well mass and energy are like two sides of a coin. According to Albert
Einstein's Mass Energy equation, mass can be converted to energy which is given by the equation E= M*C^2.
Mass is anything that has weight and occupies space whereas Energy is the ability to do work or to put matter into motion. (Delmar Cengage Learning)
The primary difference between momentum and kinetic energy is that momentum is a vector quantity that depends on an object's mass and velocity, while kinetic energy is a scalar quantity that depends only on an object's mass and speed.
Mass defect is the difference between the mass of an atomic nucleus and the sum of the masses of its individual protons and neutrons. This lost mass is converted into binding energy, which is the energy required to hold the nucleus together. The greater the mass defect, the greater the binding energy holding the nucleus together.
The difference is due to the binding energy that holds the nucleus together. When nucleons come together to form a nucleus, energy is released as the strong nuclear force overcomes the electromagnetic repulsion between protons. This released energy contributes to the mass of the nucleus through Einstein's mass-energy equivalence principle (E=mc^2), and accounts for the discrepancy between the individual nucleon masses and the actual mass of the nucleus.
Nuclear binding energy is the energy required to keep the nucleus of an atom intact. It is related to mass defect through Einstein's mass-energy equivalence E=mc^2. The mass defect represents the difference between the sum of the individual masses of the nucleons in an atom and the actual mass of the nucleus, which is converted into binding energy.
Binding energy is the energy required to hold a nucleus together, and it is equivalent to the mass defect, which is the difference between the mass of the nucleus and the sum of the masses of its individual protons and neutrons. This relationship is described by Einstein's famous equation E=mc^2, where the mass defect is converted into binding energy.
Momentum is the product of mass and velocity. Energy is the capacity of a body to do work.
The primary difference between momentum and kinetic energy is that momentum is a vector quantity that depends on an object's mass and velocity, while kinetic energy is a scalar quantity that depends only on an object's mass and speed.
E=mc2. Put both masses in there and find the difference.
If you add the exact mass of the protons, neutrons, and electrons in an atom you do not get the exact atomic mass of the isotope. The diference is called the mass defect. The difference between the mass of the atomic nucleus and the sum of the masses of the particles within the nucleus is known as the mass defect.
Di ko alam,May.
The mass of a nucleus is subtracted from the sum of the masses of its individual components.
Mass defect is associated with nuclear reactions and nuclear binding energy. It refers to the difference between the measured mass of an atomic nucleus and the sum of the masses of its individual protons and neutrons. This difference is released as energy when the nucleus is formed.
The term that describes the tiny difference in mass between the products and reactants of a nuclear change is "mass defect." This difference in mass is converted into energy according to Einstein's famous equation E=mc^2, which explains the principle behind nuclear reactions.
Physical energy is energy due to motion (kinetic energy) and/or energy due to position or configuration (potential energy). Nuclear energy is due to the destruction of mass.
There is a considerable mass difference, for example, between 4 hydrogen atoms, and 1 helium atom. Or between one U-235 atom, and the two daughter products, when it splits up. This mass difference is related to the binding energy between the nucleons.
Mass defect is the difference between the mass of an atomic nucleus and the sum of the masses of its individual protons and neutrons. This lost mass is converted into binding energy, which is the energy required to hold the nucleus together. The greater the mass defect, the greater the binding energy holding the nucleus together.
The difference is due to the binding energy that holds the nucleus together. When nucleons come together to form a nucleus, energy is released as the strong nuclear force overcomes the electromagnetic repulsion between protons. This released energy contributes to the mass of the nucleus through Einstein's mass-energy equivalence principle (E=mc^2), and accounts for the discrepancy between the individual nucleon masses and the actual mass of the nucleus.