NCERT Solution Class 9th Science Chapter – 9 Gravitation
Textbook | NCERT |
Class | 9th |
Subject | Science |
Chapter | 9th |
Chapter Name | Gravitation |
Category | Class 9th Science |
Medium | English |
Source | Last Doubt |
NCERT Solution Class 9th Science Chapter – 9 Gravitation Notes In this Chapter We Will read about Gravitation, Newton’s Universal law of gravitation, Buoyant force ‘f’, Acceleration due to gravity, Gravitational Force of Earth, According to this law, Importance of universal law of gravitation, Gravitational Constant, Thrust and Pressure and More much. you have provided easy notes which use in your study make progress in education. |
NCERT Solution Class 9th Science Chapter – 9 Gravitation
Chapter – 9
Gravitation
Notes
Gravitation
Newton’s Universal law of gravitation Buoyant force ‘f’ Acceleration due to gravity (g)2 |
Newton’s Universal law of gravitation
Force (F)= GM1M₂ / R2 G = Gravitational Constant M₁ = Mass of object 1 M2 = Mass of object 2 R = distance between object W = m x g Weight = Mass Acceleration due to gravity |
Buoyant force ‘f’
Thrust→ Pressure P = F/A P = Pressure F = Force A = Area |
Acceleration due to gravity (g)2
g = GM/R2 R = Radius of Earth M = Mass of Earth G = Gravitational constant Value of G = 6.67 x 10-11Nm2/kg2 |
Gravitational Force of Earth
If we release a small stone without pushing it from a height, it accelerates towards earth. The stone is when accelerated towards earth, means some force is acting on it. The force which pulls the objects towards the centre of the earth is known as gravitational force of the earth. Here, stone also attracts earth. It means every object in universe attracts every other object. |
Newton’s Universal Law of Gravitation
Sir Isaac Newton in 1687 proposed a law about the force of attraction between the two objects in the universe which is known as Newton’s law of gravitation. According to this law Every mass in this universe attracts every other mass with a force which is directly proportional to the product of two masses and inversely proportional to the square of the distance between them. Let masses (m1) and (m2) of two objects are distance (d) apart, then force of attraction (F) between them F ∞ m₁ x m₂ F ∞ 1/d2 F ∞ m₁ x m₂ / d2 F = Gm₁ x m₂ / d2 Where G is a constant and is known as Gravitational constant. Value of G = 6.67 x 10-11 Nm²/kg2 G is called universal gravitational constant. If unit of F is in Newton, m is in kg, dis in metre, then unit of G can be calculated as: G = F x d2 / m1 x m2 so unit be Nm2/kg2 or Nm2/kg2 |
Relation between Newton’s third law of motion and Newton’s law of gravitation According to Newton’s third law of motion, “Every object exerts equal and opposite force on other object but in opposite direction.” According to Newton’s law of gravitation, “Every mass in the universe attracts the every other mass.” In case of freely falling stone and earth, stone is attracted towards earth means earth attracts the stone but according to Newton’s third law of motion, the stone should also attract the earth and really it is true that stone also attracts the earth with the same force F = m x a but due to very less mass of the stone, the acceleration (a) in its velocity is 9.8 m/s² and acceleration (b) of earth towards stone is 1.65 × 10-24 m/s2 which is negligible and we cannot feel it. |
Importance of universal law of gravitation
(i) The force that binds us to the earth. (ii) The motion of moon around the earth. (iii) The motion of earth around the sun. (iv) The tides due to moon in the sea. |
Free fall of an object and acceleration during free fall
When an object is thrown upward, it reaches certain height, then it starts falling down towards earth. It is because the earth’s gravitational is exerted exerts on it. This fall under the influence of earth is called ‘free fall of an object’. During this free fall direction do not change but velocity continuously changes which is called acceleration due to gravity. It is denoted by ‘g’. Its unit is same as acceleration i.e. m/s². |
Gravitational Acceleration and its value at the surface of earth
