main group inorganic chemistry (chem 231)academic.macewan.ca/gelminil/231_1.pdf · some review of...
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MAIN GROUP INORGANIC CHEMISTRY (CHEM 231)
SOME REVIEW OF CHEM 101/102
Terms to be familiar with-Neutron, proton, electron-Atomic mass, mass number-Isotopes-Acids and bases-Redox reactions-Bonding (ionic vs molecular)
Reactivity outer electrons
Exact solution only for H atom or Bohr atoms like He+, C5+ or V22+
There are two coordinate systems that can be used.
1.Cartesian (x,y,z)
and
2. Spherical Polar (R(r) A(θ, φ)
1s orbital
2s orbital
ms = spin magnetic → electron spin
ms = ±½ (-½ = α) (+½ = β)
Pauli exclusion principle:
Each electron must have a unique set of quantum numbers.
Two electrons in the same orbital must have opposite spins.
Electron spin is a purely quantum mechanical concept.
N
S
H
N
S
H
N
S
He
Energy level diagram for He. Electron configuration: 1s2
paramagnetic – one (more) unpaired electrons
diamagnetic – all paired electrons
Ene
rgy
1
2
3
0 1 2
n
l
Effective Nuclear Charge, Z*The presence of other electrons around a nucleus “screens” an electron from the full charge of the nucleus.
We can approximate the energy of the electrons by modifying the Bohr equation to account for the lower “effective” nuclear charge:
E Zn R
n= −
⎛
⎝⎜⎜
⎞
⎠⎟⎟
*2
2Z* = Z - σ
Z* is the effective nuclear chargeZ is the atomic numberσ
is the shielding or screening constant
The Size of Atoms and IonsRadii of neutral atoms
The atomic radius of an atom is defined as half the distance between the nuclei in a homonuclear bond.
r decreases
r inc
reas
es
In general:
- radii decrease across a period because of increasing Z*.
-radii increase down a group because of the increasing distance of the electrons from the nucleus.
- increasing distance from the nucleus outweighs effective nuclear charge for atomic radii down a group.
Electronegativity also lets us predict the acidity of some binary element hydrogen compounds. Remember that X(H) = 2.2
X increases, acidity increases Going from left to right in a period X
increases.
E.g. Going from Li to F:X(Li) = 0.9 so the polarization for an Li-H bond is: Liδ+-Hδ- (“hydridic”)
X(C) = 2.5 so the C-H bond is not polarized and not basic or acidic
X(F) = 4.0 so the polarization for an F-H bond is: Fδ--Hδ+ (“protic”)
A similar approach can be used to predict the acidity/basicity of E-O-H bonds.
Please note that going down a group, the element-H bonds get weaker(e.g.: EO-H > ES-H > ESe-H ) thus the acidity of the compounds increases.
Polarizability and Hard and Soft Atoms
The polarizability,α, of an atom is its ability to be distorted by the presence of an electric field (such as a neighbouring ion). The more easily the electron cloud is distorted, the higher α. This happens primarily with large atoms and anions that have closely spaced frontier orbitals (HOAO and LUAO).
α decreases
αin
crea
ses
The hardness,η, of an atom is a related quantity. Hard atoms (high η) bind their electrons tightly and are not easily polarized. Soft atoms (low η) bind their electrons loosely and have a higher α.
η= ½ ([IPA - EAA ]) in eV ηSi ≈ 3.4 ηF ≈
7.0
ηSn ≈ 3.0 ηI ≈
3.7
Hard and Soft Ions
The hardness,η, of an atom or ion can also provide us with information about the chemistry that will happen between different reagents. In general, hard acids tend to form compounds with hard bases and soft acids tend to bind to soft bases.
Hard acids include transition metals and main group elements that are small and highly charged e.g. Li+, Mg+2, Al+3, Fe+3
Hard bases generally contain main group elements that are small and very electronegative e.g. F-, R-O-, NH3 , Cl-
Soft acids include transition metals and main group elements that are large and not as highly charged e.g. Tl+, Ag+, Pb+2, Fe+2
Soft bases generally contain main group elements that are large and weakly electronegative e.g. I-, SR2 , AsR3 , R-N≡C