I PUC Physics QB 2024-25 PDF

REVISED QUESTION BANK 2024 –25 I PUC PHYSICS (33) DEPARTMENT OF SCHOOL EDUCATION (PRE–UNIVERSITY) 18th CROSS, MALLESHWARAM, BANGALORE COORDINATOR: B. MAHESH PRINCIPAL, GOVT. PU COLLEGE, MYLANAYAKANAHOSAHALLI, CHANNAPATNA TQ, RAMANAGARA DIST COMMITTEE MEMBERS 1. ADITHYA RAO. K. V. LECTURER IN PHYSICS, GPU COLLEGE, SRINGERI CHIKMAGALUR DIST. 2. DEVARAJ TALAKALLU, LECTURER IN PHYSICS, GOVT. SCIENCE PU COLLEGE, AT POST DASTIKOPPA, KALAGHATAGI TALUK, DHARWAD DIST. 3. MAHESH, LECTURER IN PHYSICS, GOVT. PU COLLEGE FOR GIRLS, RAMANAGARA, RAMANAGARA DIST. 4. PRASANNA K. V., LECTURER IN PHYSICS, GOVT. PU COLLEGE, KOPPA, CHIKMAGALUR DIST. 5. PRAKASH, LECTURER IN PHYSICS, GOVT. PU COLLEGE FOR GIRLS, CHENNAPATNA, RAMANAGARA DIST. 6. CHETHANA, LECTURER IN PHYSICS, GOVT. PU COLLEGE FOR BOYS, CHANNAPATNA, RAMANAGARA DIST. 1. UNITS AND MEASUREMENT MULTIPLE CHOICE QUESTIONS: 1. The units that are used for fundamental physical quantities are called (A) System of units (B) fundamental units (C) Derived units (D) All of these 2. Which of the following physical quantity has same unit in CGS, FPS, MKS and SI systems of unit? (A) Mass (B) Length (C) Time (D) Energy 3. Which of the following physical quantity is not a fundamental quantity? (A) Length (B) temperature (C) electric current (D) energy 4. The SI unit of electric current is (A) watt (B) joule (C) volt (D) ampere 5. The SI unit of solid angle is (A) Radian (B) degree (C) steradian (D) radian/metre 6. pascal is the unit of (A) force (B) pressure (C) force (D) energy 7. The SI unit of frequency is (A) metre/second (B) radian/second (C) newton-metre (D) hertz 8. Which of the following statement is incorrect regarding significant figures? (A) All non-zero digits are significant. (B) All the zeros between two non-zero digits are significant. (C) The trailing zero(s) in a number with a decimal point are significant. (D) The power of 10 is counted while counting the number of significant figures. 9. The number of significant figures in 30600 (A) 3 (B) 2 (C) 5 (D) 4 10. The number of significant figures in 0.03400 (A) 2 (B) 3 (C) 4 (D) 5 11. Which of the following pairs of physical quantities have same dimensions? (A) Force and power (B) force and torque (C) Torque and work (D) torque and power 12. The dimensional formula of frequency (A) [M0L0T–1] (B) [M0L1T–2] (C) [M1L1T–2] (D) [M0L1T0] 13. The dimensional formula of gravitational constant (A) [M–1L3T–2] (B) [M1L3T–2] (C) [M2L3T–1] (D) [M2L–2T0] 14. Which of the following physical quantity has a unit but no dimensions? (A) Strain (B) relative density (C) plane angle (D) stress 15. Which of the following constant is a dimensionless constant? (A) G (B) π (C) c (D) h 16. The physical quantity having the dimensions [M1L–1T–2] is (A) Angular momentum(B) energy (C) pressure (D) force 17. Statement i: When we change the unit of measurement of a quantity, its numerical value changes. Statement ii: Smaller the unit of measurement smaller is its numerical value. (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. 18. Statement i: The units of a derives are expressed as combination of the basic units Statement ii: There are only seven basic quantities (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. 19. Statement i: The number of significant figures in 3050 is three and the number 0.02300 has four significant figures. Statement ii: All non-zero digits are significant. (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement I is true but statement ii is false. (D) Both the statements are false. 20. If force F, acceleration A and time T are basic physical quantities, the dimensions of energy are (A) [F2A–1T1] (B) [F1A1T2] (C) [F1A1T–2] (D) [F1A–1T1] FILL IN THE BLANKS (strain, plane angle, temperature, frequency, significant) 1. ________ is a basic physical quantity. 2. In a number, the zeros between two non-zero digits are _________ 3. ___________ is a supplementary quantity. 4. The physical quantity that has neither a unit nor a dimesion is ___________ 5. The physical quantity having the dimension [M0L0T–1] is ___________ TWO MARK QUESTIONS 1. What are basic units? Give one example. 2. Write the SI unit and dimensional formula for moment of inertia. 3. State the principle of homogeneity of dimensions. 4. Give any two limitations of dimensional method. THREE MARK QUESTIONS 1. Check the dimensional correctness of the equation x = v0t + ½ at2 where the symbols having their usual meaning. 2. Check the dimensional correctness of the equation T = 2π where L is the length of a simple pendulum, T is its time period and g is the acceleration due to gravity. 3. Derive the expression for period of a simple pendulum which depends on its length (l) and acceleration due to gravity (g) using dimensional analysis. ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 B C D D C B D D A C 11 12 13 14 15 16 17 18 19 20 C A A C B C C A B B ANSWERS TO FIBS: 1. temperatutre; 2. singnificant 3. plane angle 4. strain 5. frequency ************************************************************************* 2. MOTION IN A STRAIGHT LINE MULTIPLE CHOICE QUESTIONS: 1. If the distance covered by a particle is zero, then it’s displacement (A) may or may not be zero (B) cannot be zero (C) must be zero (D) negative 2. The numerical ratio of distance travelled to displacement is (A) always equal to one (B) always less than one (C) always more than one (D) greater than equal to one 3. The area under velocity-time graph represents (A) displacement (B) uniform acceleration (C) average speed (D) average velocity 4. The slope of the tangent drawn to position-time graph at any instant gives (A) Instantaneous velocity (B) instantaneous acceleration (C) Average velocity (D) average speed 5. Stopping distance of a vehicle moving with uniform acceleration is directly proportional to (A) Acceleration (B) square of the acceleration (C) initial velocity (D) square of initial velocity 6. The slope of velocity time graph gives (A) average velocity (B) acceleration (C) average speed (D) distance travelled 7. When a body thrown vertically upward, it will take t time to reach its highest point. Then the time taken to return to ground is (A) 2t (B) t2 (C) t (D) √ 8. A body thrown from the top of a tower in horizontal direction and at the same time another body dropped from the same point. The two bodies will reach the earth (A) Simultaneously (B) dropped body reached first (C) depending on their masses (D) horizontally thrown body reach first 9. A body cannot have (A) A constant speed and varying velocity (B) an acceleration and a constant speed (C) A uniform velocity and varying speed (D) non zero speed and zero acceleration. 10. A body is released from the certain height. After falling for some time, suppose the acceleration due to gravity vanishes. Then (A) Body continues to move with uniform acceleration. (B) Body continues to move with uniform retardation. (C) Body continues to move with uniform variable velocity (D) Body continues to move with uniform/constant velocity. 11. A vehicle travels half the distance L with speed v1 and the other half with speed v2, then its average speed is ( ) (A) (B) (C) (D) 12. The distance-time graph for a particle in motion as shown in figure. The maximum instantaneous velocity of the particle is around the point. (A) A (B) C (C) B (D) D 13. Statement i: The displacement of a body may be zero, when distance travelled by it is not zero. Statement ii: The displacement is the longer distance between initial and final position (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. 14. Statement i: The average speed of an object is greater than or equal to the average velocity over a given time interval. Statement ii: The two are equal only if the path length is equal to the magnitude of displacement. (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. 15. Statement i: A particle may be momentarily at rest and yet have non-zero acceleration. Statement ii: The zero velocity of a particle at any instant does not necessarily imply zero acceleration at that instant. (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. 16. Statement i: An object may fall with a constant velocity. Statement ii: This happens when acceleration of the object is equal to acceleration due to gravity. (A) Both the statements are true and statement ii is the correct explanation of statement i. (B) Both the statements are true but statement ii is not correct explanation of statement i (C) Statement i is true but statement ii is false. (D) Both the statements are false. FILL IN THE BLANKS: (velocity, uniform acceleration, displacement, scalar, downwards) 1. The shortest distance between initial and final position of a body in motion is called __________ 2. Speed is a _________ quantity. 3. If body has equal changes in velocity in equal intervals of time, the body is said to be in _______ 4. The slope of position-time graph of a body in uniform motion gives _____________ 5. A body moving under earth’s gravitational field, the direction of acceleration is always ___________ TWO MARK QUESTIONS: 1. Write any two differences between instantaneous speed and instantaneous velocity. 2. Draw a position-time graph for a body moving with constant speed. 3. Draw a position-time graph for a body moving in positive direction with negative acceleration. 4. Define average velocity and uniform velocity. 5. A body moving with an initial velocity 5m/s and uniform acceleration 1 m/s2. Determine its velocity after 20 s. [25 m/s] THREE MARK QUESTIONS: 1. Derive the expression v = v0 + at using velocity-time graph. 2. Derive the expression v2 = + 2ax using v – t graph. 3. Mention three applications of velocity-time graph. 