Newton's First Law of Motion
Last Updated : 23 Jul, 2025
Before the revolutionary ideas of Galileo and Newton, people commonly believed that objects naturally slowed down over time because it was their inherent nature. This assumption stemmed from everyday observations, where things like friction, air resistance, and gravity seemed to slow moving objects.
⇒However, what those early thinkers didn't realize was that they were missing the larger picture: the role that forces, such as friction and gravity, play in changing an object's motion on Earth.
⇒Had they been able to observe an object in the vacuum of space, far from any forces that might influence its movement—like gravity or atmospheric drag—they would have seen something radically different.
⇒In such a setting, an object would keep moving at a constant speed in a straight line unless an external force acted on it to change its motion.
⇒If the object were stationary, it would stay at rest unless something pushed or pulled on it. This realization, articulated by Newton in his First Law of Motion, revealed a key truth about the natural world: objects don't inherently want to stop moving—they only change their motion when a force makes them do so.
Newton’s First Law of Motion, also known as the law of inertia, states that a body always opposes its change in the state of motion.
⇒Newton's Laws of Motion were first proposed by ''Sir Isaac Newton'' in the late 17th century.
⇒Newton's First Law of Motion finds its importance in various other laws, and it is one of the fundamental laws of physics. It also holds significant importance in various real-life examples.
Here, we will learn about Newton’s First Law of Motion, its examples, real-life applications of Newton's First Law of Motion, Newton's First Law of Motion equations, and some practice problems on Newton's First Law of Motion.
What is Newton’s First Law of Motion?
Newton’s first law of motion states that,
"An object at rest will remain at rest, and an object in motion will remain in motion with a constant velocity, unless acted upon by an external force."
In simple words, an object which is at rest will continue to stay at rest and an object which is in uniform motion continues to stay in uniform motion until an external force is applied. The first law of motion is also called as Law of Inertia.
Newton's First Law of Motion Class 9
Newton's First Law of Motion, often introduced in class 9 physics, is a fundamental concept if a body is at rest or moving at a constant speed in a straight line, it will stay at rest or continue moving in the same way unless a force acts on it.
This law not only applies to physical objects in our everyday life but also forms a basis for more complex principles in physics. Understanding this law paves the way for comprehending the forces at play in the universe and is a critical step for students in class 9 to grasp the broader concepts of physics.
The formula for Newton's First Law of Motion is:
Fnet=0
- This means if the total (net) force acting on an object is zero, the object will either stay at rest or keep moving in a straight line at a constant speed.
- If an object is at rest: It will stay at rest until a force makes it move. This means that if an object is already in motion, it will continue moving in the same direction and with the same speed, and if it is at rest, it will remain at rest. This condition is fundamental to understanding the behavior of objects in motion and the effect of forces on their motion.
- If an object is moving: It will keep moving in a straight line at the same speed until a force changes its speed or direction. An inertial reference frame is a reference frame that is either at rest or moving with a constant velocity relative to other reference frames. The use of an inertial reference frame ensures that the observation of the object's motion is consistent and not affected by the motion of the observer. If the observer is not in an inertial reference frame, then the observation of the object's motion will be distorted by the observer's motion.
- In simple terms, an object will not change its motion (i.e., it won't accelerate) unless a net external force acts on it. This principle, known as inertia, is key to understanding how objects behave when different forces are applied to them.
Also Read,
Understanding Force and Net Force
Force refers to a push or pull that can cause an object to change its state of motion or shape.
- It can be applied in various forms, such as gravity pulling an object downward, or a person pushing a box across the floor. Forces are measured in units called Newtons (N).
- Net force is the total force acting on an object after all individual forces have been combined. It is the vector sum of all the forces. If multiple forces are acting in different directions, the net force determines the overall effect on the object’s motion.
For example, if a person pushes a box with 10 N of force to the right, and another person pushes with 5 N to the left, the net force would be 5 N to the right. If forces cancel each other out, the net force would be zero, meaning no change in motion would occur.
