What is the work done by the force of gravity in the following cases?
$(a)$ $A$ satellite moving around the Earth in a circular orbit of radius $35000 \, km$.
$(b)$ $A$ stone of mass $250 \, g$ is thrown up to a height of $2.5 \, m$.
$(a)$ $A$ satellite moving around the Earth in a circular orbit of radius $35000 \, km$.
$(b)$ $A$ stone of mass $250 \, g$ is thrown up to a height of $2.5 \, m$.
(N/A) The work done is $0 \, J$. In a circular orbit,the force of gravity acts perpendicular to the direction of motion (displacement). Since the angle between force and displacement is $90^{\circ}$,the work done $W = F \cdot s \cdot \cos(90^{\circ}) = 0$.
$(b)$ Given: mass $m = 250 \, g = 0.25 \, kg$,height $h = 2.5 \, m$,acceleration due to gravity $g = 9.8 \, m/s^2$ (or $10 \, m/s^2$).
Since the stone is thrown upwards,the force of gravity acts downwards (opposite to displacement).
Work done $W = -mgh = -(0.25 \, kg) \times (9.8 \, m/s^2) \times (2.5 \, m) = -6.125 \, J$ (or $-6.25 \, J$ if $g = 10 \, m/s^2$ is used).
$(b)$ Given: mass $m = 250 \, g = 0.25 \, kg$,height $h = 2.5 \, m$,acceleration due to gravity $g = 9.8 \, m/s^2$ (or $10 \, m/s^2$).
Since the stone is thrown upwards,the force of gravity acts downwards (opposite to displacement).
Work done $W = -mgh = -(0.25 \, kg) \times (9.8 \, m/s^2) \times (2.5 \, m) = -6.125 \, J$ (or $-6.25 \, J$ if $g = 10 \, m/s^2$ is used).
Explore More
Similar Questions
Give the formula for calculating work done. What is the $SI$ unit of work?
Easy
View SolutionWhat are the factors on which the work done depends?
Easy
View Solution$(a)$ An arrow moves forward when released from a stretched bow. Explain the transformation of energy in the process.
$(b)$ $A$ boy of mass $50 \, kg$ climbs up a vertical height of $100 \, m$. Calculate the amount of potential energy he gains.
$(b)$ $A$ boy of mass $50 \, kg$ climbs up a vertical height of $100 \, m$. Calculate the amount of potential energy he gains.
Medium
View SolutionWhen the speed of a moving object is doubled,its:
Easy
View Solution$(i)$ State the law of conservation of energy.
$(ii)$ Show that the total mechanical energy of a freely falling body is conserved.
$(ii)$ Show that the total mechanical energy of a freely falling body is conserved.
Difficult
View SolutionVedclass Products
For Students
Vedclass Test Series
Mock tests in real JEE/NEET style with performance analysis. 5-day free trial.
Start Free TrialFor Teachers
Exam Paper Generator
Generate Set A/B/C/D exam papers from 7.5L+ questions in 2 minutes. 3 chapters free.
Try FreeFor Institutes
Online Exam Module
Live online exams with unlimited students, 360° analytics & white-label branding.
See Demo