4. A car moving along a straight road with a speed of 126 km/h is brought to a stop within a distance of 200 m. What is the retardation of the car? (3.06 ms–2) 5. A stone thrown vertically upward with velocity of 20 m/s. Calculate the maximum height reached by it. (g = 10 ms–2). (20 m) FIVE MARK QUESTIONS: 1. Derive the expression x = v0t + at2 using velocity-time graph. 2. A body covers the first one-third distance at a constant speed of 20ms–1, next one-third distance with a speed of 40 ms–1 and last one-third distance at 60 ms–1. Calculate the average velocity of the body over the complete journey. (32.72 ms–1) –1 3. A player throws a ball vertically upwards with a speed of 29.4 ms. Calculate (i) maximum height attained by the ball (ii) time taken by the ball to reach the highest point. (h = 44.1m, t = 3s) 4. A body let fall from the top of a tower covers 45 m in the last second of its fall. Find the height of the tower. (g = 10 ms–2). (125 m) –1 5. A body projected vertically upwards with a velocity of 15 ms from the top of a tower reaches ground in 5s. Find the height of the tower. (g = 9.8 ms–2). (47.52m) 6. A ball A thrown vertically upwards reaches the balcony of a house 100m high. At the same time another ball B is dropped from rest from the balcony of the house. When and where will the two balls pass each other. (g = 10 ms–2). (t = √ s, at a height x = 75m above the ground) 7. From the velocity time graph given below, calculate the distance travelled during the time interval 2s to 6 s. v 12 5 10 t (36m) ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 C D A A D B C A 9 10 11 12 13 14 15 16 C D C B C A A C ANSWERS TO FIBS: 1. displacement; 2. scalar; 3. uniform acceleration; 4. velocity; 5. downwards ************************************************************************* 3. MOTION IN A PLANE MULTIPLE CHOICE QUESTIONS: 1. The physical quantity that has both magnitude and direction is called (A) Scalar (B) vector (C) dimensional (D) phasor 2. Which of the following is not a vector quantity? (A) work (B) impulse (C) displacement (D) momentum 3. Two vectors are said to be equal if they have (A) Only same magnitude (B) same magnitude and perpendicular (C) Only in same direction (D) same magnitude and same direction 4. If a vector is multiplied by a positive scalar, the resulting quantity is (A) A scalar having same magnitude as initial vector. (B) A vector having same direction as initial vector. (C) A vector having different direction of initial vector. (D) A scalar having magnitude different from that of initial vector. 5. Which of the following statement is incorrect? (A) In one dimensional motion, the velocity and acceleration of an object are always along the same line (B) In two or three dimensional motion the angle between velocity and acceleration vectors may have any value between 0⁰ and 180⁰. (C) The maximum height attained by a projectile is always equal to its horizontal rage. (D) The resultant acceleration of an object in circular motion is towards the centre only if the speed is constant. 6. It is found that ⃗ + ⃗= ⃗. This necessarily implies (A) ⃗ = 0 (B) ⃗ ⃗ are opposite to each other (C) ⃗ ⃗ are perpendicular to each other (D) ⃗. ⃗ ≤ 0 7. The motion in a plane can be treated as superposition of two separate simultaneous one dimensional motion along two ________ directions. (A) Same (B) perpendicular (C) opposite (D) any 8. The resultant of two vectors acting at a point is minimum if they are (A) in same direction (B) perpendicular to each other (C) making an angle 120⁰ with each other (D) opposite to each other 9. In a projectile motion, the maximum range is always equal to (A) maximum height (B) twice of the maximum height (C) thrice of the maximum height (D) four times the maximum height. 10. At maximum height, the velocity and accelerations of the projectile are (A) In same direction (B) perpendicular to each other (C) Opposite to each other (D) both are zero 11. For maximum range for a projectile, the angle of projection should be (A) 45⁰ (B) 30⁰ (C) 60⁰ (D) 90⁰ 12. For maximum height of a projectile, the angle of projection should be (A) 45⁰ (B) 30⁰ (C) 60⁰ (D) 90⁰ 13. The trajectory of a projectile motion is a (A) parabola (B) straight line (C) circle (D) hyperbola 14. If a body is projected with an angle θ to the horizontal, then (A) Its velocity is always perpendicular to its acceleration. (B) Its velocity becomes zero at its maximum height. (C) Its velocity is in horizontal direction at maximum height (D) When the just hitting the ground, its velocity and acceleration are in same direction. 15. The centripetal acceleration is (A) Directly proportional to its velocity and radius of the circular path. (B) Directly proportional to its velocity and inversely radius of the circular path. (C) Directly proportional to its square of its velocity and inversely proportional to square of the radius of the circle. (D) Directly proportional to its square of its velocity and inversely proportional to the radius of the circular path. 16. Statement i: Vectors addition is commutative. Statement ii: Two vectors may be added graphically using triangle law of vector addition. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Both the statements are false. 17. Statement i: The difference of two vectors can be treated as sum of two vectors. Statement ii: Subtraction of vectors can be defined in terms of addition of vectors. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Both the statements are false. 18. Statement i: For the motion in two or three dimensions, velocity and acceleration vectors must have any angle from 0⁰ to 90⁰ between them. Statement ii: For such motion velocity and acceleration of an object is always in the opposite direction. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Both the statements are false. 19. Statement i: The trajectory of a projectile motion under the acceleration due to gravity can be a straight line. Statement ii: The shape of the trajectory of the motion of an objects determined by the Acceleration alone. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Both the statements are false. 20. Statement i: Centripetal acceleration is always directed towards the centre of the circular path. Statement ii: Centripetal acceleration is a constant vector. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Both the statements are false. 21. Statement i: In projectile motion, the angle between the instantaneous velocity and acceleration at the highest point is 180°. Statement ii: At the highest point, velocity of projectile will be in horizontal direction only. (A) Both the statements are true and statement ii is the correct explanation for statement i. (B) Both the statements are true but statement two is not correct explanation for statement i. (C) Statement i is true but statement ii is false. (D) Statement i is false and statement ii is correct. FILL IN THE BLANKS: (resolution, unit, speed, null, horizontal, same direction) 1. A vector with zero magnitude is called________ vector. 2. The splitting up of a vector into two or more components are called _______ of vector. 3. The resultant of two vectors is maximum if they are acting in __________ 4. _________ velocity remains constant throughout the motion of a projectile. 5. In uniform circular motion, the body moves in a circle with constant ___________ TWO MARK QUESTIONS: 1. Define scalar product of two vectors. Give an example for scalar product of vector. 2. Write the expression for resultant of two concurrent vectors A and B and explain the terms. 3. Write the expression for time of flight of a projectile motion and explain the terms. 4. Write the expression for range of a projectile and explain the terms. 5. Write the expression for centripetal acceleration and explain the terms. THREE MARK QUESTIONS: 1. Explain the triangle method of vector addition. 2. If ⃗ = 3 ̂ + 2 ̂ and ⃗ = ̂ – 2 ̂ + 3 , find the magnitude of ⃗ + ⃗. 3. Two forces of 4 N and 3 N act at a point making an angle of 60⁰ with one another. Find the magnitude of resultant of the two forces. 4. Obtain the expression for time of flight of a projectile motion. 5. Obtain the expression for maximum height of a projectile motion. 6. A projectile is projected at an angle of 30⁰ to the horizontal with an initial speed of 20 ms–1. Calculate its time of flight. 7. Obtain the expression for horizontal range of a projectile motion. 8. A stone of mass 2 kg is tied with a string of length 1.5 m is rotating in a circle with a constant speed of 10 ms–1. Calculate its centripetal acceleration. FIVE MARK QUESTIONS: 1. Derive the expression for magnitude and direction of resultant of two concurrent vectors. 2. Obtain the equation of path of a projectile. OR Show that the trajectory of a projectile is a parabola. 3. What is centripetal acceleration? Derive the expression for centripetal acceleration. 4. The resultant of two forces acting at an angle of 120⁰ is at right angle to the smaller force. If the greater force is 8 N, find the smaller force and the resultant. (F = 4 N, R = 6.93 N) 5. A football player kicks a ball at an angle of 30⁰ to the horizontal with an initial speed of 20 ms–1. Calculate (A) maximum height and (B) horizontal range reached by the ball. (H = 5 m, R = 34.64 m). 