Principles and Problems

Principles and Problems
PHYSICS Principles and Problems Chapter 4: Forces in One Dimension

Forces in One Dimension
CHAPTER4 Forces in One Dimension BIG IDEA Net forces cause changes in motion.

Section 4.1 Force and Motion Section 4.2 Weight and Drag Force
CHAPTER4 Table Of Contents Section Force and Motion Section Weight and Drag Force Section Newton’s Third Law Click a hyperlink to view the corresponding slides. Exit

Force and Motion MAIN IDEA Essential Questions
SECTION4.1 Force and Motion MAIN IDEA A force is a push or a pull. Essential Questions What is a force? What is the relationship between force and acceleration? How does motion change when the net force is zero?

Force and Motion Review Vocabulary New Vocabulary
SECTION4.1 Force and Motion Review Vocabulary Acceleration the rate at which the velocity of an object changes. New Vocabulary Force System Free-body diagram Newton’s second law Newton’s first law Inertia Equilibrium

SECTION4.1 Force and Motion Force Consider a textbook resting on a table. To cause it to move, you could either push or pull on it. A force is defined as a push or pull exerted on an object.

Force and Motion Force (cont.)
SECTION4.1 Force and Motion Force (cont.) If you push harder on an object, you have a greater effect on its motion. The direction in which force is exerted also matters. If you push the book to the right, the book moves to the right. The symbol F is a vector and represents the size and direction of a force, while F represents only the magnitude.

SECTION4.1 Force and Motion Force (cont.) Forces can cause objects to speed up, slow down, or change direction as they move. Based on the definitions of velocity and acceleration, a force exerted on an object causes that object’s velocity to change; that is, a force causes an acceleration. All accelerations are the result of an unbalanced force acting on an object.

SECTION4.1 Force and Motion Force (cont.) When considering how a force affects motion, it is important to identify the object of interest. This object is called the system. Everything around the object that exerts forces on it is called the external world.

SECTION4.1 Force and Motion Force (cont.) Think about the different ways in which you could move a textbook. You could touch it directly and push or pull it, or you could tie a string around it and pull on the string. These are examples of contact forces.

SECTION4.1 Force and Motion Force (cont.) A contact force exists when an object from the external world touches a system and thereby exerts a force on it.

SECTION4.1 Force and Motion Force (cont.) There are other ways in which the motion of the textbook can change. If you drop a book, the gravitational force of Earth causes the book to accelerate, whether or not Earth is actually touching it. This is an example of a field force. Field forces are exerted without contact.

SECTION4.1 Force and Motion Force (cont.) Forces result from interactions; thus, each force has a specific and identifiable cause called the agent. Without both an agent and a system, a force does not exist. A physical model which represents the forces acting on a system, is called a free-body diagram.

SECTION4.1 Force and Motion Force (cont.) Click image to view movie.

Force and Motion Combining Forces
SECTION4.1 Force and Motion Combining Forces When the force vectors are in the same direction, they can be replaced by a vector with a length equal to their combined length. If the forces are in opposite directions, the resulting vector is the length of the difference between the two vectors, in the direction of the greater force. Vector sum of all the forces on an object is net force.

Acceleration and Force
SECTION4.1 Force and Motion Acceleration and Force To explore how forces affect an object’s motion, consider the situation explored in the figure, in which, a horizontal force is exerted on an object.

Acceleration and Force (cont.)
SECTION4.1 Force and Motion Acceleration and Force (cont.) Notice, in order to reduce complications resulting from the object rubbing against the surface, the investigation was performed on a smooth, well-polished table and the cart has wheels.

SECTION4.1 Force and Motion Acceleration and Force (cont.) To exert a constant force, a spring scale was used to pull the cart. The velocity of the cart was measured for a period of time. Using the data, a velocity-time graph was constructed.

SECTION4.1 Force and Motion Acceleration and Force (cont.) The data indicates for a constant force there is a constant acceleration on an object. Thus, indicating the relationship between force and acceleration is linear and allowing the application of the equation for a straight line: The y-intercept is 0, so the linear equation simplifies to y=kx. The y-variable is acceleration and x-variable is force.

SECTION4.1 Force and Motion Acceleration and Force (cont.) What is the physical meaning of the slope of the acceleration-force graph? To determine this, increase the number of carts gradually.

