EMR and the atom: Part Deux

http://imagers.gsfc.nasa.gov/ems/waves3.html

Electron Configurations

What you’ve seen so far….

Model of an atom

Which is really not true- why? Because orbitals- the

“electron cloud” are 3-D, not flat

e-s are spread out as much as possible

are not round in most cases e-s are moving very rapidly

(We can’t see this in a still image)

Orbitals

The electrons are spread out in orbitals that have varying Shapes Energy (distance from nucleus)

The orbitals are described in regards to their quantum numbers Descriptions that are descriptive and hierarchical There are 4 numbers that describe an orbital

Written as follows: (#, #, #, ±#)

Principal quantum number (n)The first number (1, #, #,±#) Describe the

distance from the nucleus to the orbital The energy of the orbital

Values for n are integers The smallest possible value is 1

As the distance from the nucleus (and therefore energy) increases, the number increases

Quantum numbers

There periodic table and n

The 7 periods on the periodic table correspond to n values

Each period has a unique n value For the 1st period, n=1 For the 2nd period, n=2 And so on….

Angular Momentum (l) (this is a script l, as in llama)

Is the shape of the orbital It is the second number in the description

(#,1,#, ±#) Range from 0 to n-1 (although we never

deal with anything above l=3) s =0 p =1 d =2 f = 3

The s orbital

http://www.sfu.ca/~nbranda/28xweb/images/s_orbital.gif

p orbitals

d orbitals

d orbitals

f orbitals

General tutorials for electron configuration stuff

some slides in this PowerPoint are from this site already

http://www.wwnorton.com/college/chemistry/gilbert/tutorials/ch3.htm

See key equations and concepts (select from menu on the left), as well as the looking through the overview where to the tutorials are listed (links for just those are on the left, too)

Magnetic number (ml)

Denote the orbital sublevel that is filled It is the third number in the description

(#,#,1, ±#) s orbitals have one sublevel; a sphere has one

orientation in space p orbitals have three sublevels; 3 orientations in

space d orbitals have five sublevels; 5 orientations in

space f orbitals have seven sublevels; 7 orientations in

space

“Flavors” of ml

s sublevels have one orbital; a sphere has one orientation in space

“Flavors” of ml

p sublevels have three orbitals; 3 orientations in space

“Flavors” of ml

d sublevels have five orbitals; 5 orientations in space

“Flavors” of ml

f sublevels have seven orbitals; 7 orientations in space

Magnetic number (ml)

Denote the orbital sublevel that is filled It is the third number in the description

(#,#,1, ±#) Values of –l to l, (integers only) For

s ml = 0 only since l= 0 p ml = -1,0,1 since l= 1 d ml = -2,-1,0,1,2 since l= 2 f ml = -3,-2,-1,0,1,2,3 since l= 3

Spin

It is the last number in the description (#,#,#,±½)

Spin is +½ or -½ Up or down

Summary, excluding spin

How we use this….

There is a specific order to how the e- fill the orbitals; it is not random Although there are exceptions to the

rules (last thing we do)

The principles of e- configuration

The Aufbau (next) Principle: That e- fill the lowest energy sublevel before

going to the next sublevel The Pauli Exclusion Principle:

That e-s are paired according to opposite spins Hund’s Rule:

e-s spread out in equal energy sublevels before placing electrons

The first level to fill is the 1s level It is the lowest energy sublevel It holds two electrons

They are oppositely paired (up and down- ↑↓) Each sublevel (each __) holds 2 electrons

Next…

The second sublevel is the 2s sublevel It also holds 2 electrons (because s

holds 2, not because of the number), also oppositely paired ↑↓

1s2, 2s2,then comes 2p6

So, as it states above 1s fills, 2s fills ,then

comes 2p It holds up to six

electrons Because p orbitals

hold 6 electrons

Next…

From 2p, 3s fills with 2e-, then onto 3p, with 6e- then 4s with 2e- followed by 3d with 10e- (because d

holds 10e-) Then 4p with 6e-

Notice, you follow the arrows

Remember, the number of electrons comes from the letter (the orbital’s momentum,ml)

The sublevels of the orbitals are first filled, then you continue onto the next level (Aufbau)

Also be sure to place one electron in each sublevel prior to filling the level (↑ ↑ ↑ and not ↑↓ ↑ _) (Hund)

e-s must be paired with e-s of opposite spin (↑↓, not ↑↑ or ↓↓) (Pauli)

Putting it all together…

Carbon (neutral, so 6 electrons) What this would look like:

↑↓ ↑↓ ↑ ↑ _1s 2s 2p

(notice there are 6 arrows for 6 electrons) This can also be written as 1s2 2s2 2p2

Notice the superscripts add up to 6

There are some exceptions…

This is because some energy levels are very close together electrons are able to move between close orbitals in order

to minimize repulsion Example: the 4s and 3d orbitals are very close in

energy So exceptions for some period 4 d block elements

occur Cr is not 1s2 2s2 2p6 3s2 3p6 4s2 3d4

Cr is 1s2 2s2 2p6 3s2 3p6 4s1 3d5

Because it takes less energy to split the electrons between the 5 sublevels than it does to put them together in the 4s and 3d