- Person 1 pushes the box with a force of 10 N to the right.
- Person 2 pushes the box with a force of 5 N to the left.
- To the right: Positive direction (+10 N).
- To the left: Negative direction (-5 N).
⇒Net Force= 10N(right)+(−5N)(left)
⇒Net Force=10N−5N=5N
⁛The net force acting on the box is 5 N to the right.
Examples of Newton's First Law of Motion
Now, Let us understand the First Law of Motion by various examples that we can observe in our daily life. Newton's first law of motion examples can be observed in numerous everyday situations:
Example 1: A Stationary Car
A car parked on a level surface will remain stationary until an external force, such as a push, is applied, In this picture a person applied a force on car but the car didn't move.
Example 2: A Rolling Ball
A ball rolling on a flat surface will continue to roll in a straight line unless friction or another force stops it.
The image given below shows a football that is placed on the ground it will not move until a net external force is applied to it.
The football move in the direction of applied force. In simple words, we can say that objects cannot start, stop, or change direction on their own. They require some external force to change their state. This tendency of objects to resist changes in their state of motion or rest is known as inertia.
Example 2: A Passenger in a Car
When a car suddenly stops, passengers lurch forward because their bodies continue to move forward due to inertia.
Applications of Newton's First law of Motion
In our daily life, we came across various examples which support Newton’s First Law of Motion.
Some of the examples which support this law are,
- When the brakes of a vehicle are applied quickly, the passenger will be thrown forward due to the presence of inertia. Inertia tries to keep the passenger moving. This is the reason why it is recommended to wear seat belts while travelling by vehicle.
- A roller coaster uses the principle of inertia. It continues to move in the same direction at a constant speed until the tracks act as an external force that changes its direction.
- If you slide a hockey puck on ice, eventually it will stop. This is because of friction on the ice or if it hits something, like a player’s stick or a goalpost.
- A book lying on the table remains at rest as long as no net force acts on it.
- A marathon runner continues to run several meters beyond the finish line due to inertia.
- If pulled quickly, a tablecloth can be removed from underneath the dishes. The dishes remain still unless the friction from the movement of the tablecloth is not too high in magnitude.
- Men in space find it more difficult to stop moving because of a lack of gravity acting against them.
- Inertia enables ice skaters to glide on the ice in a straight-line motion.
Concept of Inertia
Newton's First Law of Motion Describes the Concept of Inertia, Inertia is the resistance of an object to any change in its state of motion. It is a fundamental property of matter that describes how objects tend to maintain their current state of motion.
⇒An object at rest tends to stay at rest, and an object in motion tends to stay in motion with the same speed and direction unless acted upon by an external force. This property of matter was first described by Sir Isaac Newton in his first law of motion, which is also known as the law of inertia.
⇒The inertia of an object depends on its mass. The greater the mass of an object, the greater its inertia, and the more difficult it is to change its state of motion.
For example, a massive object like a boulder requires more force to set it in motion than a lighter object like a pebble. Similarly, a moving car requires more force to bring it to a stop than a bicycle moving at the same speed.
What is an External Force?
The force applied on an object externally that produces an acceleration in the body is called the external force. For an object of mass 'm' and the external force applied is 'F' then the acceleration produced is 'a' the relation between them is,
F = m×a
S.I. unit of force is Newton (N).
External force can be categorized as,
- Balanced Forces: The force is said to be balanced forces if they nullify one another and their resultant force is equivalent to zero.
- Unbalanced forces: When two opposite forces acting on a body, move a body in the direction of the greater force or forces which bring a motion in a body are called unbalanced forces.
Read More: Balancedand Unbalanced Forces
Free Body Diagrams
Free body diagrams also called FBD are very useful to solve various problems of mechanics. FBDs show all the force that is being applied to any object in the proper directions. To solve problems on Newton’s Laws of Motion using FBD use the steps given below:
Steps to Solve Problems on Newton’s Laws of Motion:
In a fixed wedge a block of mass m is kept now we have to find the acceleration of the block then,
Step 1: Draw the F.B.D of the block,
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Step 2: Write all the components of the force acting on the block in the 'x' and 'y' components.
