The ratio of their respective momenta
⇒ \(\frac{P_1}{P_2}\) \(\bigg[P = \sqrt{ 2mKE}\bigg]\)
= \(\sqrt{ \frac{m_1}{m_2}}\)
= \(\sqrt{\frac{8}{2}} \; \; \; [mass = 8\;kg \;and\; 2\;kg]\)
= \(\frac{2}{1}\)
Therefore, the correct option is (B): \(\frac{2}{1}\)
If mass is written as \( m = k c^P G^{-1/2} h^{1/2} \), then the value of \( P \) will be:
Choose the correct answer from the options given below:
List – I | List – II |
---|---|
(a) Gravitational constant | (i) [L2T-2] |
(b) Gravitational potential energy | (ii) [M-1L3T-2] |
(c) Gravitational potential | (iii) [LT-2] |
(d) Gravitational intensity | (iv) [ML2T-2 |
The portion of the line \( 4x + 5y = 20 \) in the first quadrant is trisected by the lines \( L_1 \) and \( L_2 \) passing through the origin. The tangent of an angle between the lines \( L_1 \) and \( L_2 \) is:
The work which a body needs to do, against the force of gravity, in order to bring that body into a particular space is called Gravitational potential energy. The stored is the result of the gravitational attraction of the Earth for the object. The GPE of the massive ball of a demolition machine depends on two variables - the mass of the ball and the height to which it is raised. There is a direct relation between GPE and the mass of an object. More massive objects have greater GPE. Also, there is a direct relation between GPE and the height of an object. The higher that an object is elevated, the greater the GPE. The relationship is expressed in the following manner:
PEgrav = mass x g x height
PEgrav = m x g x h
Where,
m is the mass of the object,
h is the height of the object
g is the gravitational field strength (9.8 N/kg on Earth) - sometimes referred to as the acceleration of gravity.