daveb said:You'd still have protons, electrons, neutrinos, pions, etc., so matter would still have different properties. The rest of your post makes no sense. What diffuses through space? What do you mean by anchors?
elroyjetsn said:Diffuses through space- Without inertia to give it momentum or directionality, it would just generate space. That would explain how radio waves travel through the "vacuum" of space. Electrons and protons are there but without neutrons, they don't interact with regular matter and seem invisible to us.
Anchors- Neutrons give atoms relativity? and enable them to react and interact as electrons and protons are shared according to quantum physics. The subatomic particles indicate that there is complexity in the design of protons, neutrons, etc.
Wayne
Janus said:Where did you get the notion that only neutrons are responsible for inertia and momentum? This is patently false. For instance, the majority of hydrogen atoms consist of just a proton and electron with no neutron present, yet they still have momentum and inertia.
elroyjetsn said:I suppose that's my question then. The relationship between neutron and mass and momentum. Does hydrogen behave the same as matter with neutrons? I'm just exploring ideas. How does the presence of neutrons change things for an atom?
daveb said:Protons are about 938 MeV and neutrons about 940 MeV, and since for A number > 20 an atoms needs more neutrons than protons, yes, neutrons do provide most of the mass - they just don't provide all of it.
daveb said:Perhaps you might want to look at this site first. Protons and electrons interact all the time without neutrons - that's what hydrogen is (1 proton, 1 electron, no neutron). And miost of the universe is made of hydrogen.
Inertia is a property of matter, not just neutrons. Protons and electrons have inertia whether or not there's a neutron around to "anchor" them (and neutrons' normal interaction with electrons is via ionization of atoms when some neutron flux interacts with matter. As for neutrons giving atoms relativity, this also makes no sense.
elroyjetsn said:I should say that neutrons give the greatest portion of mass to an atom. Don't know the percentage breakdown though.
BTW, If you threw a hydrogen atom and a lead atom, the lead atom would no doubt carry further so "patently false" needs more explanation. :)
Matterless neutrons, also known as virtual neutrons, behave similarly to regular neutrons in terms of their interaction with other particles. This is because they still carry the same properties and obey the same laws of physics, despite not having any mass.
Yes, matterless neutrons still have inertia. Inertia is a property of matter that describes its resistance to changes in motion. While matterless neutrons do not have mass, they still have energy and momentum, which contribute to their inertia.
Matterless neutrons play an important role in quantum field theory, where they are used to describe the interactions between particles. They also help to explain certain phenomena, such as the strong force that holds atomic nuclei together.
No, matterless neutrons cannot be directly observed or measured. They are considered virtual particles, which means they can only exist for a very short period of time and cannot be detected by traditional means.
Matterless neutrons are unique in that they are the only particles that have no mass but still have inertia. Other virtual particles, such as virtual photons or virtual electrons, do not have this property. Additionally, matterless neutrons only interact with the strong nuclear force, while other virtual particles can interact with multiple forces.