Force acting along incline plane,
Fincline = mg sin45°
Force acting along normal,
Fnormal = mg cos45°
Step 3: Find the acceleration using Newton's law of motion.
ma = mg sin45°
a = g sin45°
Constraint Equations
Constraint Equations are formed in such motions where the motion of one body is dependent on the motion of another body i.e. motion of one body affects the motion of another body.
In the above pulley system, it is evident that the motion of blocks M1 and M2 are interdependent on each other and hence constraint equations are formed.
We have two equations and three unknowns, thus a constraint equation is required to solve the above equations.
M1g - T = M1a1
M2a2 = 2T - M2g
Solved Examples - Newton's First Law of Motion
Example 1: A person is in an elevator that moving upward at a constant velocity. The weight of the person is 800 N. Immediately the elevator rope broke, so the elevator falls. Determine the normal force acted by the elevator’s floor on the person just before and after the elevator’s rope broke.
Solution:
Given that,
The weight of the person, W = 800 N.
Before the elevator’s rope broke:
When the person is in the elevator, weight acts on the person downwards. A normal force acts on the person upwards and the magnitude of the normal force is equal to the weight. Because the person is at rest in the elevator and the elevator moves at a constant speed with no acceleration, so there is no net force acting on the person.
∑F = 0
N – w = 0
N = w
N = 800 N
After the elevator’s rope broke:
The elevator and the person free fall together, where the magnitude and the direction of their acceleration(a) is equal to acceleration due to gravity(g). There is no normal force on the person.
- Once the elevator's rope breaks, both the person and the elevator are in free fall. This means both are accelerating downward due to gravity at the same rate, ggg.
- When an object is in free fall, the normal force from the floor is zero because there is no longer any force exerted by the floor on the person. The person is essentially "weightless" in this scenario because both the person and the elevator are accelerating together at the same rate.
Hence, the normal force acted by elevator’s floor to the person just before and after the elevator’s rope broke are 800 N and 0 N respectively.
Example 2: What net force is required to keep a 100 kg object moving with a constant velocity of 10 m/s?
Solution:
Newton's first law states that an object in motion tends to stay in motion unless if acted upon by a net force. This means that if friction is not present, there is no net force required to keep an object moving if it's in motion.
A net force is only required to change an object's motion. The 100 kg object is moving at a constant velocity i.e. there is no net force acting on the object.
So, the net force is equal to 0 N.
Example 3: A person is traveling in an aeroplane at a constant speed of 500 mph. Another person is travelling in their car at a constant speed of 50 mph. Determine who experiences a larger acceleration in both cases.
Solution:
Since both the persons are traveling at a constant speed, the acceleration of both the persons is zero.
Thus, neither of the person experiences any acceleration.
Since the acceleration is zero, then there is no net force acting on both the persons.
Example 4: A passenger in an elevator has a mass that exerts a force of 110N downwards. He experiences a normal force upwards from the elevator's floor of 130N. What direction is he accelerating in, if at all, and at what rate? Use g=10 m/s2
Solution:
Here, the net force is equal to (130 - 120) N = 20 N upwards.
To find the mass of the passenger, use the following formula:
F = mg
m = 110 N/ 10 m/s2
= 11 kg
Then, to find the net acceleration, use Newton's second law.
F = ma
a = 20N /11kg
= 1.82 m/s2
Example 5: A 1500 kg spaceship travels in the vacuum of space at a constant speed of 600 m/s. Ignoring any gravitational forces, what is the net force on the spaceship?
Solution:
In a vacuum, there is no friction due to air resistance. Newton's first law states that an object in motion stays in motion unless acted upon by a net force. Thus, the spaceship will travel at the constant speed of 600 m/s and the net force on the spaceship must be zero as acceleration is also zero.
Since,
F = ma
Therefore,
F = (1500kg)(0m/s2)
= 0 N.
