contributes to the torque (try opening a door by pushing parallel to the door – it does not work!). As can be seen from equation (1.5), the units for torque are N·m , if the force F is in newtons and the distance r from the pivot is in metres. You may recall from Unit 4 that a N·m was defined as a joule; however, this unit is not called a joule when calculating torques as the force and the distance are perpendicular, not parallel (as they are when calculating work). Example 1 Suppose that you are trying to open a door that is 70.0 cm wide. You are applying a force of 68 N 10.0 cm from the outer edge of the door, but you are pushing at an angle of 75o from the surface of the door. What torque are you applying on the door? Solution Figure 24: Overhead view of door in Example 1 As can be seen in the overhead view of the door, the force is being applied 60.0 cm from the natural pivot point, which is the hinge. Remember also, that it is only the component of the force that is perpendicular to the torque arm (the door) that contributes to the torque. r 0.600m F 68 N 75 ? RRHS Physics Page 56 F r Fy r Fr sin (68)(0.600) sin 75 39 N m RRHS Physics Page 57 Rotational Equilibrium While forces were described using up, down, left, right, etc., torques are described using the terms clockwise and counterclockwise. A clockwise torque added to an equal (in magnitude) counterclockwise torque will be zero. Rotational equilibrium is attained if the sum of all of the torques is zero. 0 (1.6) This is the second condition for static equilibrium. Just as the components of a force are positive or negative depending on their direction, so is a torque. If a clockwise torques is considered to be positive, then a counter-clockwise torque must be considered to be negative; therefore, equation (1.6) can also be expressed by saying that the sum of all of the clockwise torques must equal the sum of all of the counterclockwise torques. cw ccw 0 cw ccw (1.7) As we have seen, there are two conditions for static equilibrium: 1. The sum of the forces is zero (providing translational equilibrium), and 2. The sum of the torques is zero (providing rotational equilibrium). It is important to remember that when calculating the torques, all distances must be measured from the pivot point. Any convenient location can be chosen for the pivot point. An equilibrant force must provide both translational and rotational equilibrium. When finding an equilibrant force to satisfy both of these conditions, it is necessary to find both the force itself (magnitude and direction) and the location of application. Centre of Gravity One of the forces often involved in calculating the torques on an object is the force of gravity. Before dealing with torques, we were not usually concerned with the location of the force on a body, but for calculating torques, this is important. Where does gravity act on a body? Of course, it acts on every particle in the body, but there is a point called the centre of gravity (cg) where the entire force of gravity can be considered to be acting. The center of gravity is the point at which we could apply a single upward force to balance the object. For a mass with a uniform distribution of mass (such as a ruler), the centre of gravity would be at the geometric center (the middle of the ruler). Example 2 RRHS Physics Page 58 A 2.0 kg board serves as a see-saw for two children. One child has a mass of 30.0 kg and sits 2.5 m from the pivot point. At what distance from the pivot must a 25.0 kg child sit on the other side to balance the see-saw? Assume that the board is uniform and centred over the pivot. Solution mb 2.0kg m1 30.0kg Fg1 m1 g m2 25.0kg (30.0)(9.80) r1 2.5m 294 N Fg 2 m2 g (25.0)(9.80) 245 N r2 ? Drawing a free body diagram, we have If we choose our pivot point here to be the centre of the board, then there is no torque due to either the force exerted by the pivot or the weight of the board, since both of these forces act on the pivot point and the torque arm is zero. The only torques present will be due to the weight of the two children. Since we already know both of these forces, we do not have to consider translational equilibrium in this problem. cw ccw Fg 2 r2 Fg1r1 245r2 (294)(2.5) r2 3.0m The second child must be 3.0 m away from the pivot on the other side of the board. Example 3 RRHS Physics Page 59 A 4.0 m platform with a uniform distribution of mass has a 3.2 kg box 0.80 m from the left end. The mass of the platform is 2.0 kg. Calculate the size and location of the required equilibrant force. Solution The equilibrant force