The oxidation state is zero.
It is always found in the oxidation state of 0
The oxidation state of Cl in ClO2 is +3. This is determined by assigning oxygen an oxidation state of -2 and knowing that the overall charge of the compound is 0. Since there are two oxygen atoms with an oxidation state of -2 each, the oxidation state of Cl must be +3 to balance it out.
Xenon is a noble gas and typically has an oxidation state of 0 in its elemental form. However, xenon can form compounds where it exhibits positive oxidation states such as +2, +4, +6, or +8.
Zero(0) for elemental nitrogen. However, nitrogen exhibits various oxidation numbers when combined with other elements, to form compounds. The oxidation number is the number of electrons in the valence shell directly involved in the combination with another element. e.g. N2O = Oxid'n No. 1 (Nitrous oxide ' Laughing Gas'). NO = Oxidation No. 2 (Nitrogen monoxide) NO2 = Oxid'n No. 4 (Nitrogen dioxide) HNO3 = Oxidation No. 5 . (Nitric Acid) HNO2 = Oxid'n No. 3 ( Nitrous Acid). NB THere may be electrons in the valence shell not directly combining in a compound/reaction, known as 'lone pairs'. NB Phosphorus, which is in the same Group(V) as nitrogen also exhibits variable oxidation states.,
The oxidation number of N in NO2 is +4. Each oxygen atom has an oxidation number of -2, so the sum of the oxidation numbers in NO2 must equal the overall charge of the molecule, which is 0. This means that the oxidation number of N must be +4 to balance the -4 oxidation contributed by the two oxygen atoms.
the oxidation states are always 0 for both atoms
the oxidation states are always 0 for both atoms
It is always found in the oxidation state of 0
The oxidation state of Cl in ClO2 is +3. This is determined by assigning oxygen an oxidation state of -2 and knowing that the overall charge of the compound is 0. Since there are two oxygen atoms with an oxidation state of -2 each, the oxidation state of Cl must be +3 to balance it out.
Xenon is a noble gas and typically has an oxidation state of 0 in its elemental form. However, xenon can form compounds where it exhibits positive oxidation states such as +2, +4, +6, or +8.
There are three physical states: Solid, Liquid, and Gas. However, Plasma is also considered a state, and there have been studies concerning a state between solid and liquid that glass may be in.
the electron configuration of a noble gas
Zero(0) for elemental nitrogen. However, nitrogen exhibits various oxidation numbers when combined with other elements, to form compounds. The oxidation number is the number of electrons in the valence shell directly involved in the combination with another element. e.g. N2O = Oxid'n No. 1 (Nitrous oxide ' Laughing Gas'). NO = Oxidation No. 2 (Nitrogen monoxide) NO2 = Oxid'n No. 4 (Nitrogen dioxide) HNO3 = Oxidation No. 5 . (Nitric Acid) HNO2 = Oxid'n No. 3 ( Nitrous Acid). NB THere may be electrons in the valence shell not directly combining in a compound/reaction, known as 'lone pairs'. NB Phosphorus, which is in the same Group(V) as nitrogen also exhibits variable oxidation states.,
The oxidation number of N in NO2 is +4. Each oxygen atom has an oxidation number of -2, so the sum of the oxidation numbers in NO2 must equal the overall charge of the molecule, which is 0. This means that the oxidation number of N must be +4 to balance the -4 oxidation contributed by the two oxygen atoms.
No, oxidation does not always turn something into a gas. Oxidation is a chemical reaction in which a substance loses electrons, leading to a change in its chemical composition. This process can result in various outcomes, such as the formation of a gas, solid, or solution.
In a chemical reaction, the law of conservation of mass states that the total number of atoms must remain constant. Therefore, if the reaction starts with 6 atoms of a solid and 12 atoms of a gas, the products will contain a total of 18 atoms, which can be a combination of solids, gases, or other states of matter. The specific types of products formed will depend on the nature of the reaction and the elements involved.
Atoms exist in various states primarily based on their energy levels and interactions. The most common states include solid, liquid, and gas, which describe how atoms are arranged and move in relation to one another. Additionally, atoms can exist in excited states when they absorb energy, leading to higher energy configurations. In more extreme conditions, such as in stars, atoms can form plasma, where electrons are stripped from nuclei.