SECTION4.1 Force and Motion Acceleration and Force (cont.) A plot of the force versus acceleration for one, two, and three carts indicates that if the same force is applied in each situation, the acceleration of two carts is the acceleration of one cart and the acceleration of three carts is the acceleration of one cart.

SECTION4.1 Force and Motion Acceleration and Force (cont.) This means that as the number of carts is increased, a greater force is needed to produce the same acceleration. The slopes of the lines in the graph depend upon the number of carts; that is, the slope depends on the total mass of the carts.

SECTION4.1 Force and Motion Acceleration and Force (cont.)

SECTION4.1 Force and Motion Acceleration and Force (cont.) The formula, F = ma, tells you that if you double the force, you will double the object’s acceleration. If you apply the same force to several different objects, the one with the most mass will have the smallest acceleration and the one with the least mass will have the greatest acceleration. One unit of force causes a 1-kg mass to accelerate at 1 m/s2, so one force unit has the dimensions 1 kg·m/s2 or one newton and is represented by N.

Force and Motion Newton’s Second Law
SECTION4.1 Force and Motion Newton’s Second Law The observation that acceleration of an object is proportional to the net force exerted on it and inversely proportional to its mass is Newton’s second law, which can be represented in the following equation. Newton’s second law states that the acceleration of an object is equal to the sum of the forces (the net force) acting on the object, divided by the mass of the object.

Newton’s Second Law (cont.)
SECTION4.1 Force and Motion Newton’s Second Law (cont.) One of the most important steps in correctly applying Newton’s second law is determining the net force acting on the object. Draw a free-body diagram showing the direction and relative strength of each force acting on the system. Then add the force vectors to find the net force.

Newton’s Second Law (cont.)
SECTION4.1 Force and Motion Newton’s Second Law (cont.) Next, use Newton’s second law to calculate the acceleration. Finally, if necessary, use what you know about accelerated motion to find the velocity or position of the object.

Force and Motion Fighting Over a Toy
SECTION4.1 Force and Motion Fighting Over a Toy Anudja is holding a stuffed dog with a mass of kg, when Sarah decides that she wants it and tries to pull it away from Anudja. If Sarah pulls horizontally on the dog with a force of 10.0 N and Anudja pulls with a horizontal force of 11.0 N, what is the horizontal acceleration of the dog?

Step 1: Analyze and Sketch the Problem
SECTION4.1 Force and Motion Fighting Over a Toy Step 1: Analyze and Sketch the Problem Sketch the situation. Identify the stuffed dog as the system and the direction in which Anudja pulls as positive. Draw the free-body diagram. Label the force.

Step 2: Solve for the Unknown
SECTION4.1 Force and Motion Fighting Over a Toy Step 2: Solve for the Unknown

SECTION4.1 Force and Motion Fighting Over a Toy Identify known and unknown variables. Known: m = 0.30 kg FAnudja on dog = 11.0 N FSarah on dog = 10.0 N Unknown: a = ?

SECTION4.1 Force and Motion Fighting Over a Toy Use Newton’s second law to solve for a. Fnet = FAnudja on dog + (-FSarah on dog)

SECTION4.1 Force and Motion Fighting Over a Toy Substitute Fnet= FAnudja on dog+ (–FSarah on dog)

SECTION4.1 Force and Motion Fighting Over a Toy Substitute FAnudja on dog = 11.0 N, FSarah on dog = 10.0 N, m = 0.30 kg

Step 3: Evaluate the Answer
SECTION4.1 Force and Motion Fighting Over a Toy Step 3: Evaluate the Answer

Force and Motion Fighting Over a Toy Are the units correct?
SECTION4.1 Force and Motion Fighting Over a Toy Are the units correct? m/s2 is the correct unit for acceleration. Does the sign make sense? The acceleration is in the positive direction because Anudja is pulling in the positive direction with a greater force than Sarah is pulling in the negative direction.

Force and Motion Fighting Over a Toy Is the magnitude realistic?
SECTION4.1 Force and Motion Fighting Over a Toy Is the magnitude realistic? It is a reasonable acceleration for a light, stuffed toy.