6. The ceiling of a long hall is 25m high. What is the maximum horizontal distance that a ball thrown with a speed of 40ms–1 can go without hitting the ceiling of the hall? (150.5m) 7. A foot ball player kicks a ball so that it just clears a 4 m high wall at a distance of 5 m. It falls at a distance of 11 m from the wall. Determine the initial speed and the angle of projection of the ball. (v0 = 12.59 ms–1, θ = 49.3⁰) ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 11 B A D C C A B B D B A 12 13 14 15 16 17 18 19 20 21 D A C D B A D C B D ANSWERS TO FIBS: 1. null; 2. resolution; 3. same direction; 4. horizontal 5. speed ************************************************************************** 4. LAWS OF MOTION MULTIPLE CHOICE QUESTIONS: 1. No force is required to keep (A) an object moving in circular motion (B) an object moving in straight line with constant velocity (C) an object moving with constant acceleration (D) an object moving in elliptical path. 2. What is the term for an object’s tendency to resist changes in the state of motion? (A) Friction (B) Force (C) Momentum (D) Inertia 3. The ratio of force on an object to its acceleration is: (A) mass (B) velocity (C) momentum (D) mass density 4. What happens to the acceleration of an object when the force applied to it increases? (A) Decreases (B) Remains constant (C) Increases (D) Become zero 5. When object A exerts a force on object B, what force does object B exert on object A? (A) Equal force in same direction (B) Equal force in opposite direction (C) Lesser force in same direction (D) Greater force in opposite direction 6. Forces always occurs in (A) Triplets (B) Quarters (C) Pairs (D) None 7. Rocket works on the principle of conservation of: (A) Energy (B) Momentum (C) Mass (D) All of these 8. A force F is applied to object for time Δt. What is the impulse? (A) I = F/Δt (B) I = FΔt (C) I = ΔpΔt (D) I = Δp/Δt 9. The component of contact force that is perpendicular to the surface in contact is referred to as: (A) Frictional force (B) Normal reaction force (C) Both (A) and (B) (D) None of the mentioned 10. The spring force is given by (A) F = kx (B) F = k/x (C) F = -k/x (D) F = – kx 11. A block of wood is placed on a surface. A force is applied parallel to the surface to move the block. The frictional force developed acts (A) along the direction of the applied force (B) opposite to the direction of applied force (C) normal to the surface upward (D) normal to the surface downward 12. Which of the following is a self-adjusting force? (A) Limiting friction (B) Dynamic friction (C) Sliding friction (D) Static friction. 13. Which of the following statement is correct? (A) Friction does not depend on the area of contact (B) Friction is always less than the applied force (C) Friction depends on the size of the body (D) Friction depends on the area of contact 14. On a banked road, which force is essential to provide the necessary centripetal force to a car to take a turn while driving at the optimum speed? (A) Component of frictional force (B) Component of normal reaction (C) Both (A) and (B) (D) None of these 15. A cyclist bends while taking a turn in order to (A) reduce apparent speed (B) reduce friction (C) reduce speed (D) provide necessary centripetal force 16. Match the physical quantities of Column I with their dimensions in Column II. Column I Column II (i) Weight (a) [ ] (ii) Acceleration (b) [ ] (iii) Impulse (c) [ ] (A) (i)-(a), (ii)-(c), (iii)-(b) (B) (i)-(a), (ii)-(b), (iii)-(c) (C) (i)-(b), (ii)-(c), (iii)-(a) (D) (i)-(b), (ii)-(a), (iii)-(c) 17. Statement I: There is a stage when frictional force is not needed at all to provide the necessary centripetal force on a banked road. Statement II: On a banked road, due to its inclination the vehicle tends to remain inwards without any chances of skidding. (A) Both Statements I and Statement II are true and the Statement II is a correct explanation of the Statement I. (B) Both Statements I and Statement II are true but Statement II is not a correct explanation of the Statement I. (C) Statement I is true but the Statement II is false. (D) Statement I and Statement II both are false. 18. Which one of the following statements is incorrect? (A) Frictional force opposes the relative motion. (B) Limiting value of static friction is directly proportional to normal reaction. (C) Rolling friction is smaller than sliding friction (D) Coefficient of sliding friction has dimensions of length. 19. A mass M kg is suspended from a spring balance, which in turn is hanging from the hook of another spring balance. What will be the readings on both of these balances? (Neglect the mass of the spring balances) (A) Both will read M kg. (B) Both will read M/2 kg. (C) The lower one will read M kg, and the upper one zero. (D) The sum of both their readings will be M kg. 20. Three blocks with masses m, 2m and 3m are connected by strings, as shown in the figure. After an upward force F is applied on block m, the masses move upward at constant speed v. What is the net force on the block of mass 2m? (g is the acceleration due to gravity) (A) 6 mg (B) Zero (C) 2 mg (D) 3 mg 21. A block slides down an inclined plane with angle θ. What is the force of kinetic friction? (A) = cos (B) = sin (C) = (D) = cos FILL IN THE BLANKS: (impulse, Nm-1, Nm, constant, zero, mass) 1. _________ is a measure of the inertia of a body. 2. When no external force is applied on a system, its total momentum is _____________ 3. A force acting for a short duration is called _____________. 4. At equilibrium net force on a body is _________. 5. The SI unit of spring constant is __________. TWO MARK QUESTIONS: 1. Name the two physical quantities which are defined on the basis of Newton's first law. 2. Write the expression for momentum in vector form and explain the terms. 3. Mention the SI unit and dimensional formula of momentum. 4. Distinguish between mass and weight of a body. 5. Write Newton's second law in component form. 6. State and explain Newton’s I law of motion. 7. Mention the significance of component form of Newton's second law. 8. What is an impulsive force? Give example. 9. Define impulse of a force with an example. 10. State and explain Newton's third law of motion. 11. Give an example which illustrates the law of conservation of linear momentum. 12. State the principle of rocket propulsion. 13. Mention the common forces in mechanics. 14. What are normal reaction and friction? 15. What are contact forces? Give examples for contact forces in mechanics. 16. Mention the types of friction. 17. Mention the advantages of friction. 18. Name the types of kinetic friction. 19. What is sliding friction? Give example. 20. What is rolling friction? Give example. 21. What is banking of roads? Why banking is necessary for a curved road? 22. A constant force of 8 N is applied to a body of mass 3 kg. Find the acceleration of the body. [2.66 ms-2] 23. A 10 kg object accelerates at 2 m/s². What is the magnitude of the force? [20 N] -1 24. A body of mass 1.5 kg has linear moment of 6 kgms. Find its linear velocity. [4 ms-1] THREE MARK QUESTIONS: 1. Write Galileo's experimental observations of motion of objects on a single inclined plane. 2. Explain (i) inertia of rest, (ii) inertia of motion and (iii) inertia of direction, with example for each. 3. Show that the impulse of a force is equal to the change in momentum produced in the body. 4. Write the important points to be noted about the Newton's third law of motion with regard to the usage of the terms "action and reaction". 5. What are concurrent forces? Obtain the condition for the equilibrium of the concurrent forces. 6. State the laws of limiting friction. 7. State the laws of kinetic friction. 8. Mention any three disadvantages of friction. OR Friction is an evil. Explain. 9. Mention any three methods of reducing friction. 10. Derive an expression for maximum speed of circular motion of a car on a level road. 11. A body of mass 25 kg moving initially with a speed of 15 ms-1 brought to stop with an average retardation of 2.5 ms-2. How long does the body take to stop? [6 s] -1 -1 12. Constant force acting on a body of mass 5 kg changes its speed from 4 ms to 7 ms in two seconds, the direction of the body remains unchanged. What is the magnitude of force? [7.5 N] 13. Two billiard balls each of mass 0.05 kg moving in opposite directions with speed 6 ms-1 collide and rebound with the same speed. What is the impulse imparted to each ball due to the other? [– 0.6 Ns] -1 14. A bullet of mass 0.04 kg moving with a speed of 90 ms enters a heavy wooden and is stopped after a distance of 0.6 m. What is the average resistive force exerted by the block on the bullet? [– 270 N] FIVE MARK QUESTIONS: 1. State Newton's second law of motion. Hence, derive the relation ⃗ = ⃗, where symbols have their usual meaning. OR State Newton's second law motion. Arrive at an expression for force acting on a particle of mass m producing in it an acceleration a. 2. State and prove the law of conservation of linear momentum in the case of two colliding bodies. OR Arrive at the principle of conservation of linear momentum for two bodies colliding while moving along same straight line. 3. Derive an expression for maximum speed of a car on a banked road in circular motion. OR Obtain the expression for the maximum speed with which a vehicle can safely negotiate a curved road banked at an angle θ. 4. A driver of a car moving at 25 ms-1 sees a child on the road 70 m ahead and stops the car 20 m earlier to the child. If the mass of the car with the driver is 1000 kg, calculate the force exerted by the brakes on the car and the time taken to stop the car. [6250 N, 4 s] 5. A body of mass 2 kg is acted upon by two perpendicular forces 4 N and 3 N. Calculate the magnitude and direction of the acceleration of the body. [5 N, 53° 8′ with 4 N force] 6. A machine gun of 15 kg fires 0.02 kg bullets at the rate of 10 per second with a speed of 300 ms-1. Calculate the force required to hold the gun in position. [60 N] 7. A body of mass 2 kg is placed on a horizontal surface having kinetic friction 0.4 and static friction 0.5. If the force applied on the body is 18 N, calculate the acceleration of the body. Take