Gravitation

i. During the free-fall motion of a body, the gravity is the only force acting upon the object.

ii. The motion of a free falling body is non-uniform because it experiences an acceleration of 9.81 ms^-2 under the influence of gravity.

Hence it’s motion is uniformly accelerated.

The value of the universal gravitational constant in 1947 was the same as that of now.
G=6.673×10^-11 N m² kg^-2

False
Earth exerts the force of attraction on apple equal to the force apple exerts on the earth.

The moon’s gravity is 1/6th of the gravity on earth. It is not strong enough to hold the atmosphere on its surface from going back to space.

weight

Weight and it is equal to the product of mass(m) and acceleration due to gravity(g).

W = m×g
More explanation is given in this diagram.

(a) According to Newton’s law of gravitation:
(i)the force between two objects is directly proportional to the product of their masses and,
(ii)the force between two objects is inversely proportional to the square of the distance between them.

Suppose two objects of masses M₁ and M₂ are kept at a distance “d”, then the force between the two object is given as:

(b) The Newton’s law of gravitation is applicable to all types of bodies- big or small, terrestrial or celestial. So, it is called the universal law.

Given,
mass of electron(m_e)= 9.1 × 10^-31 kg
distance between them(r)= 10 Å=10 × 10^-10 m
G=6.673 × 10^-11 N m² kg^-2
The gravitational force between them(F_g) is given by,

Given, weight on earth(W)=600 N
g= 10 ms^-2
Let the mass on earth be m.
As we know,
Weight=mass×acceleration due to gravity at that place
W=mg

Given,
Weight on the moon(W’)=100 N
Mass(m)=60 kg
Let the acceleration due to gravity on the moon be g’.
Weight =mass x acceleration due to gravity at that place

From second law of motion, the force on a body is the product of its mass and acceleration.
Let the mass of body be m.

The acceleration of falling objects due to the gravitational force of earth is equal to the acceleration due to gravity(g).
Thus, force(F) on the falling objects is given by,
F=mg
This force is equal to the gravitational force between the body and earth.
where, G=Universal Gravitational constant
M=mass of earth
m=mass of body
r=distance between the body and the centre of earththe
As both forces are equal,
which is independent of mass(m) of body.

From Newton’s law of gravitation, the gravitational force between two bodies is directly proportional to the product of their masses.

As the masses of earth and sun are very large as compared to the mass of me and my friend, the gravitational force between them is much greater than between me and my friend.

The mass of a body is a measure of its inertia. It is independent of the acceleration due to gravity at a place.
The weight of a body is the force with which it is attracted to the earth. It is directly proportional to the acceleration due to gravity. Thus, we feel heavier on earth than the moon.
We experience weightlessness during free fall because we have no support to feel our weight.

(a) Given,
mass of book(m)=400 g=0.4 kg
Let the radius of the earth be R.
height of book=R
the distance of book from the centre of the earth(d)=radius of earth + height of book=R+R=2R
The acceleration due to gravity at the surface of the earth(g) is given by,
The acceleration due to gravity at such height(g’) is given by,

Weight(W’)=mg’=0.4×2.45=0.98 N

(b) Weight is the force with which a body is attracted towards the center of the earth. It is directly proportional to the acceleration due to gravity. It is given by, Weight=mass × acceleration due to gravity

Given,
time taken=0.5 second
g=10 ms^-2
As the car is under free fall, the initial speed is zero.
u=0
(a)Under free fall,
u=0, a=g
v=u+a×t
v=0+10×0.5
v=5 ms^-1

(b)

(c)From Newton’s equation of motion,
As u=0,

Where h is the height,
t is the time of free fall,
g is the acceleration due to gravity.
Putting the values in the above equation, we get

Whenever an object falls under the effect of gravitational force towards the earth, it is said to be under free fall.

The direction of motion of the object does not change during free fall. But due to the acceleration due to gravity, the velocity of object changes.

The equations of motion are:
v=u+at
v²=u²+2as
Under free fall, u=0,
a=acceleration due to gravity=g,
s=height of fall=h
Thus under free fall, the equations become
v=gt
v²=2gh

Given,
time taken to reach top(t)=5s
As the object is thrown up, final velocity is zero. (v=0)
The acceleration due to gravity will be negative as the direction of motion is opposite to the direction of gravity.
Using equation of motion,
v=u+gt
⇒u=v-gt
Putting the values,
u=0-(-10)(5)
⇒u=50 ms^-1

(a) I would do the same Raju has done. I would ask the vendor to change the balance and check if it is done by mistake. If the vendor does not agree, I shall complain about him to the concerned authorities.
(b) Raju shows values like observant, scientific temper.
(c) The weight of balance should be checked before buying a substance to ensure if we are not paying more for a lesser quantity.