SMK SULTAN ISMAIL JB, NUR FATHIN SUHANA BT AYOB
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1 SMK SULTAN ISMAIL JB, NUR FATHIN SUHANA BT AYOB
2 POLAR AND NON POLAR BONDS
3 BOND POLARITY 1. Atoms with different electronegative from polar bonds (difference in EN) 2. Depicted as polar arrow : 3. Example : C - Cl δ δ + C - Cl # Polar bond
4 POLAR BOND electron poor region electron rich region H F Polar bond 4
5 NON POLAR BOND F F Non polar bond 5
6 BOND POLARITY Example : C F δ + δ C - F # Polar bond C C (no difference of electronegativity) # Non polar bond
7 ELECTRONEGATIVITY Electronegativity of an atom is the ability of an atom that is covalently bonded to another atom to attract electrons to itself An atom with a high electronegativity will attract electrons towards itself and away from the atom with a lower electronegativity Electronegativity of an atom is inversely proportional to its size. The smaller the atomic size, the stronger the attraction for the bonding electrons and the higher electronegativity.
8
9 NON POLAR BONDS 1. For covalent bond that consists of two identical atoms, the bonding electrons are shared equally between the two atoms and are attracted equally to both the atoms. This type of bond is called non-polar bond. 2. Diatomic molecules such as H 2, O 2, Cl 2, N 2, have non polar bonds because the atoms in the molecules have same electronegativity. These molecules are called non polar molecules.
10 POLAR BOND 1. In covalent bond that contains two atoms that are not identical. The bonding electrons will be attracted more strongly by the more electronegative element and this result in unsymmetrical distribution of electrons. 2. Ex : H Cl. The more electronegative chlorine atom attracts the bonding electron pair more strongly than hydrogen does. 3. HCl is a polar molecule and it contains polar bond. 4. The separation of charge in polar covalent bond like H-Cl is called polarisation. 5. When two electrical charge of opposite signs are separated by small distance, a dipole is established. Thus, HCl has a dipole because the H-Cl is a polar.
11 DIPOLE MOMENT (μ) A quantitative measure of the polarity of a bond is its dipole moment ( µ ). µ = Q r Where : µ = dipole moment Q = the product of the charge from electronegativity r = distance between the charges Dipole moments are usually expressed in debye units(d) 1D (Debye) = 3.36 x Cm
12 RESULTANT (NET) DIPOLE MOMENT 1. Determined by molecular shape and bond polarity Resultant dipole moment > 0 (polar molecule) Resultant dipole moment = 0 (non-polar molecule) 2. Example : I - I EN = 0 (charge in electronegativity) μ = 0 I 2 is a non polar molecule
13 RESULTANT (NET) DIPOLE MOMENT CI - I 3. Example : EN 0 (charge in electronegativity) μ 0 I 2 is a polar molecule
14 RESULTANT (NET) DIPOLE MOMENT CO 2 O = C = O 4. Example : CO 2 shape =linear The two bond dipoles cancel each other (molecule is symmetrical) Resultant dipole moment, μ = 0 CO 2 is a non polar molecule
15 RESULTANT (NET) DIPOLE MOMENT OCS O = C = S 5. Example : OCS shape =linear The two bond dipoles do not cancel each other Resultant dipole moment, μ 0 OCS is a polar molecule
16 RESULTANT (NET) DIPOLE MOMENT BF 3 F 6. Example : BF 3 shape =trigonal planar The two bond dipoles cancel each other Resultant dipole moment, μ = 0 BF 3 is a NON polar molecule F B F
17 RESULTANT (NET) DIPOLE MOMENT BF 2 Br F 7. Example : BF 3 Br shape =trigonal planar The three bond dipoles do not cancel each other Resultant dipole moment, μ 0 BF 3 Br is a polar molecule F B Br
18 Carbon tetrachloride, CCl 4 - molecular geometry : tetrahedral - Chlorine is more electronegative than carbon, - Dipole moment can cancel each other - has no net dipole moment (µ = 0) - therefore CCl 4 is a nonpolar molecule.
19 Chloromethane, CH 3 Cl - molecular geometry : tetrahedral - Cl is more electronegative than C, C is more electronegative than H - Dipole moment cannot cancel each other - has a net dipole moment (µ 0) - therefore CH 3 Cl is a polar molecule.
20 Ammonia, NH 3 - molecular geometry : tetrahedral - N is more electronegative than H, - Dipole moment cannot cancel each other - has a net dipole moment (µ 0) - therefore NH 3 is a polar molecule.