is the single force that will provide equilibrium (both translational and rotational). In this case, the direction of the equilibrant force is obviously upward since all of the forces on the platform are downward. Since the platform has a uniform distribution of mass, the center of gravity is at the center of the platform. We can guess at the approximate location of the upward equilibrant force. In this situation, there is no natural (or fixed) pivot point – the platform could rotate about a number of points. In this situation, it is completely arbitrary where we pick the pivot point. For this problem, we will choose the left end to be the pivot point (as indicated by the X in the diagram). mb 3.2kg m p 2.0kg rb 0.80m rp 2.0m Fgb mb g (3.2)(9.80) 31.4 N Fgp m p g (2.0)(9.80) 19.6 N req ? Translational Equilibrium To satisfy translational equilibrium, the forces must balance – in this case, the total force up must equal the total force down. RRHS Physics Page 60 Fy 0 0 Feq Fgb Fgp Feq Fgb Fgp 31.4 19.6 51N Rotational Equilibrium To satisfy rotational equilibrium, the torques must balance – the clockwise torques must equal the counter-clockwise torques. In this example, the forces of gravity on the platform and on the box provide clockwise torques; the upward equilibrant force will provide a counter-clockwise torque. 0 cw ccw 0 cw ccw Fgb rb Fgp rp Feq req (31.4)(0.80) (19.6)(2.0) (51)req req 1.3m Feq 51N up, 1.3 m from the left end RRHS Physics Page 61 Check Your Learning A uniform 1500 kg bridge, 20.0 m long, supports a 2200 kg truck whose centre of mass is 5.0 m from the right support column as shown in the diagram below. Calculate the force on each of the vertical support columns. RRHS Physics Page 62 1.3.2 In Class or Homework Exercise 1. A person is trying to open a door that is 90.0 cm wide. If there is a spring on a door 5.0 cm from the hinges which exerts a force of 60.0 N to keep the door closed, a. How much force must be used to open the door if the force is applied at the outer edge of the door? b. How much force must be used if the force from the person is applied 15.0 cm from the hinges? 2. A 60.0 kg person is sitting 1.2 m from the pivot on a see-saw. A 50.0 kg person is sitting 0.90 m away from the pivot on the other side. Where must a 22.0 kg child sit to balance the see-saw? 3. A long board is holding a person in the air. The person has a mass of 75.0 kg and is located 2.0 m from one end. The 10.0 m board has a mass of 10.0 kg, and its center of gravity is located 4.0 m from the same end as the person. The board is being held up by two students, one at either end. What force is required by each student to hold the board up? 4. Find the equilibrant force (magnitude, direction, and location) in the following diagram. 5. Find the equilibrant force (magnitude, direction, and location) which will stabilize the following beam: 6. In the following diagram, determine the magnitude, direction, and point of application of the necessary equilibrant force. RRHS Physics Page 63 7. A 5.0 m long ladder leans against a wall at a point 4.0 m above the ground. The ladder is uniform and has a mass of 12.0 kg. Assuming that the wall is frictionless (but the ground is not) determine the force exerted on the ladder by the wall. 8. A sign with a mass of 165 kg is supported by a 35 kg boom (with a uniform distribution of mass and a length of 1.6 m) and a cable, as shown in the diagram below. The cable makes an angle of 36o with the boom. Find the magnitude of the force exerted by the cable. 9. Calculate the forces F1 and F2 that the supports exert on the diving board shown below when a 50.0 kg person stands at its tip. a. ignoring the mass of the board b. If the board has a mass of 40.0 kg (uniformly distributed) RRHS Physics Page 64 1.3.3 Module Summary In this module you learned that o An object is said to be in static equilibrium if it is in both translational equilibrium and rotational equilibrium. o Translational Equilibrium is achieved when the net force is zero: Fx 0 Fy 0 o Torque can be calculated using the equation F r o Rotational Equilibrium is achieved when the net torque is zero: 0 RRHS Physics Page 65 Module 1.4 2D Collisions 1.4.1 Conservation of Momentum You learned in grade 11 that the total momentum of an isolated system remains constant. Also, if you remember from grade 11, momentum is a product of mass and velocity ( p mv ). Since velocity is a vector, so is momentum. This vector nature of momentum becomes extremely important in two dimensional collisions. When you analyzed one dimensional collisions, you