The two properties that determine the force of gravity between two objects are the product of the masses (mM) and the square of the distance between the masses,r: F= GmM/r^2
According to the law of universal gravitation, the attractive force (F) between two bodies is proportional to the product of their masses (m1 and m2), and inversely proportional to the square of the distance, r, (inverse-square law) between them. The constant of proportionality, G, is the gravitational constant. G = 6.674 x 10-11 N(m/kg)2 F = G(m1)(m2)/r2
The moe mass and the closer the object, the greater the Gravitational Potential E= -GmM/r energy and Force F=GmM/r^2.
Force is the cause of movement. Electrons can be moved by gravitational force F= GmM/r^2 and electric force produced by the Electromagnetic fields, F=eE and F= evB= e(-v.B + vxB).
Yes, work= -GmM/R This work is energy that is stored in the gravitational field of the two masses and is called the gravitational potential energy of the two masses when they are separated by a distance R: Ep= -GMm/R
The force F= GmM/r^2.Newtons or N. for short
The gravitational force in form of vectors is the Gradient of the Gravitational Potential Energy -GmM/r: F= Del -GmM/r = Del -mu/r = mu/r^2 (R/r )= muR/r^3 = mw^2R where 'R' is the radial vector.
Both! Force is a quaternion quantity, the sum of a scalar force and a vector force. For example there are two gravitational forces, the scalar force Fs= - GmM d/dr 1/r = GmM/r^2 and the vector force Fv= Del -GmM/r = GmM R/r^3.
The two properties that determine the force of gravity between two objects are the product of the masses (mM) and the square of the distance between the masses,r: F= GmM/r^2
F = GMm/R² where * F is the force of attraction between two objects * G is the universal gravitational constant; G = 6.67*10-11 N-m²/kg². The units of G can be stated as Newton meter-squared per kilogram-squared or Newton square meter per square kilogram. * M and m are the masses of the two objects * R is the distance between the objects, as measured from their centers * GMm/R² is G times M times m divided by R-squared this is newtons gravity equation, it is not as accurate as einsteins but in this case it should do the trick. there is more on this website: http://www.school-for-champions.com/science/gravity_universal_equation.htm
F = GMm/R² where * F is the force of attraction between two objects * G is the universal gravitational constant; G = 6.67*10-11 N-m²/kg². The units of G can be stated as Newton meter-squared per kilogram-squared or Newton square meter per square kilogram. * M and m are the masses of the two objects * R is the distance between the objects, as measured from their centers * GMm/R² is G times M times m divided by R-squared this is newtons gravity equation, it is not as accurate as einsteins but in this case it should do the trick. there is more on this website: http://www.school-for-champions.com/science/gravity_universal_equation.htm
According to the law of universal gravitation, the attractive force (F) between two bodies is proportional to the product of their masses (m1 and m2), and inversely proportional to the square of the distance, r, (inverse-square law) between them. The constant of proportionality, G, is the gravitational constant. G = 6.674 x 10-11 N(m/kg)2 F = G(m1)(m2)/r2
The moe mass and the closer the object, the greater the Gravitational Potential E= -GmM/r energy and Force F=GmM/r^2.
Force is the cause of movement. Electrons can be moved by gravitational force F= GmM/r^2 and electric force produced by the Electromagnetic fields, F=eE and F= evB= e(-v.B + vxB).
I think this is Newton's Law of Gravitation, F = GmM/R2. G is a numerical constant(6.67E-11), and has no dimension.
Yes, work= -GmM/R This work is energy that is stored in the gravitational field of the two masses and is called the gravitational potential energy of the two masses when they are separated by a distance R: Ep= -GMm/R
The equation is F = GmM/r2 whereF is the force of gravity, G is the universal gravitational constant, m and M are the two masses, and r is the distance between the masses.