g = 10 ms-2. [5 ms-2] 8. Two masses 8 kg and 12 kg are connected at the two ends of a light inextensible string that goes over a frictionless pulley. Calculate the acceleration of the masses and the tension in the string when the masses are released. [1.96 ms-2, 94.08 N] 9. A 70 kg man stands in contact against the inner wall of a hollow cylindrical drum of radius 3 m rotating about its vertical axis with 200 rev/min. The coefficient of friction between the wall and his clothing is 0.15. What is the minimum rotational speed of the cylinder to enable the man to remain stuck to the wall (without falling) when the floor is suddenly removed? [4.7 rad s-1] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 11 B D A C B C B B B D B 12 13 14 15 16 17 18 19 20 21 2 D A C D C C D A B D ANSWERS TO FIBS: 1. mass 2. constant 3. impulse 4. zero 5. Nm-1 *************************************************************************************** 5. WORK, ENERGY AND POWER MULTIPLE CHOICE QUESTIONS: 1. The scalar product is given by (A) A⃗ × B⃗ = AB cosθ (B) A⃗ B⃗ = AB cosθ (C) A⃗ B⃗ = AB sinθ (D) A⃗ × B⃗ = AB sinθ 2. Scalar product obeys (A) Distributive law over addition (B) Commutative law (C) Both (A) and (B) (D) None 3. For unit vectors ̂, ̂, (A) ̂ ̂ = ̂ ̂ = = 1 (B) ̂ ̂ = ̂ ̂ = = 0 (C) Both (A) and (B) (D) None 4. The work performed on an object does not depend upon (A) the displacement. (B) the force applied. (C) the angle at which the force is applied to the displacement (D) initial velocity of the object. 5. Which of the following is an example of positive work? (A) Force applied in the opposite direction of displacement (B) Force applied perpendicular to displacement (C) Force applied in the same direction of displacement (D) No force applied 6. A particle made to go around a circle with a constant speed with the help of a rope. The work done by the rope is (A) positive non–zero (B) negative non–zero (C) Zero (D) None of the these 7. A ball slips down on a frictionless inclined table. The work done by the table surface on the ball is (A) Negative (B) Zero (C) Positive (D) Unity 8. If a light body and heavy body have same kinetic energy, then which one has greater linear momentum? (A) Lighter body (B) Heavier body (C) Both have same momentum (D) can’t be predicted 9. The potential energy of a system increases if work is done (A) upon the system by a non conservative force (B) by the system against a non conservative force (C) by the system against a conservative force (D) upon the system by a conservative force 10. What is the primary difference between kinetic and potential energy? (A) Kinetic energy is stored, while potential energy is dynamic (B) Kinetic energy is dynamic, while potential energy is stored (C) Kinetic energy is mechanical, while potential energy is thermal (D) Kinetic energy is electrical, while potential energy is gravitational 11. A spring is compressed by 2 cm. What type of energy is stored in the spring? (A) Kinetic energy (B) Thermal energy (C) Potential energy (D) Electrical energy 12. Which of the following statements is true? (A) Power is the rate of doing work (B) Energy is the rate of change of power (C) Work is the rate of change of force (D) Force is the rate of change of work 13. Which is the type of collision in which both the linear momentum and the kinetic energy of the system remain constant before and after the collision? (A) Inelastic Collision (B) Elastic Collision (C) Destructive collision (D) None 14. In a perfectly inelastic collision, the two bodies ___________ after collision. (A) move in opposite direction (B) move with different velocities (C) moves in perpendicular direction (D) stick together 15. If a body of mass m collides head on, elastically with velocity u with another identical body at rest. After collision velocity of the second body will be (A) 2u (B) u (C) zero (D) can’t decide 16. Match the CGS units of physical quantities of Column I with their SI unit conversion factors in Column II. Column I Column II (i) 1 dyne (a) 10-7 J (ii) 1 erg (b) 746 W (iii) 1 hp (c) 10-5 N (A) (i)-(b), (ii)-(c), (iii)-(a) (B) (i)-(a), (ii)-(b), (iii)-(c) (C) (i)-(c), (ii)-(a), (iii)-(b) (D) (i)-(b), (ii)-(a), (iii)-(c) 17. Statement I: Kinetic energy of a body is quadrupled, when its velocity is doubled. Statement II: Kinetic energy is proportional to square of velocity. (A) Both Statements I and Statement II are true and the Statement II is a correct explanation of the Statement I. (B) Both Statements I and Statement II are true but Statement II is not a correct explanation of the Statement I. (C) Statement I is true but the Statement II is false. (D) Statement I and Statement II both are false. 18. A bullet of mass m and velocity v is fired into a large block of wood of mass M which is at rest. If the bullet gets stuck in the block, the final velocity of the system is (A) (B) (C) (D) 19. The restoring force of a spring with a block attached to the free end of the spring is represented by (A) (B) (C) (D) 20. A body is initially at rest. It undergoes one-dimensional motion with constant acceleration. The power delivered to it at time t is proportional to (A) t1/2 (B) t (C) t3/2 (D) t2 FILL IN THE BLANKS: (conservative, kinetic energy, power, scalar product, constant, zero) 1. Work is ____________ of force and displacement. 2. When work done is zero, then the speed of a body remains ____________. 3. The total mechanical energy of a system is conserved if the forces doing work on it are ____________. 4. In an inelastic collision, the _________ does not remain constant. 5. The rate of doing work is called ____________. TWO MARK QUESTIONS: 1. Mention the necessary conditions for work done. 2. State the conditions under which no work is done. OR Write the conditions for zero work-done. 3. Under what conditions the work done by a force is maximum and minimum? 4. Can acceleration be produced without doing any work? Give example. 5. Write the SI unit and dimensional formula of work. 6. What are conservative and non-conservative forces? Give example. 7. Mention the SI unit of energy and write its dimensional formula. 8. Name the types of mechanical energy. 9. Define kinetic energy of a body. Give examples. 10. Define potential energy. Give examples. 11. State and explain force law for the spring. 12. What is a spring constant of a spring? Give its SI unit. 13. Draw a graph of variation of kinetic energy and potential energy of a block attached to a vibrating spring which obeys Hooke's law. 14. Mention the different forms of energy. 15. What is the unit of electrical energy? Express it in joules. 16. Which physical quantity is measured in HP? Express it in SI units. 17. Write the SI unit and dimensional formula of power. 18. Show that = ⃗ ∙ ⃗, where the symbols have their usual meaning. 19. Mention the types of collisions. 20. What is elastic collision? Give examples. 21. What is inelastic collision? Give examples. 22. Distinguish between elastic collision and inelastic collision. 23. A constant force of 8 N is applied to a body which displaces it through a distance of 9 m in the direction of the applied force. Find the work done by the force. [72 J] 24. An object of mass 10 kg is moving with speed 5 m/s. Estimate the kinetic energy associated with the object. [125 J] THREE MARK QUESTIONS: 1. Show that the work done is equal to the scalar product of force and displacement vectors. 2. What is meant by positive work, negative work and zero work? Give examples of case. 3. Derive an expression for the work done by a variable force graphically. 4. Distinguish between conservative and non-conservative forces with an example for each. 5. State and prove work-energy theorem for a constant force. 6. Derive an expression for gravitational potential energy 7. Derive the expression for the potential energy of a spring. 8. Show that kinetic energy of the object on reaching the ground dropped from a certain height is equal to its gravitational potential energy at the initial height. 9. State and prove the law of conservation of mechanical energy. 10. A force ⃗ = (5 ̂ + 3 ̂ + 2 ) N is applied over a particle which displaces it from its origin to the point ⃗ = (2 ̂ − ̂) m. Calculate the work done on the particle [7 J] 11. A man pushes a roller with a force of 50 N through a distance of 20 m. Calculate the work done if the handle of the roller is inclined at an angle of 600 with the ground. [500 J] FIVE MARK QUESTIONS: 1. State and prove work-energy theorem for a variable force. 2. Derive an expression for the potential energy of an elastic stretched spring. 3. Show that the spring force is conservative. 4. Show that the total mechanical energy of a freely falling body under gravity is conserved. 5. Derive expressions for the velocities of colliding particle after the collision in one dimensional elastic collision. Discuss special cases. 6. Derive an expression for the loss of kinetic energy when a moving particle collides with another particle at rest in a completely inelastic collision in one dimension. 