H2SbO3- is -1
To find the sum of the oxidation states in a compound, we rely on the principle that the overall charge of the compound is zero. In this case, the oxidation state of hydrogen is +1, oxygen is -2 (except in peroxides), and we denote antimony as x. The compound is neutral, so the sum of the oxidation states must be equal to zero. Using these rules, we have 2(+1) + x + 3(-2) = 0. Solving, we find that x = +5.
The oxidation number of sulfur in MgSO4 is +6. This is because the oxidation state of magnesium is +2 and oxygen is always -2, so the algebraic sum of the oxidation states in MgSO4 must add up to zero.
The sum of all oxidation states in a neutral molecule or compound is equal to zero. In ions, the sum of all oxidation states is equal to the ion's charge. For atoms in their elemental form, the oxidation state is zero. Specific rules apply to common elements and their typical oxidation states.
The oxidation state of Cl in HClO4 is +7. In HClO4, since the oxidation state of H is +1 and that of O is -2, the sum of the oxidation states in the compound must equal 0. Therefore, the oxidation state of Cl in this case is +7.
The sum of all oxidation states in a compound is equal to the overall charge of the compound. This principle is derived from the fact that the total charge of a compound must be zero for a neutral compound.
To find the sum of the oxidation states in a compound, we rely on the principle that the overall charge of the compound is zero. In this case, the oxidation state of hydrogen is +1, oxygen is -2 (except in peroxides), and we denote antimony as x. The compound is neutral, so the sum of the oxidation states must be equal to zero. Using these rules, we have 2(+1) + x + 3(-2) = 0. Solving, we find that x = +5.
The oxidation number of sulfur in MgSO4 is +6. This is because the oxidation state of magnesium is +2 and oxygen is always -2, so the algebraic sum of the oxidation states in MgSO4 must add up to zero.
The sum of all oxidation states in a neutral molecule or compound is equal to zero. In ions, the sum of all oxidation states is equal to the ion's charge. For atoms in their elemental form, the oxidation state is zero. Specific rules apply to common elements and their typical oxidation states.
The oxidation state of Cl in HClO4 is +7. In HClO4, since the oxidation state of H is +1 and that of O is -2, the sum of the oxidation states in the compound must equal 0. Therefore, the oxidation state of Cl in this case is +7.
The sum of all oxidation states in a compound is equal to the overall charge of the compound. This principle is derived from the fact that the total charge of a compound must be zero for a neutral compound.
In a compound the sum of oxidation states of the elements contained is zero.E1 + E2 + ... = 0If you know the oxidation states of the elements E1... you can calculate the oxidation state of the element E2.
In Fe3O4, the oxidation number of Fe is +8/3. This can be found by setting up an equation where the total sum of the oxidation numbers in the compound equals the overall charge. In this case, Fe3O4 has a neutral charge, so the total sum of oxidation numbers is zero.
The oxidation state of iodine in CHI3 is -1. This is because hydrogen usually has an oxidation state of +1 and the overall molecule has to be neutral, so the sum of the oxidation states must be zero.
To determine the oxidation number of an element, consider its usual oxidation state based on its position in the periodic table and the known oxidation states of other elements in the compound. In a neutral compound, the sum of the oxidation numbers must equal zero, and in an ion, the sum must equal the charge of the ion. Use these rules to assign the oxidation number of the element.
In Mg2P2O7, magnesium (Mg) has an oxidation state of +2, phosphorus (P) has an oxidation state of +5, and oxygen (O) has an oxidation state of -2. The sum of the oxidation states for each element in the compound must equal zero due to its neutrality.
The sum of oxidation numbers in a neutral compound is always zero, as the charges balance out. In polyatomic ions, the sum of oxidation numbers equals the charge of the ion. When determining oxidation numbers, rules such as assigning elements in their elemental state an oxidation number of zero and hydrogen an oxidation number of +1 are typically followed.
Na+ + NO3- --> NaNO3 The oxidation sum is zero for NaNO3.