Protons are composed of three smaller particles called quarks, each with their own mass and electric charge. These quarks contribute to the overall mass and charge of the proton. Due to the strong force that holds the quarks together within the proton, the combined mass and charge of all three quarks manifest as the consistent mass and electric charge that all protons share.
Quarks can actually vary greatly in size. The most common types of Quarks are Up and Down (scientists are not the most creative when it comes to names) and they have the mass of about 1/400 and 1/200 (respectfully) the mass of a proton. But some quarks, like the Top quark (another uncreative name) has the mass of the entire Tunston atom.
Quarks are fundamental particles inside protons. In the case of titanium, protons can contain a combination of up and down quarks which are the building blocks of protons. Scientists can study these quarks indirectly through high-energy scattering experiments.
Quarks are fundamental particles that are the building blocks of protons and neutrons, which make up the atomic nucleus. In the formation of particles, quarks combine together via strong nuclear force to form hadrons such as protons and neutrons. These combinations of quarks determine the properties of the resulting particles, such as their mass and charge.
Each proton and neutron is made up of three quarks.
Protons are composed of three smaller particles called quarks, each with their own mass and electric charge. These quarks contribute to the overall mass and charge of the proton. Due to the strong force that holds the quarks together within the proton, the combined mass and charge of all three quarks manifest as the consistent mass and electric charge that all protons share.
"There are six types of quarks, known as flavors: up, down, charm, strange, top, and bottom. Up and down quarks have the lowest mass of all quarks. The heavier quarks rapidly change into up and down quarks through a process of particle decay: the transformation from a higher mass state to a lower mass state. For this reason, up and down quarks are generally stable and the most common in the universe, whereas charm, strange, top, and bottom quarks can only be produced in high energy collisions (such as those involving cosmic rays and in particle accelerators)." -Copied word for word from wikipedia.
Because the electron is a lepton, and is not made of quarks.
Out of electrons, protons, and neutrons, neutrons are the heaviest subatomic particle, with a mass of about 1838 times that of the electron. (If you are asking about electrons, up quarks, and down quarks, then electrons still aren't the heaviest Down quarks are the heaviest, with almost 10 times the mass of an electron.)
Quarks have not been observed to exist separately - they are "confined" within larger particles such as protons and neutrons, that are made up of several quarks (3 each, in the case of protons and neutrons).
Neutrons are composed of three quarks, specifically one "up" quark and two "down" quarks. These quarks are held together by the strong nuclear force, which is mediated by particles called gluons. The combination of these quarks gives the neutron its properties, such as its mass and charge neutrality.
it melt faser in iastic cup Mass, quarks and leptons
The electron is the smallest subatomic particle in an atom and has almost no mass compared to the proton and neutron.
The mass of a proton primarily comes from the interactions between the quarks and the gluons that hold them together via the strong nuclear force, as described by Einstein's famous equation E=mc^2. The mass of a proton is not simply the sum of the masses of its constituent quarks due to the binding energy involved in holding the quarks together.
You think probable to proton and neutron.
No. Quarks can be described as "sizeless" because their mass is based on their energy, and even a proton's mass is not exactly equal to the mass of the constituent quarks (gluon mass is involved). The "volume" occupied by a quark (if it existed, uncombined) also varies by quark type.* An upper size limit has been proposed of about 1 x 10^-18 m, that is, less than one thousandth of the diameter of a proton.
it melt faser in iastic cup Mass, quarks and leptons