7. A body of mass 0.5 kg travels in a straight line with velocity v = 5 x3/2 ms-1. What is the work done by the net force during its displacement from x = 0 to x = 2 m? [50 J] 8. A bullet of mass 100 gm is fired from a gun with a velocity of 432 kmph. It strikes a wooden plank and emerges out in 0.01 sec with a velocity of 144 kmph. Calculate the work done by the bullet in penetrating wooden plank and thickness of wooden plank. [640 J, 0.8 m] -1 9. A bullet of mass 0.012 kg and horizontal speed 70 ms strike a block of wood of mass 0.4 kg and instantly comes to rest with respect to the block. The block is suspended from the ceiling by means of thin wires. Calculate the height to which the block rises. [0.2123 m] 10. A rain drop of mass 1 g falling from a height 1 km hits the ground at a speed 50 ms-1. Calculate the (i) work done by the gravitational force and (ii) work done by the unknown resistive force. Given, g = 9.8 ms-2 [9.8 J, 8.55 J] 11. A pump on the ground floor of a building can pump up water to fill a tank of volume 30 m3 in 15 min. If the tank is 40 m above the ground, and the efficiency of the pump is 30%, how much electric power is consumed by the pump? [43.56 W] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 B C A D C C B B C B 11 12 13 14 15 16 17 18 19 20 C A B D B C A C D B ANSWERS TO FIBS: 1. scalar product 2. constant 3. conservative 4. kinetic energy 5. Power *************************************************************************************** 6. SYSTEM OF PARTICLES AND ROTATIONAL MOTION MULTIPLE CHOICE QUESTIONS: 1. What do we call a body in which the distances between all particles remain constant, even when subjected to external force? (A) Elastic body (B) Plastic body (C) Rigid body (C) Fluid body 2. A moving Radium nucleus decays into Radon and an alpha particle. The two particles produced during decay move in different directions. What is the direction of motion of the centre of mass after decay? (A) The centre of mass moves along the original path. (B) The centre of mass moves along with Radon because Radon is heaver (C) The centre of mass moves along with alpha particle because alpha particle moves faster. (D) When radium splits in to two then no more center of mass. 3. What is the vector product of two parallel vectors ⃗ and ⃗? (A) AB (B) zero (C) 1 (D) A.B 4. ⃗ and ⃗ are two non zero vectors. If ⃗. ⃗ = 0, then what is the angle between ⃗ and ⃗ ? (A) zero (B) 900 (C) 1800 (D) 2π rad 5. A body rotates with a constant angular momentum. Then (A) Torque is zero (C) Torque is maximum (B) Torque is minimum (D) Torque is independent of angular momentum 6. The relation between linear velocity and angular velocity of a rotating body is (A) ⃗ = ⃗ × ⃗ (B) v⃗ = r⃗ × ω⃗ (C) = (D) = 7. The physical quantity which is equal to (torque)×(angular displacement) is _______ (A) Angular velocity (B) Work (C) Angular momentum (D) Angular acceleration 8. What is the angle between ⃗ × ⃗ and ⃗ × ⃗ ? (A) Zero (B) 900 (C) 1800 (D) 2π rad 9. Write the dimension of angular momentum ⃗. (A) [ M1L2T-1 ] (B) [ M1L-2T1 ] (C) [ M-1L2T-1 ] (D) [ M-2L2T-1 ] 10. SI unit of torque is (A) rad s-1 (B) Nm-1 (C) js-1 (D) Nm 11. A point on the body about which the gravitational torque is zero is called (A) center of body (B) center of gravity (C) geometrical center (D) central force 12. Name the physical quantity which is equal to ∑ (A) Angular velocity (B) Work (C) Moment of inertia (D) Inertia 13. Some dancers performing a pirouette on the toes of one foot. They employ the principle of conservation of (A) linear momentum (B) angular momentum (C) Mass (D) torque 14. The kinetic energy of a rotating body is, KE = (A) (B) (C) (D) Iω 15. A pair of equal and opposite forces with different lines of action produces (A) Rotation without translation (C) Both Translation and rotation (C) Translation without rotation (D) Neither translation nor rotation 16. A seesaw is balanced with a child on each end. What happens if one child moves closer to the fulcrum? (A) The sea saw will remain balanced. (B) The side where the child moved will go down. (C) The side where the child moved will go up (D) The seesaw will start rotating faster. 17. Two boys are sitting on a seesaw balanced around its fulcrum. Boy A weighs 20kg and sits 2 meters away from the fulcrum. Boy B weighs 40kg and sits 1 meter away from the fulcrum. Why is the seesaw balanced? (A) The sum of weights is equal to zero. (B) The weight of boy A is greater than boy B. (C) The sum of moments around the fulcrum is equal to zero. (D) Both (A) and (B) are correct. 18. Choose the correct diagram which shows the direction of angular velocity of a rotating disc. 19. Some regular objects are listed in column I and their moments of inertia are listed in column II. Identify the correct match. COLUMN I COLUMN II (i) Solid sphere along any diameter (a) (ii) Thin circular disc at its center a, perpendicular to its (b) plane (iii) Hollow cylinder along its axis (c) (A) (i) – (a), ( ii) – (b), (iii) – (c) (B) (i) – (b), (ii) – (c), (iii) – (a) (C) (i) – (c), (ii) – (b), (iii) – (a) (D) (i) – (a), (ii) – (c), (iii) – (b) 20. STATEMENT 1: A girl sits on a swivel chair. When she brings her arms closer to the body, the angular speed of rotation increases. STATEMENT 2: In the absence of friction and external torque, the angular momentum of a system is conserved. (A) Both the statements are correct. STATEMENT 2 is the correct explanation for the STATEMENT 1. (B) Both the statements are correct. STATEMENT 2 is not the correct explanation for the STATEMENT 1. (C) STATEMENT 1 is correct. STATEMENT 2 is wrong. (D) STATEMENT 2 is correct. STATEMENT 1 is wrong. FILL IN THE BLANKS: [moment of force, radius of gyration, power, moment of inertia, angular acceleration, work ] 1. The physical quantity which is equal to the time rate of change of angular momentum is……….. 2. The ……….. of a body about an axis may be defined as the distance from the axis of a mass point where mass is equal to the mass of the whole body and whose moment of inertia is equal to the moment of inertia of the body about the axis. 3. The …………. of a body is directly proportional to the applied torque and inversely proportional to moment of inertia. 4. The rotational analogue of mass in linear motion is …………….. 5. The …………. required to rotate a body with an angular velocity ω is ω, where is the torque. TWO MARK QUESTIONS: 1. What is the pure translational motion? Give one example 2. What is the pure rotational motion? Give one example 3. Give an example for a body whose centre of mass lies (i) inside the body and (ii) outside the body 4. What is mechanical advantage of a lever? The mechanical advantage of a lever is greater than one. What does it mean? 5. Define vector product of two vectors. Give an example. 6. Define moment of force. Write the expression for it. 7. Mention the two factors on which torque of a rotating body depends. 8. Define angular momentum. Write the expression for it. 9. Write the dimension and SI unit of angular momentum. 10. State and explain the principle of conservation of angular momentum. 11. Write any two examples for conservation of angular momentum. 12. Define moment of inertia of a particle. Write its SI unit. 13. Mention two factors on which moment of inertia of a rigid body depends. 14. Define couple. Give the expression for moment of couple. 15. Give two examples for couple. 16. State the principle of moments. What is mechanical advantage? 17. Give the general conditions of equilibrium of a rigid body. 18. Why a flywheel is used in engines of vehicles? 19. What are the factors on which the moment of inertia of a body depends? 20. To maintain a rotor at a uniform angular speed of 200rads-1¸ an engine needs to transmit a torque of 180Nm. What is the power required by the engine? [3600 W] THREE MARK QUESTIONS: 1. Write three kinematic equations of rotational motion of a body with a uniform angular acceleration and explain the terms. 2. What is the rotational analogue for the equation dw = Fdx? Prove that the power = ω 3. Write the relation between angular momentum and moment of inertia. Prove that the torque = α 4. Distinguish between vector product and scalar product of two vectors. Give one example for each. 5. Explain the principles of moments for a lever. 6. Obtain the relation between linear velocity and angular velocity of a rotating body. 7. Derive the expression for kinetic energy of a rotating body. 8. Two particles of masses 2kg and 4kg located at 2m and 4m, respectively, from the origin along x axis. Find the coordinate of center of mass. [3.33m from origin] 9. Find the torque of a force 2ı̂ − 3ȷ̂ + 4k about the origin. The force acts on a particle whose position vector is ı̂ + ȷ̂ − k. [ ̂− ̂− ] 10. A meter stick is balanced on a knife edge at its centre. When two Coins, each of mass 5g are put on the top of the other at 12.0cm mark, the stick is found to be balanced at 45.0cm. What is the mass of the meter stick? [66 g] FIVE MARK QUESTIONS: 1. Show that torque is equal to rate of change of angular momentum of a particle. 2. Define centre of mass. Assuming the expression for velocity of centre of mass show that the centre of mass moves as if all the mass of the system is concentrated at the centre of mass and all the external forces were applied were applied at that point. 