Lecture Notes by Dr Sadeem Chapter 11 Al
Lecture Notes by Dr. Sadeem Chapter 11 Al. Barody (Silberberg 3 ed) Covalent Bonding: Valence Bond Theory and Molecular Orbital Theory 11. 1 Valence Bond (VB) Theory and Orbital Hybridization 11. 2 The Mode of Orbital Overlap and the Types of Covalent Bonds 11. 3 Molecular Orbital (MO)Theory and Electron Delocalization
Valence Bond Theory 1. Covalent Bonds » Result from the overlap of valence shell atomic orbitals to share an electron pair 2. s, p, or hybrid orbitals may be used to form covalent bonds e. g. Predict the Orbitals used for bonding in: H 2, HF, H 2 S, F 2
Examples of s and p Orbitals involved in Bonding 1. Overlap of s orbitals » H 2 2. Overlap of s and p orbitals » HF » H 2 S 3. Overlap of p orbitals » F 2
Hybrid Orbitals 1. 2. The use of only s and p orbitals does not explain bonding in most molecules!!! e. g. Be. Cl 2, CH 4 , H 2 O hybrid orbitals are used in these cases Hybrid Orbitals are used to hold bonding and nonbonding electrons! Ø s, p, and d orbitals may hybridize to form hybrid orbitals
How to Determine an Atom’s Hybridization Write Lewis structure for the molecule or ion, then. . . 1. 2. Determine number of electron pairs around the atom in question One orbital is needed for each electron pair sp hybridization provides 2 orbitals sp 2 hybridization provides 3 orbitals sp 3 hybridization provides. . . ? . . . orbitals sp 3 d hybridization provides. . . ? . . orbitals sp 3 d 2 hybridization provides. . ? . . . orbitals
Examples of Hybrid Orbitals l Example of sp hybrid orbitals: » Be. Cl 2
Examples of Hybrid Orbitals l Example of sp 2 hybrid orbitals BF 3
Hybrid Orbitals 1. Examples of sp 3 hybrid orbitals CH 4, C 2 H 6, H 2 O, NH 3 2. Example of sp 3 d hybrid orbitals PCl 5 3. Example of sp 3 d 2 hybrid orbitals SF 6
Bond Angle ~92 o
Mode of Orbital Overlap Sigma vs. Pi Bonds 1. Sigma Bonds (s-bond) » Head to head overlap of s, p, or hybrid orbitals » Responsible for the framework of a molecule Single bond = one s bond
Mode of Orbital Overlap Sigma vs. Pi Bonds 2. Pi bonds (p-Bonds) » Side to side overlap of p orbitals » Restrict rotation l l Double bond = one s bond + one p bond Triple Bond = one s bond + two p bonds
Examples: Sigma vs. Pi Bonds Ethane l Ethylene (ethene) l » Effect of p-bonding on rotation about the s-bond? Acetylene (ethyne) l Nitrogen l Formaldehyde l
Predict the hybrid orbitals used in the following l Nitrogen gas, N 2 l Formaldehyde: H 2 CO l Carbon dioxide, CO 2 l Carbon monoxide, CO l Sulfur dioxide, SO 2
One option for SO 2 oo S = [Ne] 3 s 2 3 px 2 3 py 1 3 pz 1 This structure is. . . » Favored by formal charge » Requires ? ? hybridization Big Problems with this Structure. . » How many unhybridized p-orbitals are available for p bonding? » How many p-orbitals are needed?
Another Option for SO 2 S = [Ne] 3 s 2 3 px 2 3 py 1 3 pz 1 • ? ? ? Hybridization • Bond order? • Resonance? oo
Resonance: Delocalization of electrons l l Shifting of p-bond electrons without breaking the s- bond Although not favored by formal charge, B. O. = 1. 5 oo Resonance oo
Molecular Orbital Theory l l p-electron pair found in molecular orbital formed from the overlap of p-orbitals B. O. = 1. 5 » same as measured B. O. l S – O bond length is intermediate between S – O and S = O bond lengths oo
Strengths and Weaknesses of Valence Bond Theory l l l VB Theory Molecules are groups of atoms connected by localized overlap of valence shell orbitals VB, VSEPR and hybrid orbital theories work well together to explain the shapes of molecules But……VB theory inadequately explains… » Magnetic property of molecules » Spectral properties of molecules » Electron delocalization » Conductivity of metals
Molecular Orbital Theory l The electrons in a molecule are found in Molecular Orbitals of different energies and shapes » Just as an atom’s electrons are located in atomic orbitals of different energies and shapes l l MOs spread over the entire molecule Major drawbacks of MO Theory » Based on Quantum theory » Calculations are based on solving very complex wave equations major approximations are needed! » Difficult to visualize
Advantages of MO Theory l VB Theory incorrectly predicts that. . » O 2 is diamagnetic with B. O. = 2 or. . » O 2 is paramagnetic with B. O. = 1 l MO Theory correctly predicts that. . » O 2 is paramagnetic with B. O. = 2 l VB Theory requires resonance structures to explain bonding in certain molecules and ions » MO Theory does not have this limitation
Formation of Molecular Orbitals l l l MO’s form when atomic orbitals overlap Bonding MOs » Result from constructive interference of overlapping electron waves » Stabilize a molecule by concentrating electron density between nuclei MO’s more stable than AO’s delocalize electron charge over a larger volume
Overlap of standing electron Waves Constructive interference Destructive interference