The uniform acceleration produced in a freely falling object due to the gravitational force of earth, is called acceleration due to gravity. It is represented by ‘g’ and it always acts towards the centre of the earth. Value of ‘g’ on the surface of earth The force acting on an object is F = GMem / R2 Where M = Mass of earth m = Mass of an object R = Radius of earth and if acceleration due to gravity is ‘g’ due to force F then, F = m x g Equating (i) and (ii), we get m x g = GMe m / R2 Or g = GM / R2 If G = 6.673 × 10-11 Nm2/kg2, Me = 6 x 1024 kg, R2 = (6.37 × 106)2 m² Then, g = 6.6734 × 10-11 x 6 x 1024 / (6.37×106)2 g = 9.8 m/s² |
Relationship and difference between ‘G’ and ‘g’
G = Gravitational constant g = Acceleration due to gravity g = GM / R2 |
Difference between G (Gravitational constant) and g (Acceleration due to gravity)
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Example
If two stones of 150 gm and 500 gm are dropped from a height, whichstone will reach the surface of earth first and why? Explain your answer. (Imp.) Ans. It was Galileo, who first time demonstrated and depicted that the acceleration of an object falling freely towards earth does not depend on the mass of the object. It can be verified by universal law of gravitation. Let an object of mass m, is allowed to fall from a distance of R, from the centre of the earth. Then, the gravitational force, F = GMem / R2 (M = Mass of the earth) The force acting on the stone is F = m x a So, m x a = GMem / R2 Or a = GMe / R2 So, acceleration in an object falling freely towards earth depends on the mass of earth and height of the object from the centre of the earth. So stones of mass 150 gm and 500 gm will reach the earth surface together. |
Equation of motion when an object is falling freely towards earth or thrown vertically upwards: Case 1. When an object is falling towards earth with initial velocity (u), then Velocity (v) after t seconds, v = u + gt Height covered in t seconds, h = ut +½gt² Relation between v and u when t is not mentioned: V2 = u2 + 2gh Case 2. When object is falling from rest position means initial velocity u = 0 (zero), then Velocity (v) after t seconds, v = gt Height covered in t seconds, h = ½gt² Relation between v and u when t is not mentioned: V2 = 2gh Case 3. When an object is thrown vertically upwards with initial velocity u, the gravitational acceleration will be negative (- g), then Velocity (v) after t seconds, v=u-gt Height covered in t seconds, h = ut – ½gt Relation between v and u when t is not mentioned: V2 = u2 – 2gh |
Mass
The mass of a body is the quantity of matter contained in it. Mass is a scalar quantity which has only magnitude but no direction. SI unit of mass is kilogram which is written in short form as kg. • Mass of a body is constant and does not change from place to place. • Mass of a body is usually denoted by the small ‘m’. • Mass of a body cannot be zero. |
Weight
The force with which an object is attracted towards the centre of the earth, is called the weight of the object. Force = m × a In case of earth, a = g So, F = m × g But the force of attraction of earth on an object is called its weight (W). So, W = m x g So, weight is the force and its SI unit is Newton (N). It depends on ‘g’ and is a vector quantity. |
Relation between 1 kg wt and express it into Newton
We know that W = m x g If mass (m) = 1 kg, g = 9.8 m/s², then W = 1 kg x 9.8 m/s² Or 1 kg wt = 9.8N So, the gravitational force of earth that acts on an object of mass 1 kg is called as 1 kg wt. |
Distinguish between Mass and Weight
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Thrust and Pressure
Thrust – The force acting on an object prependicular to the surface is called thrust. Pressure – The effect of thrust per unit area is called pressure. Pressure (P) = Force (F)/Area (A) = Newton/meter = N/m² SI unit is N/m² or Nm⁻². SI unit of pressure is Pascal (Pa). |
Factors on which pressure depends
Pressure depends on two factors: (i) Force applied (ii) Area of surface over which force acts Examples: The base of high buildings is made wider so that weight of walls act over a large surface area and pressure is less. School bags are having broad strap so that the weight of school bags fall over a larger area of the shoulder and produce less pressure and becomes less painful. The blades of knives are made sharp so very small surface area and on applying force, it produces large pressure and cuts the object easily. All liquids and gases are fluids and they exert pressure in all directions. |
