The most basic thing needed to solve a Chemistry problem is
the knowledge of the Electronic structure of the molecules of the compound. And
for that one must be able to write down the Electronic Configuration of each
element (knowing its Atomic number). For example:
The EC of Carbon with atomic number 6 is 1s2 2s2
2p2.
While the conventional method of writing down the EC of an
element is not particularly complicated and doesn’t even require one to
remember a lot of stuff, but still there is one flaw in it- Speed. Yes the
traditional method is very slow. Every time we want an EC we have to draw a
medium sized table sort of structure and draw zigzag lines upon it (U know what
I mean don’t you?).
But I have got a brand new method that achieves the EC of
an element from its Atomic number (Z) and is really fast. Let us get on with
it.
The EC of any element consists of many terms with each term
having 3 elements – 1s2. First we are going to focus on the orbitals
i.e. s, p, d, f. I am going to fix an order in which we are going to read these
four orbitals for the rest of this article (or for the rest of your life if
you’ll stick with me till the end). The order is: f, d, p, s. You are now going
to divide this order into 4 segments. The first segment contains only the last
element of the order i.e. s. The second segment contains the last two elements
of the order – p, s. The third segment contains the last three elements of the
order- d, p, s. The final segment contains all the elements in order- f, d, p,
s. Write down each segment twice starting with the first and ending with the
fourth to get your base EC:
s s p s
p s d p s d p s
f d p s f d p s
The next part is to fill up the number of electrons in each
of the orbitals. S can have max of 2, p can have max of 6, d can have max of 10
and f can have max of 14 electrons. So if I was to write the EC of an element
with Z=32, I’ll start by writing the base of the EC as taught above and then
filling each orbital with its maximum no. of electrons till all available 32 of
them are properly consumed (you don’t have to write the whole base of the EC as
it defeats the purpose of this method which is speed. So you can write a first
few elements and fill them up with electrons and later if need be add some
orbitals to the base to consume all the electrons) Remember you only to write
that bit of the base which consumes all the electrons in the element. Now I
presume that I’ll be needing only 6 first orbitals from the base so I write
them and fill them with electrons-
s2 s2 p6 s2 p6
s2
Using these 6 I have only consumed 2+2+6+2+6+2=20 electrons
and I need to accommodate 12 more so I anticipate and write 3 more orbitals in
the base and fill them up till 32 are put in.
S2 s2 p6 s2 p6
s2 d10 p2.
So two out of three things are done till now. Now for the
most complicated part- the orbit numbering of each orbital. Following are the
thumb rules:
1) All orbits are
numbered with numbers from 1 to ….. 8
2) Orbit number ‘1’ comes only ones, 2 comes twice, 3 comes
thrice and …….. 8 comes 8 times at maximum in the base EC.
3) If suppose you are writing a number for the nth time then n-2 empty elements must be
skipped before actually writing it in front of an element in the base EC. An
already numbered element in the base EC is automatically skipped and it doesn’t
count as skip for the above formula
4) Every time a new number is to be written for the first
time, it must be written at the first available empty space from the beginning.
Let us follow these rules and number the entire base EC. Put
1 in front of the first element
1s s p
s p s d p
s d p
s f d
p s f d p s
1’s are done
Put two at the first
empty element from the begining:
1s 2s p
s p s d p
s d p
s f d
p s f d p s
Put two for the second time with no skips(skips=n-2=2-2=0)
1s 2s 2p
s p s d p
s d p
s f d
p s f d p s
2’s are done
3 for the first time at the first available empty space :
1s 2s 2p
3s p s d p
s d p
s f d
p s f d p s
3 for the second time (0 skips):
1s 2s 2p
3s 3p s d p
s d p
s f d
p s f d p s
3 for the third time (1 skip as we are writing 3 for the
third time so skips=n-2=3-2=1)
1s 2s 2p
3s 3p (SKIPPED) s
3d p s
d p s
f d p
s f d p s
3’s are done
4 for the first time at the first available empty space from
the beginning:
1s 2s 2p
3s 3p 4s 3d p
s d p
s f d
p s f
d p s
.
.
.
.
.
1s 2s 2p
3s 3p 4s 3d 4p
5s 4d 5p
(SKIPPED)s 4f 5d
(SKIPPED)p (SKIPPED)s 5f d p s
Now I am about to write 5 for the fifth time(3 skips). But
there is no element to number after skipping three empty elements. So we don’t
write 5 for the fifth time at all (Imagine writing it in the air). In fact we
ignore all those numbers for which the base EC runs out of elements. Following
this consideration you will see that 8 can be written only ones in the Base EC.
So here is the final full EC :
1s 2s 2p
3s 3p 4s 3d 4p
5s 4d 5p
6s 4f 5d
6p 7s 5f
6d 7p 8s
While this process looked pretty daunting, it actually is
quite simple and after one or two practices it comes out naturally. The thing
to be kept in mind is that one can simply write the base EC sufficient enough
for a given Atomic number without these orbit numbers and then after having the
required segment of the base EC, one can proceed to number it. Hence obtaining
the EC of the element very quickly. To demonstrate the quickness of this
method, let us take an example:
Z= 65
STEP 1) Anticipate and write the base EC:
s s p s p s d p s d p s f (I guess this is enough to
accommodate 65)
then upon the above base only we fill up the electrons till
reaching 65
s2 s2 p6
s2 p6 s2
d10 p6 s2
d10 p6 s2
f11
and finally we number it :
1s2 2s2 2p6 3s2 3p6 4s2 3d10 4p6 5s2 4d10 5p6 6s2 4f11
And that is our Electronic Configuration.
This Electronic Configurations provided by this method are
equally accurate as are the ones provided by the zigzag method and hence it is
worth noting that the EC of some element should be excepted from this method as
well.