3. Find the centre of mass of three particles at the vertices of an equilateral triangle. The masses of the particles are 100 g, 150 g and 200 g respectively. Each side of the equilateral triangle is 0.5 m long. [ = , = ] √ 4. A rope of negligible mass is wound round a hollow cylinder of mass 3kg and radius 40cm. What is the angular acceleration of the cylinder if the rope is pulled with a force of 30N? What is the linear acceleration of the rope? Assume that there is no slipping. [12Nm,25rads-1,750ms-2 ] 5. A solid cylinder of mass 20 kg rotates about its axis with angular speed 100rads-1. The radius of the cylinder is 0.25m. What is the kinetic energy associated with the rotation of the cylinder? What is the magnitude of angular momentum of the cylinder about its axis? [3125J, 62.5kgm2s-1 ] 6. The angular speed of a motor wheel is increased from 1200 rpm to 3120 rpm in 16 seconds. (i) What is its angular acceleration, assuming the acceleration to be uniform? (ii) How many revolutions does the engine make during this time? [4π rads-1, 576 rotations ] 7. A flywheel of mass 10 kg and diameter 0.4m rotating at 120 rpm has its speed increased to 720 rpm in 8 seconds. Find the torque acting on the flywheel. [12.6Nm] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 C A B B A A B C A D 11 12 13 14 15 16 17 18 19 20 B C B C A C C C B A ANSWER TO FIBS: 1. moment of force 2. radius of gyration 3. angular acceleration 4. moment of inertia 5. power *************************************************************************************** 7. GRAVITATION MULTIPLE CHOICE QUESTIONS: 1. Name the astronomer who proposed the geocentric model of the planetary system. (A) Aryabhatta (B) Nicolas Tesla (C) Ptolemy (D) Kepler 2. In ‘Heliocentric theory’ of planetary system, …………… is the center. (A) Earth (B) Moon (C) Sun (D) Jupiter 3. The SI unit of universal gravitational constant (G) is : (A) N m2kg-1 (B) N m2kg-2 (C) N m kg-2 (D) N m2kg-3 4. The dimension of universal gravitational constant (G) is (A) [M1L3T2] (B) [M-1L-3T-2] (C) [M1L-3T-2] (D) [M-1L3T-2] 5. The correct form of Newton’s law of gravitation in vector form is( symbols have usual meaning) (A) ⃗ = ̂ (B) ⃗ = − ̂ (C) ⃗ = ̂ (D) ⃗ = − ̂ 6. Which of the following quantity is conserved according to Kepler’s law of areas? (A) Linear momentum (B) Angular momentum (C) Potential energy (D) Kinetic energy 7. When the earth is closer to the sun, earth (A) moves faster (B) moves with same speed. (C) moves slower (D) moves with constant acceleration. 8. Which experiment led to the determination of universal gravitational constant? (A) Cavendish’s experiment (B) Kepler’s experiment (C) Newton’s experiment (D) Galileo’s experiment 9. What is the value of universal gravitational constant in SI units? (A) 6.67×10-11 N m2kg-2 (B) 9.8 ms-2 (C) 6400km (D) 11.2km/s 10. The value of time period of revolution of moon around earth is (A) one year (B) one month (C) 27.3days (D) 27.3month 11. Which statement best describes Newton’s law of gravitation? (A) It applies only to objects on earth (B) It is limited to interactions between planets (C) It is applicable to all objects with mass in the universe. (D) It only applies to celestial bodies like stars and planets. 12. The acceleration due to gravity due to a hollow spherical shell of uniform density at a point inside it is (A) 9.8ms-2 (B) same as its value at the surface (C) zero (D) more than its value at the surface 13. The acceleration due to gravity at a large height h from the surface of earth is given by (A) g = (B) g(h) = g 1 − (C) g(h) = g 1 – (D) g(h) = ( ) 14. The work required to bring a particle of unit mass from infinity to the given point is called (A) gravitational potential (B) gravitational constant (C) gravitational potential energy (D) gravitational kinetic energy. 15. Who was the author of the book Mathematical Principles of Natural Philosophy (Principia)? (A) Johannes Kepler (B) Albert Einstein (C) Isaac Newton (D) Galileo Galilei 16. The escape speed for an object of mass ‘m’ from the surface of earth is 11.2km/s. The minimum speed required for an object of mass ‘2m’ to escape the gravitational influence of the earth is (A) 44.8km/s (B) 33.6km/s (C) 22.4km/s (D) 11.2km/s 17. STATEMENT-1: When two objects of different masses are dropped simultaneously from the same height; they will reach the earth’s surface at the same time. ( neglect the air resistance) STATEMENT- 2: The acceleration due to gravity is independent of the mass of the object. (A) Both the statements are correct. STATEMENT-2 is the correct explanation for the STATEMENT-1. (B) Both the statements are correct. STATEMENT-2 is not the correct explanation for the STATEMENT-1. (C) STATEMENT-1 is correct. STATEMENT-2 is wrong. (D) STATEMENT-2 is correct. STATEMENT-1 is wrong. 18. The time period of a planet is T and its distance from the sun is R. which one of the following graphs represents correct relation between T2 and R3. 19. The thickness of a spherical shell of mass M is R2-R1. The force exerted by this shell on an object of mass m located at a distance r varies like, 20. A satellite is orbiting in an orbit of radius RE+h, its kinetic energy is KE, potential energy is PE and total energy is E. Choose the correct relation (A) E = KE (B) PE = 2E (C) PE = 2KE (D) PE = − KE FILL IN THE BLANKS: [minimum, maximum, zero, energy, time period, linear momentum] 1. The acceleration due to gravity is ……………. at the surface of the earth. 2. The gravitational potential due to earth at a very large distance is ………… 3. The ……………… of revolution of planet Saturn around the sun is more than that of the planet Jupiter. 4. When an object is moving under the influence of gravity, …………is not conserved. 5. The …………. of any orbiting satellite is negative because it is bound to the earth by gravitational force. TWO MARK QUESTIONS: 1. Moon has no atmosphere. Why? 2. Define gravitational potential energy of a body. Give an expression for it. 3. State and explain Newton’s law of gravitation. 4. What is escape speed? Give its value in the case of earth. 5. Define orbital speed of a satellite around the earth. Write the expression for it. 6. Why does an object weigh more at the surface of earth than at any point inside the earth? 7. What is a satellite? Name the natural satellite of earth. 8. Give any two applications of artificial satellites. 9. The both radius and mass of a planet are two times that of the earth’s values. Calculate the acceleration due to gravity on the surface of that planet. [4.9ms-2] 10. The radius of the earth is RE. Find the depth at which the acceleration due to gravity is half the acceleration due to gravity at the surface of the earth. [d = RE/2] THREE MARK QUESTIONS: 1. State Kepler’s laws of planetary motion. 2. Derive the relationship between g and G. OR Derive the expression for acceleration due to gravity at a point on the surface of earth. 3. Assuming the expression for orbital velocity of a satellite at height h, derive an expression for its time period. 4. The acceleration due to gravity on Moon is 1.7 ms-2 and its radius is 0.27 times the radius of the Earth. Calculate the ratio of mass of the Earth to the mass of the Moon. 5. Mass of earth is 80 times that of moon and the radius of earth is 4 times that of moon. If the acceleration due to gravity on earth is 9.8 m/s2, calculate its value on the surface of the moon. [1.96 m/s2] 6. The escape velocity on earth is 11.2 km/s. Find the escape velocity on a planet whose radius is two times that of earth and mass is three times that of earth. 7. A Saturn year is 29.5 times earth year. How far is Saturn from sun if earth is 1.5 × 108 km from the sun? [1.43× 1012m ] 8. An earth satellite is in a circular orbit at a height of 200 km above the earth’s surface. If the radius of earth is 6400 km, find the orbit velocity. [7.8km/s] 9. A rocket is fired from the earth towards the sun. At what distance from the earth’s centre is the gravitational force on the rocket zero? Mass of the sun=2×1030kg, mass of the earth = 6× 1024 kg. Neglect the effect of other planets etc. (orbital radius = 1.5×1011m). [2.6× 108m ] FIVE MARK QUESTIONS: 1. Derive the expression for acceleration due to gravity at a point above the surface of the earth. 2. Derive the expression for acceleration due to gravity at a point below the surface of the earth. 3. Derive the expression for gravitational potential energy of a particle at a point due to the earth. 4. Obtain the expression for escape speed for an object from the surface of earth. 5. Derive the expression for orbital speed of a satellite around the earth. 6. Obtain the expression for energy of an orbiting satellite. 7. State Kepler’s law of area for a planet and show that the law of areas follows from the law of conservation of angular momentum. 8. Describe Cavendish’s experiment to determine the value of gravitational constant G. 9. Assuming the earth to be a sphere of uniform mass density, how much would a body weighs at a depth equal to half the radius of the earth if it weighs 250N on the surface of earth? What will the weight of the same body at the centre of the earth? [125N, zero] 10. Find the acceleration due to gravity at a height of 400km above the earth’s surface. Given: Radius of the earth = 6400km. g = 9.8 ms-2 [8.575ms-2] 11. A body weights 63N on the surface of the earth. What is the gravitational force on it due to the earth at a height equal to half the radius of the earth? [28N] -1 12. A rocket is fired vertically upwards with a speed of 5kms from the earth’s surface. How far the earth does the rocket go before returning to earth. (Mass of earth = 6 × 1024 kg, Mean radius of the earth = 6.4 ×106 m, G = 6.67×10-11 N m2 kg-2) [h = 1.6×106m ] 13. The size of the planet is same as that of the Earth. Its mass is 4 times that of Earth. An object of mass 2kg is placed at height of 2m from the surface of the planet. Find the potential energy of the object related to the surface of the planet. (g = 10 ms-2 on the surface of the earth). [160J] 14. Calculate the orbital velocity and period of revolution of an artificial satellite of earth moving at an altitude of 200 km. The radius of earth is 6400 km and mass of earth is 6 × 1024 kg. [7.78kms-1, 1.43h] 15. The escape speed of a projectile on the surface is 11.2 km/s. A body is projected with thrice this speed what is the speed of the body far away from the earth? Ignore the pressure of sun and other planets. [vf = 31.68 km/s] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 9 10 C C B D B B A A A C 11 12 13 14 15 16 17 18 19 20 C C D A C D A B D B ANSWERS TO FIBS: 1. maximum, 2. zero, 3.time period, 4. linear momentum, 4. energy *************************************************************************************** 8. MECHANICAL PROPERTIES OF SOLIDS MULTIPLE CHOICE QUESTIONS: 1. The breaking