Force and Motion Fighting Over a Toy The steps covered were:
SECTION4.1 Force and Motion Fighting Over a Toy The steps covered were: Step 1: Analyze and Sketch the Problem Sketch the situation. Identify the stuffed dog as the system and the direction in which Anudja pulls as positive. Draw the free-body diagram. Label the forces.

Force and Motion Fighting Over a Toy The steps covered were:
SECTION4.1 Force and Motion Fighting Over a Toy The steps covered were: Step 2: Solve for the Unknown Step 3: Evaluate the Answer

Force and Motion Newton’s First Law
SECTION4.1 Force and Motion Newton’s First Law What is the motion of an object with no net force acting on it? Newton’s second law states says that if net force is zero, then acceleration equal zero. If acceleration is zero, then velocity does not change. A stationary object with no net force acting on it will stay at rest.

Newton’s First Law (cont.)
SECTION4.1 Force and Motion Newton’s First Law (cont.) What about a moving object like a rolling ball? How long will it roll? Depends on the surface: thick carpet exerts more force than a smooth hard surface like a bowling alley. So the ball will stop rolling sooner on the carpet than the bowling alley.

SECTION4.1 Force and Motion Newton’s First Law (cont.) Galileo did many experiments, and he concluded that in the ideal case of zero resistance, horizontal motion would never stop. Galileo was the first to recognize that the general principles of motion could be found by extrapolating experimental results to the ideal case, in which there is no resistance to slow down an object’s motion.

SECTION4.1 Force and Motion Newton’s First Law (cont.) In the absence of a net force, the motion (or lack of motion) of both the moving object and the stationary object continues as it was. Newton recognized this and generalized Galileo’s results in a single statement. This statement, “an object that is at rest will remain at rest, and an object that is moving will continue to move in a straight line with constant speed, if and only if the net force acting on that object is zero,” is called Newton’s first law.

SECTION4.1 Force and Motion Newton’s First Law (cont.) Newton’s first law is sometimes called the law of inertia. Inertia is the tendency of an object to resist change. If an object is at rest, it tends to remain at rest. If it is moving at a constant velocity, it tends to continue moving at that velocity. Forces are results of interactions between two objects; they are not properties of single objects, so inertia cannot be a force.

SECTION4.1 Force and Motion Newton’s First Law (cont.) If the net force on an object is zero, then the object is in equilibrium. An object is in equilibrium if its velocity is not changing. Newton’s first law identifies a net force as something that disturbs the state of equilibrium. Thus, if there is no net force acting on the object, then the object does not experience a change in speed or direction and is in equilibrium.

SECTION4.1 Force and Motion Newton’s First Law (cont.) Some of the common types of forces are displayed on the right. When analyzing forces and motion, it is important to keep in mind that the world is dominated by resistance. Newton’s ideal, resistance-free world is not easy to visualize.

SECTION4.1 Section Check Two horses are pulling a 100-kg cart in the same direction, applying a force of 50 N each. What is the acceleration of the cart? A. 2 m/s2 B. 1 m/s2 C m/s2 D. 0 m/s2

SECTION4.1 Section Check Answer Reason: If we consider positive direction to be the direction of pull then, according to Newton’s second law,

SECTION4.1 Section Check Two friends Mary and Maria are trying to pull a 10-kg chair in opposite directions. If Maria applied a force of 60 N and Mary applied a force of 40 N, in which direction will the chair move and with what acceleration?

SECTION4.1 Section Check A. The chair will move towards Mary with an acceleration of 2 m/s2. B. The chair will move towards Mary with an acceleration of 10 m/s2. C. The chair will move towards Maria with an acceleration of 2 m/s2. D. The chair will move towards Maria with an acceleration of 10 m/s2.

SECTION4.1 Section Check Answer Reason: Since the force is applied in opposite directions, if we consider Maria’s direction of pull to be positive, then net force = 60 N – 40 N = 20 N . Thus, the chair will accelerate towards Maria.

State Newton’s first law.
SECTION4.1 Section Check State Newton’s first law. Answer: Newton’s first law states that “an object that is at rest will remain at rest, and an object that is moving will continue to move in a straight line with constant speed, if and only if the net force acting on that object is zero”.