Example 6: A ball rolls off the back of a train going 50 mph. Neglecting air friction, what is the horizontal speed of the ball just before it hits the ground?
Solution:
Newtons first law states than an object in motion tends to stay in motion unless acted upon by an external force.
Neglecting air friction, there is no external force to slow the ball down in the horizontal direction after it falls off the train.
The acceleration of gravity would only affect the ball in the vertical direction.
So, the horizontal speed of the ball is 50 mph.
Example 7: A van is driving around with a bowling ball in the back, free to roll around. The van approaches a red light and must decelerate to come to a complete stop. As the van is slowing down, in which direction is the bowling ball rolling?
Solution:
According to Newton's First Law of Motion, an object that is in motion will stay in motion unless acted on by another force.
When the van slows down, the ball will want to continue moving forward, and the friction between it and the floor of the van is not strong enough to keep the ball back.
So, the bowling ball rolls to the front of van.
Practice Questions
1. A space probe is drifting to the right at a constant velocity in deep interstellar space, far from any external forces. Two rocket thrusters are activated, exerting equal and opposite forces leftward and rightward. What happens to the motion of the probe?
a. The space probe would continue with constant velocity.
b. The space probe would speed up.
c. The space probe would slow down and eventually stop.
d. The space probe would immediately stop.
Correct Answer: (a)
Explanation: According to Newton's First Law of Motion, an object will continue in its state of motion unless acted upon by an unbalanced force. Since the forces from the two thrusters cancel each other out, there is no net force, and the probe continues to move at a constant velocity.
2. An elevator is moving upward at a constant velocity. How does the upward force exerted by the cable compare to the downward force of gravity on the elevator?
a. The upward force is greater than the downward force.
b. The upward force is equal to the downward force.
c. The upward force is smaller than the downward force.
d. The upward force could be larger or smaller than the downward force depending on the mass of the elevator.
Correct Answer:( b)
Explanation: When the elevator is moving with constant velocity, the net force must be zero according to Newton’s First Law. For the forces to cancel each other out, the upward force exerted by the cable must be exactly equal to the downward force of gravity.
3. A space probe is drifting to the right at constant velocity in deep interstellar space. A rocket thruster briefly fires in a direction perpendicular to the probe's motion, then turns off. What path does the probe follow after the thruster is turned off?
a. The probe will move downward in a curved path.
b. The probe will curve slightly downward and to the right.
c. The probe will move in a straight line to the right.
d. The probe will move diagonally downward and to the right.
Correct Answer: (c)
Explanation: Once the thruster is turned off, there is no net force acting on the probe. According to Newton's First Law, the probe will continue in a straight line at constant velocity. The force from the thruster only altered the vertical velocity, but with no further forces, the horizontal velocity remains constant, so the probe moves in a straight line.
4. A space probe in deep space is traveling with a constant velocity. What happens if no external forces are acting on the probe?
a. The probe will eventually stop due to internal friction.
b. The probe will change direction due to gravitational influences.
c. The probe will continue moving at the same velocity and in the same direction.
d. The probe will accelerate in the direction of its motion.
Correct Answer: (c)
Explanation: In the absence of external forces, the probe will continue to move at the same velocity and in the same direction. This is a direct consequence of Newton's First Law of Motion, which states that an object in motion will stay in motion unless acted upon by an external force.
5. A car is moving at a constant speed on a straight road. The engine is providing a force to move the car forward, but friction and air resistance are acting against the motion. What is the net force acting on the car?
a. The net force is greater than zero because the car is moving.
b. The net force is zero because the car is moving at constant velocity.
c. The net force is zero because the forces from the engine and friction cancel each other out.
d. The net force is in the direction of the engine’s force.
Correct Answer: (b)
Explanation: Since the car is moving at a constant speed, there is no acceleration, meaning the forces must balance out. The forward force from the engine is exactly canceled by the friction and air resistance. Therefore, the net force is zero.