Buoyancy
The upward force experienced by an object when it is immersed into a fluid is called force of buoyancy. It acts in upward direction and it depends on the density of the fluid volume of object immersed in liquid. • Force of gravitational attraction of the earth on the surface of the object ≤ buoyant force exerted by fluid on the surface of the object. Result – The object floats. • Force of gravitational attraction of the earth on the surface of the object > buoyant force exerted by fluid on the surface of the object. Result – The object sinks. • That is why, allpin sinks and boat/ship floats on the surface of water. (Archimedes’ principle) |
Density
• The mass per unit volume is called density of an object. If M is the mass and V is the volume, then density (d) is • Density (d) = Mass (M)/Volume (V) • SI unit = kg/m³ |
Archimedes’ Principle
It states, when a body is immersed fully or partially in a fluid, it experiences a upward force that is equal to the weight of the fluid displaced by it. |
Applications of Archimedes’ Principle
• It is used in determining relative density of substances. • It is used in designing ships and submarines. • Hydrometers and lactometers are made on this principle. • It is because of this ship made of iron and steel floats in water whereas a small piece of iron sinks in it. |
Relative density
• The ratio of the density of a substance to that of the density of water is called relative density. • Relative density = Density of a substance/Density of water. • It has no unit. |
Solved Numericals
Example 1. Relative density of gold is 19.3. The density of water is 103 kg/m³. What is the density of gold in kg/m³ ? Solution: Given, Relative density of gold = 19.3 Density of water = 103 kg/m³ So, Density of gold = Relative density of gold × Density of water = 19.3 × 103 Hence, density of gold = 19.3 × 103 kg/m³. |
Example 2. Mass of 0.025 m³ of aluminium is 67 kg. Calculate the density of aluminium. Solution: Given, Mass of aluminium = 67 kg Volume of aluminium = 0.025 m³ So, Density = M/V = 67 / 0.025 = 2680 kg/m³ |
Example 3. The mass of brick is 2.5 kg and its dimensions are 20 cm x 10 cm x 5 cm. Find the pressure exerted on the ground when it is placed on the ground with different faces. Solution: Given, Mass of the brick = 2.5 kg Dimensions of the brick = 20 cm x 10 cm x 5 cm So, Weight of the brick (Thrust/Force) = F = mg = 2.5 x 9.8 = 24.5 N (i) When the surface area 10 cm x 5 cm is in contact with the ground, then Area 10 x 550 cm² = 50 / 10000 = 0.005 m² So, P = F/A = 24.5 / 0.0050 = 4900 N/m² (ii) When the surface area 20 cm x 5 cm is in contact with the ground, then Area = 20 x 5 = 100 cm² = 100 / 1000 = 0.01 m² So, P = F/A = 24.5 / 0.01 = 2450 N/m² (iii) When the surface area 20 cm x 10 cm is in contact with the ground, then Area = 20 x 10 = 200 cm² = 200 / 10000 = 0.02 m² So, P = F/A = 24.5 / 0.02 = 1225 N/m² |
Example 4. A force of 20N acts upon a body whose weight is 9.8N. What is the mass of the body and how much is its acceleration ? Solution: Given, Force = 20N, Weight W = 9.8N We know, W = mg So, 9.8 = m x 9.8 Or m = 1 kg And, F = ma So, 20 = 1 x a Or a = 20 m/s² |
Example 5. A man weighs 1200N on the earth. What is his mass (take g = 10 m/s2)? If he was taken to the moon, his weight would be 200N. What is his mass on moon? What is his acceleration due to gravity on moon? Solution: Given, Weight of man on earth W₁ = 1200 N Weight of man on moon W₂ = 200 N Gravitational acceleration of earth = 10 m/s² Now, W = mg Or m = W/g = 120 kg So, mass on moon will be 120 kg as it is constant everywhere so mass of man on moon = 120 kg. Now, W₂=mg2 Or 200 = 120 × g Or g = 200/120 = 10/6 = 5/3 = 1.66 m/s² |
Example 6. An object is thrown vertically upwards and reaches a height of 78.4 m. Calculate the velocity at which the object was thrown? (g = 9.8 m/s²) Solution: Given, h =78.4 m, v = 0, g = 9.8 m/s², u = ? v2 = u² – 2gh Or 0 = u2 – 2 × 9.8 x 78.4 Or u2 = 2×49×784 / 10×10 Or u = √2 x 2 × 49 × 78 / 10×10 u = 2 x 7 / 10 √784 Or u = = 39.2 m/s² |
Example 7. What is the mass of an object whose weight is 49 Newton ? Solution: Given, Weight of object W = 49N g = 9.8 m/s² Now, W = mg Or m = w/g = 49/9.8 = 5 kg |
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