A beta particle has an electric charge of -1 because beta particles are both lightweight and fast moving, they have a greater penetrating power than alpha particles.
The nucleus of an atom is not negatively charged. (Unless the atom is an antimatter atom).
A beta particle is essentially an electron. Electrons have a negative charge and as such, they are attracted to positively charged objects and fields.
A beta particle is an electron, and electrons are negative. You're probably thinking of a positron, which has the same mass as an electron but the opposite charge.
A Neutron is a particle that holds no charge. A Proton holds a positive charge, and an electron holds a negative charge.
A Beta- particle is an electron, which has negative charge.Here are some other types: Alpha is a helium nucleus, which is 2 protons and 2 neutrons (having positive charge). Positron is the antiparticle to electron. Positrons have positive charge. Gamma does not have charge. Neutrons do not have charge. Neutrinos do not have charge.
neutral charge. this is because a beta decay gains a proton and loses a neutron.
The difference between a beta plus and beta minus particle is the electrical charge. The charges are equal, but opposite. The beta minus particle is an electron with a negative charge, while the beta plus particle is an anti-electron or positron with a positive charge.
negative, -1 to be precise since a beta particle is an electron
Beta rays have negative electrical charge.
Beta Particles have a negative charge,In Beta decay a neutron changes into a proton and a beta particle, an electron.
A beta particle is an electron, and electrons are negative. You're probably thinking of a positron, which has the same mass as an electron but the opposite charge.
e- is the symbol for an electron, aka a beta particle. It has a unit negative charge.
beta particle
Neutrons are particles of no charge. Electrons have negative charge.
A beta particle is essentially an electron. Electrons have a negative charge and as such, they are attracted to positively charged objects and fields.
The sign of the charge depends if it's a beta-minus particle (an electron) or a beta-plus particle (a positron, or anti-electron). The former is negative, but the latter is positive. Generally, when we say "beta particle," we mean "beta-minus particle," but this is not always the case! For an element that decays via beta, check the locations on the Periodic Table (or better yet, the table of nuclides!) of the parent and daughter atoms. If the atomic number of a nucleus increased by one when undergoing beta decay (it now has an extra proton), it underwent beta-minus decay. If the atomic number decreased by one, it underwent beta-plus decay. Important note: we have just discussed the sign of the beta particle's charge, not the charge itself. The charge, in SI units, is 1.6022 x 10^-19 Coulombs. This quantity is, again, negative or positive depending on whether the particle in question is a beta-minus or beta-plus.
Beta particle electrons (as opposed to Beta particle positrons which have + charge)
The sign of the charge depends if it's a beta-minus particle (an electron) or a beta-plus particle (a positron, or anti-electron). The former is negative, but the latter is positive. Generally, when we say "beta particle," we mean "beta-minus particle," but this is not always the case! For an element that decays via beta, check the locations on the periodic table (or better yet, the table of nuclides!) of the parent and daughter atoms. If the atomic number of a nucleus increased by one when undergoing beta decay (it now has an extra proton), it underwent beta-minus decay. If the atomic number decreased by one, it underwent beta-plus decay. Important note: we have just discussed the sign of the beta particle's charge, not the charge itself. The charge, in SI units, is 1.6022 x 10^-19 Coulombs. This quantity is, again, negative or positive depending on whether the particle in question is a beta-minus or beta-plus.