(High e- density) (Low e- density) Fig. 11. 13
H 2 is more stable than the separate atoms
Antibonding MOs l Antibonding MOs » Result from destructive interference of overlapping electron waves » Reduce electron density between nuclei – Destabilize a molecule » Higher in energy than bonding MOs of the same type
Using MO Theory to Calculate Bond Order l l VB definition of Bond Order. . » Number of electron pairs shared between 2 nuclei MO Theory B. O. l = ½ (No. Bonding e- - No. Antibonding e-) Meaning of B. O. » B. O. > 0, then molecule more stable than separate atoms » B. O. = 0, then zero probability of bond formation » The greater the B. O. , the stronger the bond
Why Do Some Molecules Exist and Others Do Not? Why do H 2 and He 21+ exist , but He 2 does not? Recall…. . Bonding results only if there is a net decrease in PE l Molecules with equal numbers of Bonding and antibonding electrons are unstable. . . Why? . . . » Antibonding MOs raise PE more than Bonding MOs lower PE l
Use MO theory to predict if the following can form l Hydride ions: H 2 1 - and H 2 2 l Li 2 , Li 2 1+ , Li 2 2+ , Li 2 1 l Be 2 , Be 2 1+ , Be 2 2+ , Be 2 1 -
In He 2, the antibonding electrons in s 1 s* cancel the PE lowering of s 1 s
Sigma vs Pi Molecular Orbitals l s Molecular Orbitals form when. . . » s - atomic orbitals overlap » p - atomic orbitals overlap head to head l p Molecular Orbitals form when. . . » p - atomic orbitals overlap side to side l Why are s-bonds more stable than p- bonds?
No mixing of 2 s and 2 p orbitals AO MO Energy Levels for O 2, F 2 & Ne 2 Mixing of 2 s and 2 p orbitals AO MO Energy Levels for B 2, C 2 & N 2
Explaining MO Energy Levels for Period 2 Elements O 2, F 2 and Ne 2 • Paired electrons in 2 p sublevel Repulsions 2 s and 2 p different in Energy • No “mixing” occurs between 2 s and 2 p orbitals – Raises energy of s 2 s and s*2 s MO – Energy of s 2 p < Energy p 2 p B 2, C 2 and N 2 • Only unpaired electrons in 2 p sublevel 2 s and 2 p are very close in energy • “Mixing” occurs between 2 s and 2 p orbitals – Lowers energy of s 2 s and s*2 s MO – Energy of s 2 p > Energy p 2 p
Bonding in Diatomic Molecules of Period 2 l Rules for filling of Molecular Orbitals Apply the Rules for the filling of Atomic Orbitals (Aufbau principle) l 1. Electrons 1 st fill MOs of lowest energy 2. Only 2 electrons with opposite spin per MO 3. MOs of same energy (sublevel) half fill before electrons pair Predict the bond order for each of the following molecules involving period 2 elements » Li 2, Be 2, B 2, C 2, N 2, O 2, F 2, Ne 2, NO
High Z effective of F results in lower energy or its AO’s
1. Why are oxygen’s AO’s at lower a energy than nitrogen’s? 2. Bond order? 3. Para- or diamagnetic?
Delocalized Molecular Orbitals l l l MO Theory (unlike VB Theory) does not require resonance to explain the bonding in. . . » Carbonate ion, Nitrate ion, Formate ion, Acetate ion, Benzene, etc. MO Theory: Electron pairs can be shared by 3 or more atoms. . . . Why? » MOs can overlap 3 or more atoms Delocalized Bonds form when an electron pair is shared by 3 or more atoms » Offers stability in the same way that resonance offers stability
Bonding in Solids l Why do metals conduct electricity and nonmetals do not? » Band Theory to the rescue!!
Band Theory l l Energy Bands form from the overlap of atomic orbitals of similar energy from all atoms in a solid Energy bands containing core (nonvalence) electrons are localized » i. e. Do not extend far from each atom l l Energy Bands containing valence electrons are delocalized » I. e. extent continuously throughout the solid Conduction band : Valence bands that are either partially filled or empty
Energy Bands (MO Orbitals) for Na
Fig. 12. 37
Electrical Conductors Have a conduction band that is partially filled (e. g. Group IA & Transition Metals). . or. . l Have an empty conduction band that overlaps a filled valence band (i. e. Have a narrow band gap) l » e. g. Group IIA Metals
Fig. 12. 38
Nonconductors (Insulators) All valence electrons are used to form covalent bonds l Have a large band gap between the filled valence band the empty conduction band l Some examples l » Glass, diamonds, rubber, most plastics
Semiconductors Have a small band gap between the filled valence band the empty conduction band l Thermal Energy can promote electrons from filled valence band to empty conduction band l » e. g. Silicon
Doping of Semiconductors l p-type semiconductors » Doped with a Group IIIA element – Have one less electron than Si l Causes positive holes in semi conductor l Electricity flows through these positive holes l n-type semiconductors » Doped with a Group VA element – Have one more electron than Si l Causes negative holes in semiconductor l Electricity flows through these negative holes
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