The SI unit of force, the kilogram-meter per second squared (kg · m/s2)

The SI unit of force, the kilogram-meter per second squared (kg · m/s2), is called the newton (N). Find the dimensions and the SI units of the constant G in Newton’s law of gravitation F = Gm1m2/r2. (For the dimension use L for length, M for mass, and T for time. For the units use m for meters, kg for kilograms, and s for seconds.)

The Correct Answer and Explanation is :

To find the dimensions and SI units of the gravitational constant ( G ) in Newton’s law of gravitation, we start with the equation:

[
F = G \frac{m_1 m_2}{r^2}
]

where:

• ( F ) is the gravitational force (in newtons, ( N )),
• ( m_1 ) and ( m_2 ) are the masses of the two objects (in kilograms, ( kg )),
• ( r ) is the distance between the centers of the two masses (in meters, ( m )),
• ( G ) is the gravitational constant.

Step 1: Identify the units and dimensions of each component.

1. Force (( F )): The SI unit of force is the newton (N), which can be expressed in terms of base SI units:
   [
   1 \, N = 1 \, kg \cdot m/s^2
   ]
   Thus, the dimensions of force are:
   [
   [F] = [M][L][T^{-2}]
   ]
2. Mass (( m_1 ) and ( m_2 )): The unit of mass is kilograms (( kg )):
   [
   [m] = [M]
   ]
3. Distance (( r )): The unit of distance is meters (( m )):
   [
   [r] = [L]
   ]

Step 2: Substitute into the equation to solve for ( G ).

Rearranging the equation for ( G ):
[
G = \frac{F r^2}{m_1 m_2}
]

Step 3: Substitute the dimensions and units into this expression.

Using the units and dimensions we identified:
[
[G] = \frac{[M][L][T^{-2}] \cdot [L^2]}{[M]^2}
]
This simplifies to:
[
[G] = \frac{[M][L^3][T^{-2}]}{[M^2]} = [M^{-1}][L^3][T^{-2}]
]

Step 4: Find the SI units of ( G ).

Substituting the base units:
[
[G] = \frac{m^3}{kg \cdot s^2}
]

Conclusion

The dimensions of the gravitational constant ( G ) are:
[
[G] = [M^{-1}][L^3][T^{-2}]
]

The SI units of ( G ) are:
[
[G] = \frac{m^3}{kg \cdot s^2}
]

This shows how ( G ) relates the gravitational force to the masses and the distance between them, playing a critical role in our understanding of gravitation in physics. The dimensions of ( G ) reflect its role in measuring how mass and distance influence gravitational attraction, encapsulating fundamental properties of gravity in the universe.