Weight and Drag Force MAIN IDEA Essential Questions
SECTION4.2 Weight and Drag Force MAIN IDEA Newton’s second law can be used to explain the motion of falling objects. Essential Questions How are the weight and the mass of an object related? How do actual weight and apparent weight differ? What effect does air have on falling objects?

Weight and Drag Force Review Vocabulary New Vocabulary
SECTION4.2 Weight and Drag Force Review Vocabulary viscosity a fluid’s resistance to flowing. New Vocabulary Weight Gravitational pull Apparent weight Weightlessness Drag force Terminal velocity

Weight and Drag Force Weight
SECTION4.2 Weight and Drag Force Weight Weight is the gravitational force experienced by an object. This gravitational force is a field force whose magnitude is directly proportional to the mass of the object experiencing the force: Fg = mg, where m is the mass of the object and g is the gravitational field. Because weight is a force, the proper unit used to measure weight is the newton.

Weight and Drag Force Weight (cont.)
SECTION4.2 Weight and Drag Force Weight (cont.) Gravitational field is a vector quantity that relates the mass of an object to the gravitational force it experiences at a given location. Near Earth’s surface, g is 9.8N/kg toward Earth’s center. When you step on a scale, the scale exerts an upward force on you equal in magnitude to the gravitational force pulling down on you. The scale is calibrated to convert the stretch of the springs, the upward force necessary to give a net force of zero, to weight .

Click image to view movie.
SECTION4.2 Weight and Drag Force Weight (cont.) Apparent weight and weightlessness. Click image to view movie.

Weight and Drag Force Drag Force
SECTION4.2 Weight and Drag Force Drag Force When an object moves through any fluid, such as air or water, the fluid exerts a drag force on the moving object in the direction opposite to its motion. A drag force is the force exerted by a fluid on the object moving through the fluid. This force is dependent on the motion of the object, the properties of the object, and the properties of the fluid (viscosity and temperature) that the object is moving through.

Weight and Drag Force Drag Force (cont.)
SECTION4.2 Weight and Drag Force Drag Force (cont.) As a dropped tennis ball’s velocity increases, so does the drag force. The constant velocity that is reached when the drag force equals the force of gravity is called the terminal velocity.

Click image to view movie.
SECTION4.2 Weight and Drag Force Drag Force (cont.) Click image to view movie.

SECTION4.2 Weight and Drag Force If the mass of a person on Earth is 20 kg, what will be his mass on the Moon? (Gravity on the Moon is six times less than the gravity on Earth.)

Weight and Drag Force Answer
SECTION4.2 Weight and Drag Force Answer Reason: The mass of an object does not change with the change in gravity, only the weight changes.

SECTION4.2 Weight and Drag Force Your mass is 100 kg, and you are standing on a bathroom scale in an elevator. What is the scale reading when the elevator is falling freely?

SECTION4.2 Weight and Drag Force Answer Reason: Since the elevator is falling freely with acceleration g, the contact force between the elevator and you is zero. As scale reading displays the contact force, it would be zero.

SECTION4.2 Weight and Drag Force In which of the following cases will your apparent weight be greater than your real weight? A. The elevator is at rest. B. The elevator is accelerating upward. C. The elevator is accelerating downward. D. Apparent weight is never greater than real weight.

SECTION4.2 Weight and Drag Force Answer Reason: When the elevator is moving upward, your apparent weight Fapparent = ma + Fg (where m is your mass and a is the acceleration of the elevator). So your apparent weight becomes more than your real weight.

Newton’s Third Law MAIN IDEA Essential Questions
SECTION4.3 Newton’s Third Law MAIN IDEA All forces occur in interaction pairs. Essential Questions What is Newton’s third law? What is the normal force?

Newton’s Third Law Review Vocabulary New Vocabulary
SECTION4.3 Newton’s Third Law Review Vocabulary symmetry correspondence of parts on opposite sides of a dividing line. New Vocabulary Interaction pair Newton’s third law Tension Normal force

Newton’s Third Law Interaction Pairs
SECTION4.3 Newton’s Third Law Interaction Pairs When you exert a force on your friend to push him forward, he exerts an equal and opposite force on you, which causes you to move backward. The forces FA on B and FB on A are an interaction pair. An interaction pair is two forces that are in opposite directions and have equal magnitude.