could show that in an isolated system the momentum of each object before the collision added up to equal the total momentum after the collision. This still applies in two dimensional collisions, but remember that momentum is a vector so it must be added as a vector!! For a collision involving two objects in one dimension, you would write pa pb pa pb (1.8) ma va mb vb ma va mbvb (1.9) or, since p mv , where primed quantities mean after the collision and unprimed mean before the collision. The vector nature of the momentum was addressed in one dimensional situations using positive or negative values for the velocities. In two dimensions, the vector nature of momentum does not allow simple algebraic operations using equation (1.9). Although you can still express the conservation of momentum using equations (1.8) and (1.9), special attention must be paid to the vector nature of momentum. To add momentum vectors in two dimensions, a vector diagram must be drawn. Equation (1.9) can only be used algebraically if you first break the vectors into components and then apply the equation in each dimension. Consider the example of a ball moving to the right that collides with another ball at rest. If the collision is not head on, the two balls will go in different directions after the collision. RRHS Physics Page 66 Just as with one dimensional collisions, the sum of all of the momentum vectors after the collision ( pa and pb ) is equal to the total of the momentum vectors before the collision ( pa ). pa pa pb (1.10) Since momentum is a product of mass (a scalar) and velocity (a vector), the momentum vector for an object will be in the same direction as the velocity vector of the object; however, remember that it is momentum that is conserved, not velocity – Do not draw a velocity vector diagram when solving these problems! The momentum vector diagram for equation (1.10) would look like this: where p t is really just p a , since there is only one momentum vector before the collision. The individual momentum vectors can be found using the formula p mv . We can now use our usual methods of component analysis for solving vector problems. If we draw our components into the momentum vector diagram, we see that the momentum is conserved in each dimension. RRHS Physics Page 67 In other words, the sum of the x components of momentum before the collision are equal to the sum of the x components of momentum after the collision. pa pax pbx pax pbx where the momentum components can be found using the appropriate velocity components ( pax ma vax and pbx mb vbx ). Similarly the sum of the y components of momentum before the collision are equal to the sum of the y components of the momentum after the collision. Since the original y momentum is zero in this example, the y momentum after the collision is still zero. 0 pay pby 0 pay pby RRHS Physics Page 68 1.4.1 In Class or Homework Exercise 1. A collision between two vehicles occurs at a right angled intersection. Vehicle A is a car of mass 1800 kg travelling at 60. km/h north. Vehicle B is a delivery truck of mass 3500 kg initially travelling east at 45 km/h. If the two vehicles remain stuck together after the impact, what will be their velocity after the impact? How much kinetic energy was lost in the collision? 2. A radioactive nucleus at rest decays into a second nucleus, an electron, and a neutrino. The electron and neutrino are emitted at right angles and have momenta of 8.6 1023 kg m/s and 6.2 1023 kg m/s. What is the magnitude and direction of the momentum of the recoiling nucleus? 3. A collision investigator is called to an accident scene where two vehicles collided at a right-angled intersection. From skid marks, the investigator determined that car A, mass 1400 kg was travelling 50. km/h west before impact. The two vehicles remained stuck together after impact and the velocity of the cars after impact was 10. km/h in a direction 30.0 W of N. a. What was the mass of vehicle B? b. How fast was car B travelling before the accident? 4. Two streets intersect at a 40. angle. Car A has a mass of 1500 kg and is travelling at 50. km/h. Car B has a mass of 1250 kg and is travelling 60. km/h. If they collide and remain stuck together, what will be the velocity of the combined mass immediately after impact? 5. A billiard ball of mass 0.400 kg moving with a speed of 2.00 m/s strikes a second ball, initially at rest, of mass 0.400 kg. The first ball is deflected off at an angle of 30.0o with a speed of 1.20 m/s. Find the speed and direction of the second ball after the collision. 