no beacause it is negative
Depends on what type of radioactive decay you are talking about. Beta decay (electron or positron) will have a charge, while alpha decay will not. Beta decay can either be positron decay or electron decay. Positron will result in the parent to have the same atomic mass but a different atomic number. The atomic number will be one less than that of the parent. Meaning one proton will decay into a neutron and a positron, which is a positively charged particle. Electron decay results in the parent gaining a proton while the atomic mass stays the same. A neutron decays into a proton and an electron and the electron is emitted with a negative charge. Alpha decay, however, results in the emission of a neutral helium particle. Gamma decay results in the same parent with no loss of charge or atomic number and gives off a high energy photon called a gamma particle.
There are two types of beta decay, and they are beta plus (beta +) decay and beta minus (beta -) decay. A post already exists on beta decay, and a link to that related question can be found below.
alpha: mass 4, charge +2beta: mass ~1/1800, charge -1gamma: mass 0, charge 0
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.
If an electron is released from the nucleus (and not from an electron shell) then it would have been emitted by a neutron in beta decay. In beta-minus decay, a neutral neutron emits an electron and an anti-neutrino and becomes a proton; in beta-plus decay, a proton emits a positron and a neutrino and becomes a neutron.
Energy and electrical charge are two quantities that are always conserved in nuclear decay equation.
Total charge is always conserved. If an electron is emitted, the remaining particle's charge will change by +1. If a positron is emitted, the remaining particle's charge will change by -1.
The number of neutrons is not conserved during decay.
Beta Particles have a negative charge,In Beta decay a neutron changes into a proton and a beta particle, an electron.
It is called beta decay. there are two types: 1) posive beta decay in which atomic number decreases. 2) negative beta decay in which atomic number increases.
There are 4 different types of decay, the first is alpha decay this releases a helium nucleus ( 2 protons and 2 neutrons) the second is a beta particle also known as an electron. The third is beta minus decay which is a positron, it is the same as an electron in every way except it has a positive charge where as an electron has a negative charge. The last is gamma decay, which releases a gamma ray, this is a type of electromagnetic wave.
Depends on what type of radioactive decay you are talking about. Beta decay (electron or positron) will have a charge, while alpha decay will not. Beta decay can either be positron decay or electron decay. Positron will result in the parent to have the same atomic mass but a different atomic number. The atomic number will be one less than that of the parent. Meaning one proton will decay into a neutron and a positron, which is a positively charged particle. Electron decay results in the parent gaining a proton while the atomic mass stays the same. A neutron decays into a proton and an electron and the electron is emitted with a negative charge. Alpha decay, however, results in the emission of a neutral helium particle. Gamma decay results in the same parent with no loss of charge or atomic number and gives off a high energy photon called a gamma particle.
One particle can turn into another particle or several other particles (particles decay, for example, much like radioactive nuclei) but electric charge is neither created nor destroyed, so no matter what happens to subatomic particles, the end result will have exactly the same amount of electric charge as there was originally. This principle is officially known as conservation of electric charge.
Beta particles, from beta- decay, have a charge of -1. Beta particles, from beta+ decay, have a charge of +1. Alpha particles have a charge of +2.
There are two types of beta decay, and they are beta plus (beta +) decay and beta minus (beta -) decay. A post already exists on beta decay, and a link to that related question can be found below.
In gamma decay ,nucleus lose a charge of -1 and the daughter nucleus has charge of Z+1.
An electron during beta decay.