Interaction Pairs (cont.)
SECTION4.3 Newton’s Third Law Interaction Pairs (cont.) An interaction pair is also called an action-reaction pair of forces. This might suggest that one causes the other; however, this is not true. For example, the force of you pushing your friend doesn’t cause your friend to exert a force on you. The two forces either exist together or not at all. They both result from the contact between the two of you.

SECTION4.3 Newton’s Third Law Interaction Pairs (cont.) The force of you on your friend is equal in magnitude and opposite in direction to the force of your friend on you. This is summarized in Newton’s third law, which states that all forces come in pairs.

SECTION4.3 Newton’s Third Law Interaction Pairs (cont.) Newton’s Third Law states that the force of A on B is equal in magnitude and opposite in direction of the force of B on A. The two forces in a pair act on different objects and are equal and opposite. Numerically, FA on B = – FB on A

SECTION4.3 Newton’s Third Law Interaction Pairs (cont.) When identifying an interaction pair, remember that they always occur in two different free-body diagrams and they always have the symmetry in subscripts noted on the previous slide.

Newton’s Third Law Earth’s Acceleration
SECTION4.3 Newton’s Third Law Earth’s Acceleration A softball has a mass of 0.18 kg. What is the gravitational force on Earth due to the ball, and what is Earth’s resulting acceleration? Earth’s mass is 6.0×1024 kg.

Earth’s Acceleration (cont.)
SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Step 1: Analyze and Sketch the Problem Draw free-body diagrams for the two systems: the ball and Earth. Connect the interaction pair by a dashed line.

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Identify known and unknown variables. Known: mball = 0.18 kg mEarth = 6.0×1024 kg g = m/s2 Unknown: FEarth on ball = ? aEarth = ?

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Step 2: Solve for the Unknown

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Use Newton’s second law to find the weight of the ball. FEarth on ball = mballg

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Substitute mball = 0.18 kg, g = m/s2 FEarth on ball = (0.18 kg)(-9.80 m/s2) = -1.8 N

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Use Newton’s third law to solve for Fball on Earth. Fball on Earth = –FEarth on ball

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Substitute FEarth on ball = –1.8 N Fball on Earth = – (– 1.8 N) = +1.8N

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Use Newton’s second and third laws to find aEarth.

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Substitute Fnet = 1.8 N, mEarth= 6.0×1024 kg

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Step 3: Evaluate the Answer

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Are the units correct? Dimensional analysis verifies force in N and acceleration in m/s2. Does the sign make sense? Force and acceleration should be positive.

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) Is the magnitude realistic? Because of Earth’s large mass, the acceleration should be small.

SECTION4.3 Newton’s Third Law Earth’s Acceleration (cont.) The steps covered were: Step 1: Analyze and Sketch the Problem Draw free-body diagrams for the two systems: the ball and Earth. Connect the interaction pair by a dashed line. Step 2: Solve for the Unknown Step 3: Evaluate the Answer

Newton’s Third Law Tension
SECTION4.3 Newton’s Third Law Tension The force exerted by a string or rope is called tension. At any point in a rope, the tension forces are pulling equally in both directions.

SECTION4.3 Newton’s Third Law Tension (cont.)

Newton’s Third Law The Normal Force
SECTION4.3 Newton’s Third Law The Normal Force The normal force is the perpendicular contact force exerted by a surface on another object. The normal force is important when calculating resistance.

SECTION4.3 Section Check Explain Newton’s third law.

SECTION4.3 Section Check Answer Answer: Suppose you push your friend. The force of you on your friend is equal in magnitude and opposite in direction to the force of your friend on you. This is summarized in Newton’s third law, which states that forces come in pairs. The two forces in a pair act on different objects and are equal in strength and opposite in direction. Newton’s third law FA on B = – FB on A The force of A on B is equal in magnitude and opposite in direction of the force of B on A.

SECTION4.3 Section Check If a stone is hung from a rope with no mass, at which place on the rope will there be the most tension? A. The top of the rope, near the hook. B. The bottom of the rope, near the stone. C. The middle of the rope. D. The tension will be the same throughout the rope.

SECTION4.3 Section Check Answer Reason: Because the rope is assumed to be without mass, the tension everywhere in the rope is equal to the stone’s weight.

