A proton has a positive charge, a neutron has NO charge and an electron has a negative charge. All three are spin 1/2 particles and therefore fermions, however, protons and neutrons are each comprised of three elementary particles called quarks, making them baryons, whereas electrons aren't made out of any quarks, making them leptons. The lack of quarks in electrons mean they don't interact with the strong nuclear force, whereas protons and neutrons do. Additionally, protons and neutrons are much more massive, about 2000 times so, than electrons.
Protons: positive (+) charge, located inside of the nucleus
Neutrons: neutral (0) charge, located inside of the nucleus
Electrons: negative (-) charge, located outside of the nucleus
1) charge - protons have positive, electrons have negative
2) mass - protons are significantly heavier
3) size - protons are significantly larger
In "standard model" theory it is thought that protons are made of quarks, while electrons are truly indivisible.
In mass, protons and neutrons are approximately equal (with the neutron slightly heavier) and the electron significantly lighter. In electric charge, the electron is assigned -1, the proton the opposite charge of +1, and the neutron no charge or zero. In category, the neutron and proton are composite partlces -- hadrons and more specifically baryons, made up of three quarks, by contrast, electrons are categorized as leptons, considered elementary particles not made up of smaller particles. By role or position neutrons and protons are nucleons located in the nucleus in the center of the atom whereas electrons are in orbitals or energy levels outside the nucleus. Electrons also differ from neutrons and protons in that they do not interact strongly (the strong interaction of the fundamental interactions of physics). In terms of size, quantum theory describes electrons as dimensionless points or, as having no spatial extents; this makes them smaller than neutrons or protons which have a generally accepted nonzero radius, although this differs from classical theory and (some interpretations of quantum theory).
It is the atom of deuterium. Its nucleus is composed of a proton and one neutron. The atom has one electron that is orbiting around the nucleus.
Ion.
A hydrogen atom is only a proton and an electron. Beyond that the neutron seems to keep the nucleus together and stable. Maybe a better question is, "What is the difference between a hydrogen atom without an electron and a proton?"
no
This is called inverse beta decay and it forms a neutron. Normally a neutron will decay into a proton and electron, but the opposite will happen given enough energy. Coincidentally, this is how neutron stars are formed (the immense pressure from gravity overcomes the force separating protons and electrons.)
This is valid only for the attraction between a proton and an electron.
Neutron, proton, electron.Neutron, proton, electron.Neutron, proton, electron.Neutron, proton, electron.
The main differences are proton and neutron are in the nucleus, electrons are outside of the nucleus. The weight of an electron is between a hundred and a thousand times less of that of a proton and neutron and the charge on a proton is positive, neutron is neutral and electron is negative
an electron is much lighter than a proton or neutron.
Subatomic particles are: neutron, proton, electron.
Mass ratio proton (neutron)/electron: 1 836
Mass ratio proton (neutron)/electron: 1 836
Mass ratio proton (neutron)/electron: 1 836
If a proton would be 1, an electron would be 0.000544. An electron is 1,836 times lighter than a proton. A neutron would be 1.001 as a proton is 99.86% the mass of a neutron
Mg+2 and Br-1
The electron is the smallest having about 1/1836th the mass of a proton or neutron, which means that basically an electron has no mass. The neutron and proton weigh the same both having a mass of 1.
5, electron, proton, neutron, nucleus, and electron cloud.