7. A rocket in space is initially at rest. It fires its thrusters in one direction for a short burst and then turns them off. What will happen to the rocket once the thrusters are off?
a. The rocket will continue moving in the direction it fired its thrusters.
b. The rocket will stop moving.
c. The rocket will move in the opposite direction of the thrusters.
d. The rocket’s speed will decrease gradually.
Correct Answer: (a)
Explanation: According to Newton’s First Law, once the thrusters are turned off, the rocket will continue moving in the direction it was propelled. This is because there are no external forces acting to change its motion, so it maintains its velocity.
Conclusion - Newton's First Law of Motion
Newton's First Law of Motion, or the law of inertia, states that an object will remain at rest or move at a constant speed in a straight line unless acted upon by an unbalanced force. This principle highlights an object's resistance to motion changes, known as inertia, which is proportional to its mass. The law is essential for understanding motion and analyzing physical systems through free body diagrams and constraint equations. It forms the foundation of how we study and control movement in the world.
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Laminar and Turbulent FlowLaminar flow and turbulent flow describe the movement patterns of fluids. Laminar flow is characterized by smooth, orderly layers of fluid sliding over one another without mixing, ideal for scenarios where minimal resistance is desired. Turbulent flow features chaotic, swirling patterns with irregul
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Bernoulli's PrincipleBernoulli's Principle, formulated by Daniel Bernoulli and later expressed as Bernoulli's Equation by Leonhard Euler in 1752, is a fundamental concept in fluid mechanics. It describes the relationship between the pressure (P), velocity, and height (h) of a fluid in motion. The principle states that i
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Poiseuilles Law FormulaAccording to Poiseuille's law, the flow of liquid varies depending on the length of the tube, the radius of the tube, the pressure gradient and the viscosity of the fluid. It is a physical law that calculates the pressure drop in an incompressible Newtonian fluid flowing in laminar flow through a lo
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Stoke's LawStoke's Law: Observe a raindrop falling from a height if you look closely you will notice that the speed of all the raindrops is constant and even though it falls from a height under the influence of gravity its velocity seems constant. These questions are answered using Stoke's lawStoke's law was f
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Solid Mechanics
What is Stress?Stress in physics is defined as the force exerted on the unit area of a substance. Stress affects the body as strain in which the shape of the body changes if the stress is applied and sometimes it gets permanently deformed. On the basis of the direction of force applied to the body, we can categori
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Stress and StrainStress and Strain are the two terms in Physics that describe the forces causing the deformation of objects. Deformation is known as the change of the shape of an object by applications of force. The object experiences it due to external forces; for example, the forces might be like squeezing, squash
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Stress-Strain CurveStress-Strain Curve is a very crucial concept in the study of material science and engineering. It describes the relationship between stress and the strain applied on an object. We know that stress is the applied force on the material, and strain, is the resulting change (deformation or elongation)
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Elasticity and PlasticityYou've undoubtedly heard of the idea of elasticity by now. In layman's words, it indicates that after being stretched, some substances return to their former form. You've experimented with a slingshot. Didn't you? That is an elastic substance. Let us go into the ideas of elasticity and plasticity to
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Modulus of ElasticityModulus of Elasticity or Elastic Modulus is the measurement of resistance offered by a material against the deformation force acting on it. Modulus of Elasticity is also called Young's Modulus. It is given as the ratio of Stress to Strain. The unit of elastic modulus is megapascal or gigapascal Modu
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Modulus of RigidityModulus of rigidity also known as shear modulus, is used to measure the rigidity of a given body. It is the ratio of shear stress to shear strain and is denoted by G or sometimes by S or μ. The modulus of rigidity of a material is directly proportional to its elastic modulus which depends on the mat
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Young's ModulusYoung's Modulus is the ratio of stress and strain. It is named after the famous British physicist Thomas Young. It is also known as the "Modulus of Elasticity" and is a fundamental property that describes the relationship between stress and strain in elastic materials. It explains how a material def
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Bulk Modulus FormulaThe modulus of elasticity measures a material's resistance to elastic deformation under external forces. Understanding this property is important for designing structures with materials like metals, concrete, and polymers to ensure they can withstand stresses without permanent deformation.The modulu
