There are many fission products, see the Wikipedia entry for 'Fission Product Yield'
The products of the reaction are solid strontium fluoride and solid silver chloride.
Uranium 235 has 143 neutrons; absorbing a neutron (neutron,gamma reaction) the isotope uranium-236 is obtained.
Yes, I know strontium iodate does.
Trick question, because Strontium and Sulfur DON'T react
Neither is. The uranium splitting is a fission reaction while the reaction between hydrochloric acid and sodium chloride is a chemical acid-base reaction.
The products of the reaction are solid strontium fluoride and solid silver chloride.
Uranium 235 has 143 neutrons; absorbing a neutron (neutron,gamma reaction) the isotope uranium-236 is obtained.
This characteristics is the possibility to be fissile when bombarded with neutrons and to maintain a chain reaction.
The products of this reaction are strontium chloride, carbon dioxide and water.
Yes, I know strontium iodate does.
I think that the effective cross section of the reaction (alpha, n) is not so great in this case.
Trick question, because Strontium and Sulfur DON'T react
Neither is. The uranium splitting is a fission reaction while the reaction between hydrochloric acid and sodium chloride is a chemical acid-base reaction.
SrBr2 + (NH4)2CO3 → SrCO3 + 2NH4Br Strontium Bromide + Ammonium Carbonate → Strontium Carbonate + Ammonium Bromide
The reaction forms hydrogen gas and strontium hydroxide. Sr + 2H2O --> H2 + Sr(OH)2
One large nucleus, typically uranium, undergoes fission and releases several neutrons along with the major fission products. These neutrons strike more uranium atoms and are absorbed by the nucleus causing it to become unstable. It undergoes fission releasing more neutrons and more fission products. These neutrons strike more uranium atoms etc.
Neutrons have no electric charge and have nearly 1,840 times the mass of the electron. Free neutrons undergo beta decay with a half-life of about 10 minutes. Thus, they are not readily found in nature, except in cosmic rays. They are a penetrating form of radiation. When bombarded with neutrons, various elements undergo nuclear fission and release more free neutrons. If enough free neutrons are produced, a chain reaction can be sustained.