stress of a wire depends upon: (A) length of the wire (B) the radius of the wire (C) the material of the wire (D) shape of the area of cross-section of the wire. 2. The SI unit and the dimensional formula for modulus of elasticity are: (A) Pa, [ML2T-2] (B) Nm-2, [ML-1T-2] (C) Pa, [ML1T-2] (D) N, [ML-1T-2] 3. The following table lists several points relates to the given stress-strain curve and the corresponding names. Match column – I with correct option among column – II. Column – I Column – II (a) Point A (p) Measure of ductility of the material (b) Point B (q) Proportionality limit (c) Point E (r) Fracture point (d) Region DE (s) Yield Point (A) (a) → (q), (b) → (s), (c) → (r), (d) → (p) (B) (a) → (s), (b) → (q), (c) → (r), (d) → (p) (C) (a) → (q), (b) → (s), (c) → (p), (d) → (r) (D) (a) → (s), (b) → (q), (c) → (p), (d) → (r) 4. The stress that changes the volume of the object without changing its shape is: (A) compressive stress (B) tensile stress (C) shear stress (D) hydraulic stress 5. After what point on the stress – strain curve for a metal, does the strain keeps increasing even by a reduced applied force? (A) Yield point (B) Ultimate tensile strength (C) Fracture point (D) Proportional limit 6. Consider the following statement: STATEMENT – I: Steel is preferred over copper and aluminium in structural designs. STATEMENT – II: Steel is more elastic than copper and aluminium as its Young’s modulus is greater than that for copper and aluminium. Among the given two statements: (A) Both statements are correct and statement – II is the correct reason for statement – I. (B) Both statements are correct but statement – II is not a correct reason for statement – I. (C) Statement – I is correct but statement – II is wrong. (D) Both statements are wrong. 7. The approximate relationship between Young’s modulus and rigidity modulus is: (A) ≈ (B) ≈ (C) ≈ (D) ≈ 8. Which one of the following correctly represents the general relationship between bulk moduli (B) of solids, liquids and gases? (A) < < (B) > = (C) = > (D) > > 9. The Young’s modulus of a perfect rigid body is: (A) zero (B) infinite (C) 0.5 Pa (D) negative 10. If is the stress in a stretched wire and ε is the corresponding strain, the elastic energy density in the wire is given by: (A) = (B) = (C) = (D) = 11. Consider the following statement: STATEMENT – I: To avoid buckling of beams, load-bearing bars of I – section are used. STATEMENT – II: Bars of I – shape provide large load bearing surface and good strength with less weight. Among the given two statements: (A) Both statements are correct and statement – II is the correct. (B) Statement – II is correct but statement – I is wrong (C) Statement – I is correct but statement – II is wrong. (D) Both statements are wrong. 12. Within proportionality limit, the slope of stress – strain curve gives: (A) Modulus of elasticity (B) Compressibility (C) Ultimate tensile stress (D) Reciprocal of modulus of elasticity 13. The stress-strain graphs for materials A and B are shown in the figure. The graphs are drawn to the same scale. Then: (A) Material B has greater Young’s modulus (B) Material A is more brittle. (C) Material A is stronger than B (D) Both materials are equally ductile. 14. Which one of the following statements is wrong? (A) The stretching of a coil is determined by its shear modulus. (B) The Young’s modulus of rubber is greater than that of steel. (C) When a spring is stretched by applying a load to one of its free ends, both longitudinal and shear strains are produced in the spring. (D) Poisson’s ratio is the ratio of lateral strain to the longitudinal strain. 15. The maximum load a wire can withstand without breaking, when its length is reduced to half of its original length, will (A) doubled (B) half (C) four times (D) remain same FILL IN THE BLANKS: (Poisson ratio, Young’s modulus, Shear modulus, Compressibility, Bulk modulus) 1. The ratio between longitudinal stress and longitudinal strain is called ___________. 2. ____________ is the shear stress per unit shear strain. 3. Lateral strain = ____________ × Longitudinal strain. 4. The reciprocal of bulk modulus is called _____________. TWO MARK QUESTIONS: 1. What do you mean by elasticity and plasticity? 2. Give one example each for elastic and plastic substance. 3. Define stress. Mention its SI unit. 4. Define strain. What is its unit? 5. State and explain Hooke’s law. 6. Define (i) compressive stress and (ii) tensile stress. 7. Define (i) shearing stress and (ii) hydraulic stress. 8. Define longitudinal strain. Write the expression for it. 9. Define shearing strain. Write an expression for it. 10. Define volume strain. Write an expression for it. 11. What is yield point? Define yield strength of a material. 12. What are elastomers? Give an example. 13. Draw stress – strain curve for an elastomer. 14. Write the expression for Young`s modulus. Explain the terms. 15. Write the expression for rigidity modulus of the material. Explain the terms. 16. Mention the expression for bulk modulus of the material. Explain the terms. 17. Write two application of elastic behavior of the material. 18. Define compressibility. Mention its SI unit. 19. Define Poisson ratio. Give an example for it. 20. Write the expression for the buckling sag of a beam that is supported at its two ends and is loaded at the center. Explain the terms. 21. A steel rod of area of cross section 3.14 × 10-4 m2 is stretched by a force of 100 kN. Calculate the stress acting on the rod. [3.2 × 108 Pa] 22. Calculate the fractional change in the volume of glass sphere when subjected to a hydraulic pressure of 1.013 × 106 Nm-2. (Bulk modulus of glass is 3.7 × 1010 Nm-2) [0.0027%] 9 23. The bulk modulus of a material is 2 × 10 Pa. What is its compressibility? [5 × 10-10 Pa-1] THREE MARK QUESTIONS: 1. Draw typical stress – strain graph for copper. Represent yield point, elastic limit and fracture point. 2. Define (i) Young’s modulus (ii) Rigidity modulus and (iii) Bulk modulus. 3. Derive an expression for elastic potential energy in a stretched wire. 4. A steel rod of radius 10 mm and length 2 m is stretched by a force of 100 kN along its length. The elongation in the wire is 3.2 mm. Find the stress and Young’s modulus of the material of the rod. [3.2 × 108 Pa, 2 × 1011 Pa] 5. The upper face of a cube of edge 1m moves through a distance of 1 mm relative to the lower fixed surface under action of a tangential force 1.5 × 108 N. Calculate tangential stress and rigidity modulus. [150 MPa, 150 GPa] 6. A square lead slab of side 50 cm and thickness 10 cm subjected to shearing force of 9 × 104 N. How much will the upper edge be displaced? Shear modulus of lead =5.6 GPa. [0.16 mm] 7. When a rubber ball is taken in deep of 100 m in sea its volume is decrease by 0.1% due to hydraulic stress. If the density of seawater is 1000 kgm-3, calculate the bulk modulus and compressibility of the rubber. [9.8 × 108 Pa, 10-9 Pa-1] -5 2 8. A steel wire of length 5 m and cross section 3 × 10 m stretched by the same amount as copper of length 3.7 m and cross section 4 × 10-5 m2 under given load. Find the ratio of Young’s modulus of steel to that of copper. [1.8] 9. The average depth of Indian Ocean is about 3000 m. Calculate the fractional compression, ΔV/V, of water at the bottom of the ocean, given that the bulk modulus of water is 2.2 × 109 N m–2. (Take g = 10 m s–2) [1.36%] 10. A steel cable with a radius of 1.5 cm supports a chairlift at a ski area. If the maximum stress is not to exceed 108 N m–2, what is the maximum load the cable can support? [0.71 Kn] 11. A rigid bar of mass 15 kg is supported symmetrically by three wires each 2.0 m long. Those at each end are of copper and the middle one is of iron. Determine the ratios of their diameters if each is to have the same tension. (Young’s modulus for iron and copper are 190 GPa and 110 GPa respectively) [1.31] 12. Determine the volume contraction of a solid copper cube, 10 cm on an edge, when subjected to a hydraulic pressure of 7.0 × 106 Pa. [– 0.05 cm3] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 C B A D B A C D 9 10 11 12 13 14 15 B D A A C B D ANSWERS TO FIBS: 1. Young’s modulus; 2. shear modulus; 3. poisson ratio; 4. compressibility ************************************************************************** 9. MECHANICAL PROPERTIES OF FLUIDS MULTIPLE CHOICE QUESTIONS: 1. Which one of the following statements is wrong? (A) Solids have a definite shape while liquids and gases do not have definite shape. (B) The volume of any substance depends on the pressure acting on it. (C) Solids and liquids have lower compressibility when compared to gases. (D) When compared to solids, fluids offer large shear stress. 2. Consider the following two statements: STATEMENT – I: A sharp needle when pressed against our skin pierces it. STATEMENT – II: Smaller the area on which the force acts, greater is the pressure. Between the above two statements: (A) Both statements are correct and statement – II is the correct reason for statement – I. (B) Both statements are correct but statement – II is not a correct reason for statement – I. (C) Statement – I is correct but statement – II is wrong. (D) Both statements are wrong. 