CHAPTER4 Forces in One Dimension Resources Physics Online Study Guide Chapter Assessment Questions Standardized Test Practice

SECTION4.1 Force and Motion Study Guide A force is a push or a pull. Forces have both direction and magnitude. A force might be either a contact force or a field force. Newton’s second law states that the acceleration of a system equals the net force acting on it divided by its mass.

SECTION4.1 Force and Motion Study Guide Newton’s first law states that an object that is at rest will remains at rest and an object that is moving will continue to move in a straight line with constant speed, if and only if the net force acting on that object is zero. An object with zero net force acting on it is in equilibrium.

SECTION4.2 Weight and Drag Force Study Guide The object’s weight (Fg) depends on the object’s mass and the gravitational field at the object’s location. An object’s apparent weight is the magnitude of the support force exerted on it. An object with no apparent weight experiences weightlessness.

SECTION4.2 Weight and Drag Force Study Guide A falling object reaches a constant velocity when the drag force is equal to the object’s weight. The constant velocity is called the terminal velocity. The drag force on an object is determined by the object’s weight, size and shape as well as the fluid through which it moves.

SECTION4.3 Newton’s Third Law Study Guide Newton’s third law states that the two forces that make up an interaction pair of forces are equal in magnitude, but opposite in direction and act on different objects. In an interaction pair, FA on B does not cause FB on A. The two forces either exist together or not at all.

SECTION4.3 Newton’s Third Law Study Guide The normal force is a support force resulting from the contact between two objects. It is always perpendicular to the plane of contact between the two objects.

CHAPTER4 Forces in One Dimension Chapter Assessment Combining Forces If you and your friend exert a force of 100 N each on a table, first in the same direction and then in opposite directions, what is the net force?

CHAPTER4 Forces in One Dimension Chapter Assessment Combining Forces In the first case, your friend is pushing with a negative force of 100 N. Adding them together gives a total force of 0 N.

CHAPTER4 Forces in One Dimension Chapter Assessment Combining Forces In the second case, your friend’s force is 100 N, so the total force is 200 N in the positive direction and the table accelerates in the positive direction.

CHAPTER4 Forces in One Dimension Chapter Assessment Newton’s Second Law Newton’s second law can be rearranged to the form F = ma, which you learned about previously. Assume that the table that you and your friend were pushing was 15.0 kg and the two of you each pushed with a force of 50.0 N in the same direction. To find out what the acceleration of the table would be, calculate the net force, 50.0 N N = N, and apply Newton’s second law by dividing the net force of N by the mass of the table, 15.0 kg, to get an acceleration of 6.67 m/s2.

CHAPTER4 Forces in One Dimension Chapter Assessment Forces of Ropes and Strings Tension forces are at work in a tug-of-war. If team A, on the left, is exerting a force of 500 N and the rope does not move, then team B, must also be pulling with 500 N. Tim Fuller

CHAPTER4 Forces in One Dimension Chapter Assessment Fighting Over a Toy Anudja is holding a stuffed dog, with a mass of kg, when Sarah decides that she wants it and tries to pull it away from Anudja. If Sarah pulls horizontally on the dog with a force of 10.0 N and Anudja pulls with a horizontal force of 11.0 N, what is the horizontal acceleration of the dog?

CHAPTER4 Forces in One Dimension Chapter Assessment Earth’s Acceleration When a softball with a mass of 0.18 kg is dropped, its acceleration toward Earth is equal to g, the acceleration due to gravity. What is the force on Earth due to the ball, and what is Earth’s resulting acceleration? Earth’s mass is 6.0×1024 kg.

CHAPTER4 Forces in One Dimension Chapter Assessment If a golf ball, baseball and bowling ball are thrown with the same force, which ball will move with a greater acceleration? A. Golf ball B. Baseball C. Bowling ball D. The three balls will have equal acceleration.

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: As , the lesser the mass the greater the acceleration. Since the golf ball has the least mass, it will move with the greatest acceleration.

CHAPTER4 Forces in One Dimension Chapter Assessment Jack is boating in a river applying a contact force of 30 N, in a direction opposite to the flow of water. At the same time, the water is exerting a force of 30 N on the boat. In which direction will the boat move? A. The boat will move in the direction of the flow of water. B. The boat will not move at all. C. The boat will move back and forth within a particular distance. D. The boat will move in the direction opposite to the flow of water.

