The oxidation state of carbon in CaCO3 is +4. This is because the oxidation state of calcium (Ca) is +2 and the oxidation states of oxygen (O) are -2. Therefore, to balance the charges in the compound, the oxidation state of carbon must be +4.
The oxidation state of an individual sulfur atom in SO4 is +6. In the sulfate ion (SO4^2-), each oxygen atom has an oxidation state of -2, for a total of -8. Since the overall charge of the sulfate ion is -2, the sulfur atom must have an oxidation state of +6 to balance out the charge.
The oxidation state of an individual carbon atom in CaCO3 is +4. This is because the oxidation state of Ca is +2, and the oxidation states of O are typically -2. The sum of the oxidation states for CaCO3 must equal 0, so the oxidation state of carbon in this compound must be +4.
C2O42-COO -lCOO -O always has an oxidation states of -2.So if there are 4 O atoms, with -2 each, it gives a total of -8.since the charge on the ion is -2, the total carbon is +6, and there are 2, so each carbon is +3.C= +3
The oxidation state of carbon (C) in CO2 is +4. Each oxygen atom in CO2 has an oxidation state of -2, so for the overall molecule to be neutral, carbon must have an oxidation state of +4.
The oxidation state of carbon in CaCO3 is +4. This is because the oxidation state of calcium (Ca) is +2 and the oxidation states of oxygen (O) are -2. Therefore, to balance the charges in the compound, the oxidation state of carbon must be +4.
The oxidation state of an individual nitrogen atom in CaCO3 is +4. In CaCO3, nitrogen is present in the carbonate ion (CO3)2-, and since each oxygen atom in the carbonate ion has an oxidation state of -2, the carbon atom must have an oxidation state of +4 to balance the charge.
+3
The oxidation state of an individual sulfur atom in SO4 is +6. In the sulfate ion (SO4^2-), each oxygen atom has an oxidation state of -2, for a total of -8. Since the overall charge of the sulfate ion is -2, the sulfur atom must have an oxidation state of +6 to balance out the charge.
The oxidation state of an individual carbon atom in CaCO3 is +4. This is because the oxidation state of Ca is +2, and the oxidation states of O are typically -2. The sum of the oxidation states for CaCO3 must equal 0, so the oxidation state of carbon in this compound must be +4.
C2O42-COO -lCOO -O always has an oxidation states of -2.So if there are 4 O atoms, with -2 each, it gives a total of -8.since the charge on the ion is -2, the total carbon is +6, and there are 2, so each carbon is +3.C= +3
The oxidation state of carbon (C) in CO2 is +4. Each oxygen atom in CO2 has an oxidation state of -2, so for the overall molecule to be neutral, carbon must have an oxidation state of +4.
The oxidation state of each oxygen atom in CO3^2- is -2, making a total of -6 for the three oxygen atoms. To neutralize this charge, the oxidation state of the carbon atom is +4.
The oxidation state of an individual phosphorus atom in PO is +5. This is because oxygen typically has an oxidation state of -2, so in the compound PO, the overall charge is 0, which means the oxidation state of phosphorus must be +5 to balance the charges.
The oxidation state of sulfur in BaSO₄ is +6. This is because barium (Ba) has an oxidation state of +2 and the overall compound is neutral, so the oxidation states of all atoms must add up to zero.
In SO3^2-, sulfur has an oxidation state of +4 (Sulfur's typical oxidation state is +6 and each oxygen has an oxidation state of -2, so the total charge of the ion of -2 corresponds to sulfur being in a +4 oxidation state).
The oxidation state of sulfur in MgSO4 is +6. This is because magnesium has an oxidation state of +2 and oxygen typically has an oxidation state of -2, so the overall compound must have a net charge of 0, leading to sulfur having an oxidation state of +6 to balance the charges.