3. The pressure in a fluid at rest is the same at all points if they are at the same height. This is the statement of: (A) Bernoulli’s principle (B) Pascal’s law (C) Stoke’s law (D) Hooke’s law 4. If the area of cross-section of a tube of flow decreases, then the rate of flow of the fluid through it: (A) increases (B) remains constant (C) decreases (D) may increase or decrease 5. When a tank is open to the atmosphere, the speed of efflux is given by (symbols have usual meanings): (A) = 2 ℎ (B) = ℎ (C) = (D) = 6. Dynamic lift due to spinning is called: (A) Pascal’s law (B) Magnus effect (C) surface tension (D) viscosity 7. For a given fluid in laminar flow, at a particular temperature, the shearing stress is: (A) directly proportional to strain (B) directly proportional to (strain)2 (C) directly proportional to strain rate (D) inversely proportional to strain rate 8. When an rain drop falls through the atmosphere from a large height: (A) the net force on it remains constant (B) the net force on it decreases as it falls (C) the net force on it increases as it falls (D) the drop undergoes continuous retardation 9. Consider the following two statements: STATEMENT – I: No two streamlines can cross each other. STATEMENT – II: If two streamlines intersect, an oncoming fluid particle can go either one way or the other and the flow would not be steady. Between the above two statements: (A) Both statements are correct and statement – II is the correct reason for statement – I. (B) Both statements are correct but statement – II is not a correct reason for statement – I. (C) Statement – I is correct but statement – II is wrong. (D) Both statements are wrong. 10. SI unit and dimensional formula for surface tension is: (A) N m-1, [ML-1T-2] (B) N m, [MT-2] (C) N m-1, [MT-2] (D) J m2, [MT-2] 11. Let θ be the angle of contact between a liquid drop and a solid surface. Then: (A) The liquid wets the surface if θ > 90° (B) The liquid wets the surface if θ = 90° (C) The liquid wets the surface if θ < 90° (D) The liquid does not wet the surface if θ > 90° 12. Which one of the following statements is correct? (A) Hydrostatic pressure is a vector quantity. (B) Surface tension of a liquid is independent of the area of the surface. (C) Water with detergent dissolved in it should has large angles of contact. (D) Liquids like water, alcohol are more viscous than blood, glycerine, etc. 13. Bernoulli’s principle is: (A) the law of conservation of energy for an incompressible, non-viscous fluid. (B) the law of conservation of energy for an compressible, viscous fluid. (C) the law of conservation of mass for an incompressible, non-viscous fluid. (D) the law of conservation of momentum for an incompressible, non-viscous fluid. 14. The principle behind continuity equation for flow of incompressible fluids is: (A) the law of conservation of energy (B) the law of conservation of momentum (C) the law of conservation of mass (D) Pascal’s law 15. As the temperature of a water inside a glass capillary tube increases, the height of water in the capillary tube (neglect the thermal expansions): (A) increases (B) decreases (C) remains the same (D) may increase or decrease FILL IN THE BLANKS (turbulent, hydraulic lift, viscosity, dynamic lift, surface tension, open tube manometer) 1. Drops and bubbles are spherical because of their____________ property. 2. With increase in temperature, __________ of gases increases. 3. Beyond a limiting value, called critical speed, this flow of a fluid becomes __________. 4. The force that acts on a body, such as airplane wing, by virtue of its motion through a fluid is called________. 5. A _________ works on the principle of Pascal’s law. TWO MARK QUESTIONS: 1. What are fluids? Give an example. 2. Define pressure. Write its unit. 3. Define (i) density and (ii) relative density. 4. Write the equation for gauge pressure and explain the terms. 5. Write the expression for absolute pressure and explain the terms. 6. State and explain Pascal’s law. 7. Mention any two factors on which pressure inside a fluid depends. 8. Write the conversion factors of (i) 1 torr and (ii) 1 bar into pascals. 9. In what fields the units torr and bar are used to measure pressure? 10. What is the use of a (i) mercury barometer and (ii) open tube manometer? 11. Write any two applications of Pascal’s law. 12. What is streamline motion? Give an example 13. What is turbulent motion? Give an example. 14. What are the limitations of Bernoulli’s equation? 15. Write any two applications of Bernoulli’s principle. 16. What are (i) Dynamic lift and (ii) Magnus effect? 17. What is viscosity? Write the expression for coefficient of viscosity. 18. Write the SI unit and dimensional formula for coefficient of viscosity. 19. State Stoke’s law. Write the expression for the viscous drag force on a spherical object moving through a fluid. 20. What are the factors on which drag force on an object moving through a fluid depends? 21. Define the terms (i) surface energy and (ii) surface tension. 22. (i) Why are drops and bubbles spherical in shape? (ii) Why are detergents used as wetting agents? 23. Write the expression for capillary rise inside a capillary tube. Explain the terms. 24. Mention the expressions for excess pressure inside (i) a drop and (ii) a bubble. 25. The two thighbones (femurs), each of cross-sectional area 10 cm2 support the upper part of a human body of mass 40 kg. Estimate the average pressure sustained by the femurs. [2 × 105 Pa] 26. A 50 kg girl wearing high heel shoes balances on a single heel. The heel is circular with a diameter 1.0 cm. What is the pressure exerted by the heel on the horizontal floor? [6.24 MPa] 27. What is the pressure on a swimmer 10 m below the surface of a lake? [Nearly 2 atm] 28. The density of the atmosphere at sea level is 1.29 kg/m3. Assume that it does not change with altitude. Then how high would the atmosphere extend? [ 8 km] 29. The terminal velocity of a copper ball of radius 2.0 mm falling through a tank of oil is 6.5 cm s-1. Compute the viscosity of the oil. Density of oil is 1.5 ×103 kg m-3, density of copper is 8.9 × 103 kg m-3. [0.99 kg m-1 s-1] 30. What is the excess pressure inside the drop of mercury of radius 3.00 mm at room temperature? Surface tension of mercury at that temperature (20°C) is 0.465 N m–1. The atmospheric pressure is 1.01 × 105 Pa. [310 N m-2] THREE MARK QUESTIONS: 1. Derive an expression for gauge pressure inside a static fluid. 2. Derive the equation of continuity. What is the significance of the equation? 3. Obtain the expression for the terminal velocity of a small sphere falling through a fluid. 4. Derive the expression for excess pressure inside a drop. 5. At a depth of 1000 m in an ocean (a) What is the absolute pressure? (b) What is the gauge pressure? (c) Find force acting on the window of area 20 cm × 20 cm of a submarine at this depth, the interior of which is maintained at sea level atmospheric pressure. (Given: The Density of seawater is 1.03 × 103 kgm-3 and g = 10 ms-2) [(a) 104.01 × 105 Pa, (b) 103 × 105 Pa and (c) 4.12 × 105 N] 6. Two syringes of different cross-sections (without needles) filled with water are connected with a tightly fitted rubber tube filled with water. Diameters of the smaller piston and larger piston are 1.0 cm and 3.0 cm respectively. (a) Find the force exerted on the larger piston when a force of 10 N is applied to the smaller piston. (b) If the smaller piston is pushed in through 6.0 cm, how much does the larger piston move out? [90 N, 0.67 cm] 7. In a car-lift compressed air exerts a force F1 on a small piston having a radius of 5.0 cm. This pressure is transmitted to a second piston of radius 15 cm. If the mass of the car to be lifted is 1350 kg, calculate F1. What is the pressure necessary to accomplish this task? (g = 9.8 ms-2). [1.5 kN, 1.9 × 105 Pa] 8. A metal block of area 0.10 m2 is connected to a 0.010 kg mass via a string that passes over an ideal pulley (considered massless and frictionless), as in figure. A liquid with a film thickness of 0.30 mm is placed between the block and the table. When released the block moves to the right with a constant speed of 0.085 m s-1. Find the coefficient of viscosity of the liquid. [3.46 × 10-3 Pa s] 9. A U-tube contains water and methylated spirit separated by mercury. The mercury columns in the two arms are in level with 10.0 cm of water in one arm and 12.5 cm of spirit in the other. What is the relative density (also called specific gravity) of spirit? [0.8] 10. A U-shaped wire is dipped in a soap solution, and removed. The thin soap film formed between the wire and the light slider supports a weight of 1.5 × 10–2 N (which includes the small weight of the slider). The length of the slider is 30 cm. What is the surface tension of the film? [2.5 × 10-2 N m-1] FIVE MARK QUESTIONS: 1. State and prove Bernoulli’s principle. 2. What is capillarity? Arrive at the expression for capillary rise inside a capillary tube. 3. In a test experiment on a model aeroplane in a wind tunnel, the flow speeds on the upper and lower surfaces of the wing are 70 m s–1and 63 m s-1 respectively. What is the lift on the wing if its area is 2.5 m2? Take the density of air to be 1.3 kg m–3. [1.5 × 103 N] 4. The cylindrical tube of a spray pump has a cross-section of 8.0 cm2 one end of which has 40 fine holes each of diameter 1.0 mm. If the liquid flow inside the tube is 1.5 m min–1, what is the speed of ejection of the liquid through the holes? [0.637 m s-1] ANSWERS TO MULTIPLE CHOICE QUESTIONS: 1 2 3 4 5 6 7 8 D A C B A B C B 9 10 11 12 13 14 15 A C C B A C A ANSWERS TO FIBS: 1. surface tension; 2. viscosity; 3. turbulent; 4. dynamic lift; 5. hydraulic lift *********************************************************************************** 10. THERMAL PROPERTIES OF MATTER MULTIPLE CHOICE QUESTIONS: 1. Absolute zero (0 K) is that temperature at which (A) Matter ceases to exist (B) Ice melts and water freezes (C) Volume and pressure of a gas becomes zero (D) None of these 2. The temperature at which same value of measurement in Celsius and Fahrenheit scale is (A) 00 (B) 1000 (C) 400 (D) - 400 3. Relation between coefficient of linear expansion(αL), coefficient of area expansion(αA) and coefficien

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