The Energy required o form a nucleus from its parts
The amount of mass used up in holding a nucleus together
Mass defect is... the difference between the mass of an isotope and it's mass number.
To help that one skeptical person
The energy required to form a nucleus from its parts.
This is also the correct answer on apex
The amount of mass missing from a nucleus when compared with the sum of its parts
Mass defect refers to amount by which the mass of an atomic nucleus is less than the sum of the masses of its constituent particles.
The amount of mass missing from a nucleus when compared with the sum of its parts.
-APEX
The mass defect law defines the difference between the mass of an atom and the sum of the masses of the protons and neutrons in the nucleus. The difference is expressed in Atomic Mass units.
The unit of mass defect is a.m.u and 1 a.m.u. = 931.5 MeV = 931.5 X 106 eV
mass defect is the energy that binds the protons and neytrons together in the neycleus.
it is the difference between nuclear mass and the mass of its components
Mass is converted to the energy binding a nucleus together
nuclear fusion
The mass defect represents the mass converted to binding energy
m=0.009106u
mass defect
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.
Nuclear binding energy is the energy required to hold the nucleus together. The mass defect is the difference between the mass of a nucleus and the sum of the masses of its individual protons and neutrons. The mass defect is converted into nuclear binding energy according to Einstein's famous equation, E=mc^2, where E is the energy, m is the mass defect, and c is the speed of light.
Mass is converted to the energy binding a nucleus together
nuclear fusion
E = MC2; energy is equal to a quantity of matter. When protons (and neutrons) combine in an atomic nucleus, the resultant mass is less than that of the individual particles. This is the mass defect, and the 'missing' mass is a result of the energy binding the particles together. The larger the mass defect for a particular atom (isotope), the larger the amount of nuclear binding energy.
The binding energy is the mass defect, times the square of the speed of light.The amount stated seems to be an awfully high mass defect, though.
The mass defect represents the mass converted to binding energy
The mass of a nucleus is subtracted from the sum of the masses of its individual components.
It allows you to calculate the corresponding energy.
If you really meant to ask "What is the mass defect of oxygen-16," this is how you do it. mass defect = # of protons x mass of one proton + # of neutrons x mass of one neutron - mass of the nucleus The atomic number of oxygen-16 is 8, so there are 8 protons. The mass of one proton is approximately 1.0073 amu. The Atomic Mass of oxygen-16 is 16, so there are 8 neutrons in oxygen-16. (Atomic mass of 16 minus atomic number of 8 = # of neutrons in oxygen-16.) The mass of one neutron is approximately 1.0087 amu. The mass of the nucleus of oxygen is 16. Now substitute the values into the "mass defect" equation: mass defect = 8x1.0073+8x1.0087-16=approximately 0.128 amu.
mass defect
m=0.009106u