Sounds like witchcraft (jk), any good source that explains this in more detail? I hate to rely only on Wikipedia. It makes sense that the mass of an atom can be more than the sum of its constituents due to binding energy, but being less sounds like there's some hidden field holding the remainder.Vanadium 50 said:The mass of a helium nucleus is less than the mass of two protons plus two neutrons. That's a fact. How you want to partition this difference is personal taste.
So then is it accurate to say nuclear fission of lighter elements (if even possible) would renergize the nucleons when freed?mfb said:Nuclear binding energy is negative. Energy is released when you form a helium nucleus.
Same for binding electrons: a neutral hydrogen atom has a mass slightly below the sum of masses of proton plus electron.
stoomart said:So then is it accurate to say nuclear fission of lighter elements (if even possible) would renergize the nucleons when freed?
Correct.Sentosa said:Does the helium atom have less energy, which causes it to have less mass?
No it does not. "Mass" is defined in the rest frame of the object. The concept of a relativistic mass (which depends on speed) is not used any more.Sentosa said:I know that as an object speeds up, it weighs more because it has more energy.
But why? Why can't we speak about the relativistic mass?mfb said:Correct.
The difference is the nuclear binding energy.No it does not. "Mass" is defined in the rest frame of the object. The concept of a relativistic mass (which depends on speed) is not used any more.
Oh yeah I get it.mfb said:We can, but it just leads to misconceptions, and there is no point in it - we have energy already, which is the same thing apart from a constant factor. Using relativistic mass is like using kilometers and miles in the same calculation for no reason.
Correct.Thejas15101998 said:So its like in helium we have more binding energy than that in two deuterium.
I guess so.Thejas15101998 said:So micho kaku just divides this total mass among the protons
The mass of an H proton (hydrogen atom) is approximately 1.007 atomic mass units (amu), while the mass of an He proton (helium atom) is approximately 4.003 amu. This means that an He proton is about 4 times heavier than an H proton.
The difference in mass between an H proton and an He proton is due to the number of subatomic particles they each contain. An H proton contains only one proton, while an He proton contains two protons and two neutrons, making it heavier.
The weight of a proton does not affect its properties, as the properties of a proton are determined by its charge and other fundamental characteristics, rather than its mass.
No, an H proton and an He proton cannot be used interchangeably in experiments. The difference in mass between the two protons can affect the outcome of experiments, particularly in fields such as nuclear physics and astrophysics.
The weight of a proton is typically measured in atomic mass units (amu) using a mass spectrometer. This device separates particles based on their mass-to-charge ratio, allowing for the precise measurement of the weight of a proton.