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: Since two equal and opposite forces are acting together, the net force is zero. Hence, the boat will not move at all.

CHAPTER4 Forces in One Dimension Chapter Assessment What is inertia? A. Force. B. The tendency of a body to stay only at rest C. The tendency of a body to move with constant acceleration D. The tendency of a body to move with constant velocity

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: Inertia of a body is the tendency of a body to stay at rest and/or to move with a constant velocity. Remember being at rest is simply a special case of constant velocity, v = 0 m/s.

CHAPTER4 Forces in One Dimension Chapter Assessment If the weight of a person on Earth is 120 N, what will his weight be on the Moon? (Gravity on the Moon is six times less than the gravity on Earth.) A. C. D. B.

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: Gravity on the Moon is Mass of the person is (since mass = weight/g).

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: Weight of person on the Moon = Gravity on the Moon × mass of person So, the weight of the person on the Moon

CHAPTER4 Forces in One Dimension Chapter Assessment What happens when the drag force is equal to the force of gravity? A. The object comes to rest. B. The object moves with constant acceleration. C. The object moves with constant velocity. D. The velocity of the object increases.

CHAPTER4 Forces in One Dimension Chapter Assessment Reason: When drag force equals the force due to gravity, the net force acting on the object is zero. As a result of this, the object moves with constant velocity, which is called terminal velocity.

CHAPTER4 Forces in One Dimension Standardized Test Practice What is the acceleration of the car described by the graph on the right? A m/s2 B m/s2 C m/s2 D m/s2

CHAPTER4 Forces in One Dimension Standardized Test Practice What distance will the car described by the above graph have traveled after 4.0 s? A. 13 m B. 40 m C. 80 m D. 90 m

CHAPTER4 Forces in One Dimension Standardized Test Practice If the car in the graph on the right maintains a constant acceleration, what will its velocity be after 10 s. A. 10 km/h B. 25 km/h C. 90 km/h D km/h

CHAPTER4 Forces in One Dimension Standardized Test Practice In a tug-of-war, 13 children, with an average mass of 30 kg each, pull westward on a rope with an average force of 150 N per child. Five parents, with an average mass of 60 kg each, pull eastward on the other end of the rope with an average force of 475 N per adult. Assuming that the whole mass accelerates together as a single entity, what is the acceleration of the system? A m/s2 E B m/s2 W C m/s2 E D m/s2 W

CHAPTER4 Forces in One Dimension Standardized Test Practice What is the weight of a 225-kg space probe on the Moon? The acceleration of gravity on the Moon is 1.62 m/s2. A N B N C ×103 N D ×103 N

CHAPTER4 Forces in One Dimension Standardized Test Practice Test-Taking Tip Maximize Your Score If possible, find out how your standardized test will be scored. In order to do your best, you need to know if there is a penalty for guessing, and if so, what the penalty is. If there is no random-guessing penalty at all, you should always fill in an answer, even if you have not read the question.

CHAPTER4 Forces in One Dimension Chapter Resources Forces Exerted on the Book

CHAPTER4 Forces in One Dimension Chapter Resources Ball Tied to a String

CHAPTER4 Forces in One Dimension Chapter Resources Ball Held in Your Hand

CHAPTER4 Forces in One Dimension Chapter Resources The Cart’s Motion Shown in a Linear Relationship

CHAPTER4 Forces in One Dimension Chapter Resources Acceleration of Cart

CHAPTER4 Forces in One Dimension Chapter Resources Force-Acceleration Graph

CHAPTER4 Forces in One Dimension Chapter Resources Combining Forces

CHAPTER4 Forces in One Dimension Chapter Resources Fighting Over a Toy

CHAPTER4 Forces in One Dimension Chapter Resources An Elevator Accelerating Upward

CHAPTER4 Forces in One Dimension Chapter Resources A Soccer Ball on a Table on Earth

CHAPTER4 Forces in One Dimension Chapter Resources Earth’s Acceleration

CHAPTER4 Forces in One Dimension Chapter Resources The Normal Force on an Object

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