Ep=mgh, m is mass, g is gravity (9.81m/s2) and h is height
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
The equation for potential energy is P.E.=mass*gravitation*height Over here gravitation is constant cos the questions will be related to the earth So g=10 or 9.8 Pe=mgh
No. The equation for potential energy is PE = m•g•h, where m is mass in kg, gis 9.8m/s2, and h is height in meters. Potential energy is the energy an object has due to its position. Velocity is not a factor in determining potential energy.
Potential energy is the energy of location. Gravitational potential energy is given by lifting an object, and is defined by the equation Ep = mgh, or mass * acceleration due to gravity * height.
It is internal energy that drives atoms or molecules in a random manner
potential energy+kinetic energy=mechanical energy
Potential energy = mass x gravitational acceleration x height
EP = -mGM/r
ATP
work=force x output
Does speed 'effect' the gravitational potential energy of an object? No, but gravitational potential energy can be converted into kinetic energy - so the gravitational potential energy can effect the speed. Ep = mgh Energy Potential = mass * 9.81 (gravity) * height Speed / Velocity is absent from that equation.
The equation for potential energy is P.E.=mass*gravitation*height Over here gravitation is constant cos the questions will be related to the earth So g=10 or 9.8 Pe=mgh
It's:P= Fd/t
Yes, as this equation makes it possible E=mc^2 . ------------> mass energy is different from potential energy An object has kinetic and potential energy (such as a falling apple) because commonly kinetic energy is converted to potential energy and vice versa due to conservation of energy. The sum of kinetic and potential energy needs to be taken for the total energy of the object.
No. The equation for potential energy is PE = m•g•h, where m is mass in kg, gis 9.8m/s2, and h is height in meters. Potential energy is the energy an object has due to its position. Velocity is not a factor in determining potential energy.
Potential energy is the energy of location. Gravitational potential energy is given by lifting an object, and is defined by the equation Ep = mgh, or mass * acceleration due to gravity * height.
Anything that moves is using kinetic energy, so I'll let you answer that one yourself. Potential energy is a bit more abstract, so here's some of it's uses: - Batteries (electric potential energy) - Mass (potential energy in relativistic 4-space, hence E = m*c2) - The Schrödinger equation and Hamiltonian operator in quantum mechanics (the Hamiltonian is Kinetic Energy + Potential Energy = Total Energy, used to derive the time-dependent Schrödinger equation). - Enthalpy and the laws of thermodynamics.