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Shear Modulus and Bulk ModulusA rigid body model is an idealised representation of an item that does not deform when subjected to external forces. It is extremely beneficial for evaluating mechanical systems—and many physical items are quite stiff. The degree to which an item may be regarded as stiff is determined by the physica
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Poisson's RatioPoisson's Ratio is the negative ratio of transversal strain or lateral strain to the longitudinal strain of a material under stress. When a material particularly a rubber-like material undergoes stress the deformation is not limited to only one direction, rather it happens along both transversal and
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Stress, Strain and Elastic Potential EnergyElasticity, this term always reminds of objects like Rubber bands, etc. However, if the question arises, which one is more elastic- A rubber or an Iron piece? The answer will be an Iron piece. Why? The answer lies in the definition of Elasticity, elasticity is known to be the ability of the object t
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Thermodynamics
Basics Concepts of ThermodynamicsThermodynamics is concerned with the ideas of heat and temperature, as well as the exchange of heat and other forms of energy. The branch of science that is known as thermodynamics is related to the study of various kinds of energy and its interconversion. The behaviour of these quantities is govern
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Zeroth Law of ThermodynamicsZeroth Law of Thermodynamics states that when two bodies are in thermal equilibrium with another third body than the two bodies are also in thermal equilibrium with each other. Ralph H. Fowler developed this law in the 1930s, many years after the first, second, and third laws of thermodynamics had a
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First Law of ThermodynamicsFirst Law of Thermodynamics adaptation of the Law of Conservation of Energy differentiates between three types of energy transfer: Heat, Thermodynamic Work, and Energy associated with matter transfer. It also relates each type of energy transfer to a property of a body's Internal Energy. The First L
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Second Law of ThermodynamicsSecond Law of Thermodynamics defines that heat cannot move from a reservoir of lower temperature to a reservoir of higher temperature in a cyclic process. The second law of thermodynamics deals with transferring heat naturally from a hotter body to a colder body. Second Law of Thermodynamics is one
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Thermodynamic CyclesThermodynamic cycles are used to explain how heat engines, which convert heat into work, operate. A thermodynamic cycle is used to accomplish this. The application determines the kind of cycle that is employed in the engine. The thermodynamic cycle consists of a series of interrelated thermodynamic
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Thermodynamic State Variables and Equation of StateThe branch of thermodynamics deals with the process of heat exchange by the gas or the temperature of the system of the gas. This branch also deals with the flow of heat from one part of the system to another part of the system. For systems that are present in the real world, there are some paramete
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Enthalpy: Definition, Formula and ReactionsEnthalpy is the measurement of heat or energy in the thermodynamic system. It is the most fundamental concept in the branch of thermodynamics. It is denoted by the symbol H. In other words, we can say, Enthalpy is the total heat of the system. Let's know more about Enthalpy in detail below.Enthalpy
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State FunctionsState Functions are the functions that are independent of the path of the function i.e. they are concerned about the final state and not how the state is achieved. State Functions are most used in thermodynamics. In this article, we will learn the definition of state function, what are the state fun
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Carnot EngineA Carnot motor is a hypothetical motor that works on the Carnot cycle. Nicolas Leonard Sadi Carnot fostered the fundamental model for this motor in 1824. In this unmistakable article, you will find out about the Carnot cycle and Carnot Theorem exhaustively. The Carnot motor is a hypothetical thermod
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Heat Engine - Definition, Working, PV Diagram, Efficiency, TypesHeat engines are devices that turn heat energy into motion or mechanical work. Heat engines are based on the principles of thermodynamics, specifically the conversion of heat into work according to the first and second laws of thermodynamics. They are found everywhere, from our cars, power plants to
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Wave and Oscillation
Introduction to Waves - Definition, Types, PropertiesA wave is a propagating dynamic disturbance (change from equilibrium) of one or more quantities in physics, mathematics, and related subjects, commonly described by a wave equation. At least two field quantities in the wave medium are involved in physical waves. Periodic waves occur when variables o