6. Billiard ball A is moving at a speed of 3.0 m/s east when it strikes an equal mass ball B at rest. The two balls are observed to move off at 45o angles to A’s original direction – ball A goes northeast and ball B goes southeast. What are the speeds of the two balls after the collision? 7. A grenade of mass 10.0 kg explodes into 3 pieces in the same plane, two of which A (5.0 kg) and B (2.0 kg), move off as shown. Calculate the velocity of the third piece C. RRHS Physics Page 69 1.4.2 Elastic and Inelastic Collisions Elastic Collisions As you learned in grade 11, an elastic collision is one in which no kinetic energy is lost; the total kinetic energy of the particles before the collision is the same as the total kinetic energy of the particles after the collision. For a two body collision, this would be expressed as 1 1 1 1 ma va2 mb vb2 ma va2 mbvb2 2 2 2 2 (1.11) Remember that energy is not a vector; therefore, it is only the magnitude of the velocity that is used in (1.11). Consider the special case where particle b is initially at rest. We now have 1 1 1 ma va2 ma va2 mb vb2 2 2 2 If the mass of each particle is the same, then after cancelling the mass and the factor of one half, our conservation of energy equation (1.11) reduces to va2 va2 vb2 (1.12) which is really an expression of the pythagorean theorem. Since the masses are equal, the velocity vectors are proportional to the momentum vectors. A velocity vector diagram in this situation7 would therefore show that the vectors va and vb would add to give the vector va . Since the magnitudes of these vectors are related by the pythagorean theorem, the vector diagram must be a right angle triangle. In other words, va and vb (and pa and pb ) are perpendicular to one another; after this collision, the two particles move off at right angles to one another. Remember, though, that this is only true for the special case where the two objects have the same mass, the collision is elastic, and one of the particles is initially at rest. Inelastic Collisions An inelastic collision is one in which the kinetic energy is not conserved; some of the energy is transformed into other types of energy, such as thermal energy. A completely inelastic collision is one in which the objects stick together; some energy is lost, but a completely inelastic collision does not mean that all of the energy is lost. In this type of collision, it may be possible to calculate the amount of energy lost by comparing the total initial kinetic energy with the total final kinetic energy. 7 A velocity vector diagram can be applied here only because the masses are all the same; therefore, every velocity vector is multiplied by the same factor to obtain the corresponding momentum vector RRHS Physics Page 70 1.4.2 In Class or Homework Exercise 1. A proton travelling with speed 8.2 105 m/s collides elastically with a stationary proton. One of the protons is observed to be scattered at a 60.o angle. At what angle will the second proton be observed, and what will be the velocities of the two protons after the collision? 2. Two cars collide at an intersection. The first car has a mass of 925 kg and was travelling north. The second car has a mass of 1075 kg and was travelling west. Immediately after impact, the first car had a velocity of 52.0 km/h, 40.0o north of west, and the second car had a velocity of 40.0 km/h, 50.0o north of west. What was the speed of each car prior to the collision? 3. Sphere A of mass 2.0 kg is travelling at 10.0 m/s west and approaches sphere B of mass 5.0 kg travelling at 5.0 m/s N. After the collision, sphere A moves away at 4.0 m/s in a direction 35o N of E. a. What is the final velocity of sphere B? b. Was the collision elastic? 4. A particle of mass m travelling with a speed v collides elastically with a target particle of mass 2m (initially at rest) and is scattered at 90.0 . a. At what angle does the target particle move after the collision? b. What are the particles' final speeds? c. What fraction of the initial kinetic energy is transferred to the target particle? 5. A billiard ball is moving North at 3.00 m/s, and another is moving East with a speed of 4.80 m/s. After the collision (assumed elastic), the second ball is moving North. What is the final direction of the first ball, and what are their final speeds? 6. A billiard ball of mass ma 0.40 kg strikes a second ball, initially at rest, of mass mb 0.60 kg. As a result of this elastic collision, ball A is deflected at an angle of 30o and ball B at 53o . What is the ratio of their speeds after the collision? RRHS Physics Page 71