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A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve?
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Problem: A stone is rotated in a vertical circle. Speed at bottommost point is √8gR, where R is the radius of the circle. The ratio of tension at the top and the bottom is:
Solution:
To solve this problem, we need to apply the laws of centripetal force, gravity, and tension. We assume that the stone is rotating in a vertical circle of radius R. The speed of the stone at the bottommost point is given as √8gR, where g is the acceleration due to gravity. The ratio of tension at the top and the bottom can be found as follows:
Step 1: Find the velocity of the stone at the topmost point
At the topmost point, the velocity of the stone is zero. We can use the conservation of energy principle to find the velocity of the stone at the topmost point. The total energy of the stone is given as:
E = mgh + 1/2mv^2
where m is the mass of the stone, h is the height of the topmost point, and v is the velocity of the stone at the topmost point.
At the bottommost point, the total energy of the stone is:
E = mgh + 1/2mv^2 = mgh + 1/2m(√8gR)^2 = mgh + 4mgR
Since the total energy of the stone is conserved, we can equate the energy at the topmost point to the energy at the bottommost point:
mgh = mgh + 4mgR + 1/2mv^2
Solving for v, we get:
v = √(2gR)
Step 2: Find the tension at the topmost point
At the topmost point, the tension in the string is equal to the weight of the stone minus the centripetal force required to keep the stone moving in a circle. The weight of the stone is given as:
W = mg
The centripetal force required to keep the stone moving in a circle of radius R is:
F = mv^2/R
Substituting the values of m and v, we get:
F = m(2gR)/R = 2mg
Therefore, the tension at the topmost point is:
T1 = mg - F = mg - 2mg = -mg (upward)
Step 3: Find the tension at the bottommost point
At the bottommost point, the tension in the string is equal to the weight of the stone plus the centripetal force required to keep the stone moving in a circle. The weight of the stone is given as:
W = mg
The centripetal force required to keep the stone moving in a circle of radius R is:
F = mv^2/R
Substituting the values of m and v, we get:
F = m(8gR)/R = 8mg
Therefore, the tension at the bottommost point is:
T2 = mg + F = mg + 8mg = 9mg (downward)
Step 4: Find the ratio of tension at the top and bottom
The ratio of tension at the top and bottom is:
T1/T2 = (-mg)/(
Solution:
To solve this problem, we need to apply the laws of centripetal force, gravity, and tension. We assume that the stone is rotating in a vertical circle of radius R. The speed of the stone at the bottommost point is given as √8gR, where g is the acceleration due to gravity. The ratio of tension at the top and the bottom can be found as follows:
Step 1: Find the velocity of the stone at the topmost point
At the topmost point, the velocity of the stone is zero. We can use the conservation of energy principle to find the velocity of the stone at the topmost point. The total energy of the stone is given as:
E = mgh + 1/2mv^2
where m is the mass of the stone, h is the height of the topmost point, and v is the velocity of the stone at the topmost point.
At the bottommost point, the total energy of the stone is:
E = mgh + 1/2mv^2 = mgh + 1/2m(√8gR)^2 = mgh + 4mgR
Since the total energy of the stone is conserved, we can equate the energy at the topmost point to the energy at the bottommost point:
mgh = mgh + 4mgR + 1/2mv^2
Solving for v, we get:
v = √(2gR)
Step 2: Find the tension at the topmost point
At the topmost point, the tension in the string is equal to the weight of the stone minus the centripetal force required to keep the stone moving in a circle. The weight of the stone is given as:
W = mg
The centripetal force required to keep the stone moving in a circle of radius R is:
F = mv^2/R
Substituting the values of m and v, we get:
F = m(2gR)/R = 2mg
Therefore, the tension at the topmost point is:
T1 = mg - F = mg - 2mg = -mg (upward)
Step 3: Find the tension at the bottommost point
At the bottommost point, the tension in the string is equal to the weight of the stone plus the centripetal force required to keep the stone moving in a circle. The weight of the stone is given as:
W = mg
The centripetal force required to keep the stone moving in a circle of radius R is:
F = mv^2/R
Substituting the values of m and v, we get:
F = m(8gR)/R = 8mg
Therefore, the tension at the bottommost point is:
T2 = mg + F = mg + 8mg = 9mg (downward)
Step 4: Find the ratio of tension at the top and bottom
The ratio of tension at the top and bottom is:
T1/T2 = (-mg)/(
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A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve?
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A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve? for Class 11 2024 is part of Class 11 preparation. The Question and answers have been prepared according to the Class 11 exam syllabus. Information about A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve? covers all topics & solutions for Class 11 2024 Exam. Find important definitions, questions, meanings, examples, exercises and tests below for A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve?.
A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve? for Class 11 2024 is part of Class 11 preparation. The Question and answers have been prepared according to the Class 11 exam syllabus. Information about A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve? covers all topics & solutions for Class 11 2024 Exam. Find important definitions, questions, meanings, examples, exercises and tests below for A stone is rotated in a vertical circle . Speed at bottommost point is √8gR, where R is the radius of circle. The ratio of tension at the top and the bottom isCorrect answer_ 1:3How to solve?.
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