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Wave MotionWave Motion refers to the transfer of energy and momentum from one point to another in a medium without actually transporting matter between the two points. Wave motion is a kind of disturbance from place to place. Wave can travel in solid medium, liquid medium, gas medium, and in a vacuum. Sound wa
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OscillationOscillations are defined as the process of repeating vibrations of any quantity about its equilibrium position. The word “oscillation†originates from the Latin verb, which means to swing. An object oscillates whenever a force pushes or pulls it back toward its central point after displacement. This
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Oscillatory Motion FormulaOscillatory Motion is a form of motion in which an item travels over a spot repeatedly. The optimum situation can be attained in a total vacuum since there will be no air to halt the item in oscillatory motion friction. Let's look at a pendulum as shown below. The vibrating of strings and the moveme
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Amplitude FormulaThe largest deviation of a variable from its mean value is referred to as amplitude. It is the largest displacement from a particle's mean location in to and fro motion around a mean position. Periodic pressure variations, periodic current or voltage variations, periodic variations in electric or ma
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What is Frequency?Frequency is the rate at which the repetitive event that occurs over a specific period. Frequency shows the oscillations of waves, operation of electrical circuits and the recognition of sound. The frequency is the basic concept for different fields from physics and engineering to music and many mor
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Amplitude, Time Period and Frequency of a VibrationSound is a form of energy generated by vibrating bodies. Its spread necessitates the use of a medium. As a result, sound cannot travel in a vacuum because there is no material to transfer sound waves. Sound vibration is the back and forth motion of an entity that causes the sound to be made. That is
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Energy of a Wave FormulaWave energy, often referred to as the energy carried by waves, encompasses both the kinetic energy of their motion and the potential energy stored within their amplitude or frequency. This energy is not only essential for natural processes like ocean currents and seismic waves but also holds signifi
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Simple Harmonic MotionSimple Harmonic Motion is a fundament concept in the study of motion, especially oscillatory motion; which helps us understand many physical phenomena around like how strings produce pleasing sounds in a musical instrument such as the sitar, guitar, violin, etc., and also, how vibrations in the memb
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Displacement in Simple Harmonic MotionThe Oscillatory Motion has a big part to play in the world of Physics. Oscillatory motions are said to be harmonic if the displacement of the oscillatory body can be expressed as a function of sine or cosine of an angle depending upon time. In Harmonic Oscillations, the limits of oscillations on eit
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Sound
Production and Propagation of SoundHave you ever wonder how are we able to hear different sounds produced around us. How are these sounds produced? Or how a single instrument can produce a wide variety of sounds? Also, why do astronauts communicate in sign languages in outer space? A sound is a form of energy that helps in hearing to
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What are the Characteristics of Sound Waves?Sound is nothing but the vibrations (a form of energy) that propagates in the form of waves through a certain medium. Different types of medium affect the properties of the wave differently. Does this mean that Sound will not travel if the medium does not exist? Correct. It will not, It is impossibl
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Speed of SoundSpeed of Sound as the name suggests is the speed of the sound in any medium. We know that sound is a form of energy that is caused due to the vibration of the particles and sound travels in the form of waves. A wave is a vibratory disturbance that transfers energy from one point to another point wit
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Reflection of SoundReflection of Sound is the phenomenon of striking of sound with a barrier and bouncing back in the same medium. It is the most common phenomenon observed by us in our daily life. Let's take an example, suppose we are sitting in an empty hall and talking to a person we hear an echo sound which is cre
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Refraction of SoundA sound is a vibration that travels as a mechanical wave across a medium. It can spread via a solid, a liquid, or a gas as the medium. In solids, sound travels the quickest, comparatively more slowly in liquids, and the slowest in gases. A sound wave is a pattern of disturbance caused by energy trav
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How do we hear?Sound is produced from a vibrating object or the organ in the form of vibrations which is called propagation of sound and these vibrations have to be recognized by the brain to interpret the meaning which is possible only in the presence of a multi-functioning organ that is the ear which plays a hug
