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∙ 6y agoThe balanced nuclear equation for the beta decay of potassium-42 is: ^42K -> ^42Ca + e^- + νe
The equation for the beta decay of 17F: 917F --> 817O+ 10e + ve where the 10e is a positive beta particle or positron.
The nuclear equation for the beta decay of Sn-126 is: Sn-126 -> Sb-126 + e- + anti-neutrino
To write a balanced nuclear equation for the formation of polonium-206 through alpha decay, start with the parent nucleus, which is radium-210. Radium-210 undergoes alpha decay, emitting an alpha particle (helium nucleus) to form polonium-206 and an additional particle (usually a neutrino). The balanced nuclear equation for this process would be: (^{210}{88}Ra \rightarrow ^{206}{84}Po + ^4_{2}He).
The equation for the beta decay of 3H is: 13H --> 23He + -10e where -10e represents a negative beta particle or electron.
Boron-10 (^10B) undergoing neutron capture forms boron-11 (^11B), followed by the emission of an alpha particle (helium-4 atom). The balanced nuclear equation would be: ^10B + n → ^11B + ^4He
Po-216- -----------------> Pb-212
For nuclear decay, you must also specify what isotope you are talking about. Just saying "Sulfur" simply isn't enough information.
All nuclear decay is spontaneous.
The balanced nuclear equation for the beta decay of zirconium-97 (97Zr) is: 97Zr -> 97Nb + e-, where e- represents a beta particle (electron), and 97Nb is the resulting nuclide, niobium-97.
The nuclear decay equation for Po-208 is: Po-208 → Pb-204 + He-4
The balanced nuclear equation for the alpha decay of thorium-230 is: ^230Th → ^226Ra + ^4He
Natural chromium is stable and does not decay/
Energy and electrical charge are two quantities that are always conserved in nuclear decay equation.
The decay equation is:Co-60----------------------Ni-60 + e-
224
The equation for the beta decay of 17F: 917F --> 817O+ 10e + ve where the 10e is a positive beta particle or positron.
The equation for the beta decay of 14C: 614C --> 714N + -10e where the e is an electron.