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3.25

Posted: Sun Nov 05, 2017 7:43 pm
by sandros
Can someone please explain the process ? I can't figure out the correct answers for that one ...

Re: 3.25

Posted: Sun Nov 05, 2017 8:07 pm
by Sabah Islam 1G
To find the chemical formula of the compounds, just take the value of the charge of one atom and make it the subscript of the other atom in the compound. For example, when writing the chemical formula for magnesium arsenide, the charge for Mg (magnesium) is +2, so 2 would be the subscript for As (arsenic), and the charge for As is -3, so 3 would be the subscript for Mg. Therefore, the chemical formula for magnesium arsenide would be Mg3As2.

Re: 3.25

Posted: Sun Nov 05, 2017 10:40 pm
by Timothy Kim 1B
With these two charges, find the lowest common factor between the two. Use this lowest common factor as the subscript for the opposite charges.

Re: 3.25

Posted: Tue Nov 07, 2017 6:44 pm
by Dylan Mai 1D
How do you know the charges for the elements? memorization?

Re: 3.25

Posted: Wed Nov 08, 2017 10:05 pm
by Aijun Zhang 1D
Dylan Mai 1D wrote:How do you know the charges for the elements? memorization?

It's basically based on electron configuration, or say, how it would be most stable to form a compound.
For example, for group 1 and 2, it is most possible that they are tend to lose electrons when forming a compound. Then the number of electrons lost is the charge they would have. Li only has 1 valence electron, so in a compound, it's oxidation number will be +1.
For group 14 to 17, they are more likely to gain electrons to fullfill their orbitals. So for oxygen, it usually gains 2 electrons and thus have an oxidation number of -2. But it is a little bit complicated when it comes to N, S, P and C (and sometimes O).
For d-block elements, one of the property is that they have various oxidation numbers. So it is much harder.

For what I remembered, the actual way to calculate the oxidation number is to use formal charge. But I cannot recall very well now.
Generally I would recommend to remember some of the oxidation numbers of common elements, such as H, Na, O(usually-2, sometimes -4 and -1), Cl, etc. Then use the unchanged one to calculate the one has various oxidation states.

Re: 3.25

Posted: Thu Nov 09, 2017 10:33 am
by RenuChepuru1L
what happens when there is a number in parentheses for example Bismuth(III)?

Re: 3.25

Posted: Thu Nov 09, 2017 10:43 am
by Hammad Khan 2B
RenuChepuru1G wrote:what happens when there is a number in parentheses for example Bismuth(III)?


The number in the parentheses just means the charge of the element. Ex) Cu (II) would be Cu2+ and so on.