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Audible and Inaudible SoundsWe hear sound whenever we talk, listen to some music, or play any musical instrument, etc. But did you ever wondered what is that sound and how is it produced? Or why do we hear to our own voice when we shout in a big empty room loudly? What are the ranges of sound that we can hear? In this article,
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Explain the Working and Application of SONARSound energy is the type of energy that allows our ears to sense something. When a body vibrates or moves in a ‘to-and-fro' motion, a sound is made. Sound needs a medium to flow through in order to propagate. This medium could be in the form of a gas, a liquid, or a solid. Sound propagates through a
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Noise PollutionNoise pollution is the pollution caused by sound which results in various problems for Humans. A sound is a form of energy that enables us to hear. We hear the sound from the frequency range of 20 to 20000 Hertz (20kHz). Humans have a fixed range for which comfortably hear a sound if we are exposed
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Doppler Effect - Definition, Formula, ExamplesDoppler Effect is an important phenomenon when it comes to waves. This phenomenon has applications in a lot of fields of science. From nature's physical process to planetary motion, this effect comes into play wherever there are waves and the objects are traveling with respect to the wave. In the re
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Doppler Shift FormulaWhen it comes to sound propagation, the Doppler Shift is the shift in pitch of a source as it travels. The frequency seems to grow as the source approaches the listener and decreases as the origin fades away from the ear. When the source is going toward the listener, its velocity is positive; when i
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Electrostatics
ElectrostaticsElectrostatics is the study of electric charges that are fixed. It includes an study of the forces that exist between charges as defined by Coulomb's Law. The following concepts are involved in electrostatics: Electric charge, electric field, and electrostatic force.Electrostatic forces are non cont
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Electric ChargeElectric Charge is the basic property of a matter that causes the matter to experience a force when placed in a electromagnetic field. It is the amount of electric energy that is used for various purposes. Electric charges are categorized into two types, that are, Positive ChargeNegative ChargePosit
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Coulomb's LawCoulomb’s Law is defined as a mathematical concept that defines the electric force between charged objects. Columb's Law states that the force between any two charged particles is directly proportional to the product of the charge but is inversely proportional to the square of the distance between t
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Electric DipoleAn electric dipole is defined as a pair of equal and opposite electric charges that are separated, by a small distance. An example of an electric dipole includes two atoms separated by small distances. The magnitude of the electric dipole is obtained by taking the product of either of the charge and
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Dipole MomentTwo small charges (equal and opposite in nature) when placed at small distances behave as a system and are called as Electric Dipole. Now, electric dipole movement is defined as the product of either charge with the distance between them. Electric dipole movement is helpful in determining the symmet
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Electrostatic PotentialElectrostatic potential refers to the amount of electrical potential energy present at a specific point in space due to the presence of electric charges. It represents how much work would be done to move a unit of positive charge from infinity to that point without causing any acceleration. The unit
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Electric Potential EnergyElectrical potential energy is the cumulative effect of the position and configuration of a charged object and its neighboring charges. The electric potential energy of a charged object governs its motion in the local electric field.Sometimes electrical potential energy is confused with electric pot
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Potential due to an Electric DipoleThe potential due to an electric dipole at a point in space is the electric potential energy per unit charge that a test charge would experience at that point due to the dipole. An electric potential is the amount of work needed to move a unit of positive charge from a reference point to a specific
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Equipotential SurfacesWhen an external force acts to do work, moving a body from a point to another against a force like spring force or gravitational force, that work gets collected or stores as the potential energy of the body. When the external force is excluded, the body moves, gaining the kinetic energy and losing a
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Capacitor and CapacitanceCapacitor and Capacitance are related to each other as capacitance is nothing but the ability to store the charge of the capacitor. Capacitors are essential components in electronic circuits that store electrical energy in the form of an electric charge. They are widely used in various applications,
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