The dimension of mass is always [M].
what is dimnsion of gravitational constant
The dimensions are [L^3 M^-1 T ^-2].
They are [L^3]*M^-1][T^-2].
Cavendish measured the gravitational constant "G".
The gravitational constant was found by Newton, not Einstein.
what is dimnsion of gravitational constant
The quantity called the Gravitational constant (G) has the following dimension: [G] = L3T-2M-1 The mass exponent is "negative" ... but watch out, it only means that mass is on the denominator ... i.e. [G] = L3 / T2M
Weight = Mass x (Local Gravitational Constant)/(Standard Gravitational COnstant)
The dimensions are [L^3 M^-1 T ^-2].
They are [L^3]*M^-1][T^-2].
The mass of the Earth can be determined by the gravitational force it exerts on any object. This works, once the gravitational constant is known. The gravitational constant can be measured with a Cavendish balance.
No. Gravitational Acceleration is a constant and is a function of mass. The effects of the constant upon another mass can be altered but the acceleration itself will remain the same.
Because the mass is not dependent on the gravitational influence.
Force gravitational = (mass of the object)(the gravitational constant) F=mg "g" is the gravitational constant, it is equal to 9.8 m/s^2
The gravitational force is equal to mass1 x mass2 / (the square of the distance); all this must be multiplied with a constant, known as the gravitational constant.
It is F= (mass of one object)(mass of second object)(Gravitational constant)/(the distance between them)2 The gravitational constant is about 6.67x10-11 The mass should be in kg, and the distance in meters
Basically it is the object's "weight". The gravitational force on an object is its Mass X Gravitational Constant. The gravitational constant is the acceleration of a free falling body towards another body, and on Earth is equal to 9.81 meters/sec2 or 32.2 feet/sec2. Thus while the MASS of an object is a constant physical property, the WEIGHT of an object depends on the local gravity field pulling on that MASS.