No!
If the radioisotope loses a neutron, then it will produce another isotope of the same element. However, if it loses an alpha particle or a positron, the result is a different element.
No, when a radioisotope decays, it can produce different isotopes of the same element or even different elements altogether, depending on the type of decay it undergoes. Some decay processes can result in the production of isotopes of the same element, while others can lead to the formation of entirely different elements through nuclear transmutation.
It depends on what type of rays it gives off. If it gives off Alpha ray which has two protons and two neutrons, it will change to another element with 2 less atomic number. Beta would also do the same but Gamma won't.
In a single replacement reaction, one element replaces another in a compound. This typically produces a new compound and a different element.
When elements are combined to produce another element, this process is called nuclear fusion. Nuclear fusion is the process in which two lighter atomic nuclei combine to form a heavier nucleus, releasing a large amount of energy in the process. This is the process that powers the sun and other stars.
Substances can become a different element after radioactive decay due to the transformation of the atomic nucleus. This process can result in the emission of alpha or beta particles, leading to a change in atomic number and producing a new element.
The combination of the nuclei of atoms to produce a heavier element is called nuclear fusion. This process releases a large amount of energy and is the main source of power in stars like our sun.
Yes, radioactive elements emit radiation all the time as they decay and release energy in the form of particles or electromagnetic waves. The rate at which radiation is emitted depends on the half-life of the radioactive element.
1. The isotope 238Pu: a power o,5 W for 1g. 2. For the nuclear fuels containing plutonium: this is another problem !
The element with 3 protons is lithium (Li). With 4 neutrons, it forms lithium-7, a stable isotope. Having 3 electrons, it is neutral and forms an ionic compound or molecule in its various chemical reactions.
In a single replacement reaction, one element replaces another in a compound. This typically produces a new compound and a different element.
When elements are combined to produce another element, this process is called nuclear fusion. Nuclear fusion is the process in which two lighter atomic nuclei combine to form a heavier nucleus, releasing a large amount of energy in the process. This is the process that powers the sun and other stars.
Plants produce oxygen (O2).
Substances can become a different element after radioactive decay due to the transformation of the atomic nucleus. This process can result in the emission of alpha or beta particles, leading to a change in atomic number and producing a new element.
Not normally.
CO2
A chemical reaction took place creating a new element.
Scandium is used to make high intensity lamps. Scandium iodide is added to mercury vapor lamps to produce a light source with a color resembling sunlight. The radioactive isotope Sc-46 is used as a tracer in refinery crackers for crude oil.
First of all, you must not distinguish elements, but rather isotopes (or nuclides) . As an example, in their chemical properties, carbon 12 and carbon 14 may be almost the same; or uranium 235 and uranium 238 may be almost the same, but in their nuclear reactions, they are completely different things.Therefore, of course it's quite possible that different isotopes of the same element decay in different ways - since they are basically unrelated to one another, for the purpose of nuclear reactions. However, the same isotope or nuclide may, in some cases, randomly decay in different ways. Finally, both when alpha particles are emitted, energy in form of gamma rays is usually also emitted, as a by-product so to speak.
Most nuclear power plants use uranium as the primary element to produce nuclear energy through a process called nuclear fission. Uranium-235 is the most commonly used isotope for this purpose due to its ability to readily undergo fission reactions when bombarded with neutrons.