21 BOND MOMENTS AND RESULTANT DIPOLE MOMENTS H
22 DIFFERENCE BETWEEN POLAR BOND AND POLAR MOLECULES 1. Polar molecules possess polar bond. 2. A bond is polar when the two atoms that are participating in the bond formation have different electronegativities. In polar molecule, all the bonds collectively should produce a polarity. 3. Though a molecule has polar bonds, it does not make the molecule polar. 4. If the molecule is symmetric and all the bonds are similar, then the molecule may become non polar. 5. Therefore, not all the molecules with polar bonds are polar.
23 KEEP IN MIND! The presence of polar bonds does not always lead to a polar molecule C O is a polar bond But, CO 2 is a non polar molecule O = C = O We have to CONSIDER BOTH (bond polarity and molecular shape)
24 A SUMMARY ON HOW TO DETERMINE MOLECULAR POLARITY 1. A molecule will be nonpolar if : a) The bonds are non-polar CI CI (non polar) b) No lone pair in the central atom and all the surrounding atoms are the same POLAR F B F B NON POLAR F Br F F
25 A SUMMARY ON HOW TO DETERMINE MOLECULAR POLARITY 1. A molecule will be nonpolar if : c) A molecule in which the central atom has lone pair electron will usually be polar with few exceptions N O H H POLAR H H POLAR H
26 A SUMMARY ON HOW TO DETERMINE MOLECULAR POLARITY 1. A molecule will be nonpolar if : c) A molecule in which the central atom has lone pair electron will usually be polar with few exceptions F F F Br F S POLAR F F POLAR F
27 A SUMMARY ON HOW TO DETERMINE MOLECULAR POLARITY 2. Exceptions : (NON POLAR MOLECULES) X X X F F A A Xe X X F F X LINEAR SQUARE PLANAR
28 Exercises : Predict the polarity of the following molecules: SO 2 ; HBr ; SO 3 ; CH 2 Cl 2 ; ClF 3 ; CF 4 ; H 2 O ; XeF 4 ; NF 3 28
29 HYBRID ORBITAL OVERLAP AND HYBRIDIZATION 1. VSEPR theory : predict molecular shapes by assuming that electron groups tend to minimize their repulsions 2. But, it does not tell how those shapes (which is observed experimentally), can be explained from the interactions of atomic orbitals.
30 VALENCE BOND (VB) THEORY 1. Covalent bonds are formed by sharing electrons from overlapping atomic orbitals 2. Two types of bonds : σ bond and π bond 3. Example :
31 DIRECT OVERLAP OF s AND p ORBITAL 1. Atoms in simple molecules or ions such as H 2, HF, N 2, etc. use pure s and/or p orbitals in forming covalent bonds. 2. Example : H 2 (hydrogen molecules)
32 DIRECT OVERLAP OF s AND p Example : HF (Hydrogen Flouride) H = 1s 1 F = 1s 2 2s 2 2p 5 ORBITAL Example : F 2 (Flourine molecules) F = 1s 2 2s 2 2p 5
33 HYBRIDIZATION 1. Mixing of two or more atomic orbitals to form a new set of equivalent hybrid orbitals in the same energy level 2. The spatial orientation of the new orbitals is cause more stable bonds and are consistent with the observed molecular shape types of hybridization : sp, sp 2, sp 3 hybridization
34 4.3.2 Formation Hybrid orbitals Overlapping of hybrid orbitals and the pure orbitals occur when different type of atoms are involved in the bonding. Hybridization of orbitals: mixing of two or more atomic orbitals to form a new set of hybrid orbitals The purpose of hybridisation is to produce new orbitals which have equivalent energy Number of hybrid orbitals is equal to number of pure atomic orbitals used in the hybridization process.
35 Hybridization Hybrid orbitals have different shapes from original atomic orbitals Types of hybridisation reflects the shape/geometry of a molecule Only the central atoms will be involved in hybridisation
36 HYBRIDIZATION s orbital p orbital sp orbital
37 TYPES OF HYBRID ORBITALS Type Examples Electron group Electron group arrangement sp BeCl 2 2 Linear sp 2 BF 3 3 Trigonal planar sp 3 CH 4 4 Tetrahedral
38 DETERMINING HYBRID ORBITALS 1. Draw Lewis structure 2. Predict electron group arrangement using VSEPR model 3. Deduce the hybridization of the central atom by matching the arrangement of the electron groups with the hybrid orbitals 4. Use partial the orbital diagram to explain the mixing of atomic orbitals
39 Molecular formula Lewis Structure Molecular shape and electron group arrangement Hybrid orbitals
40 SIGMA (σ) BOND 1. Resulting from end to end overlap 2. Has highest electron density along the bond axis 3. Allow free rotation 4. All single bonds are σ bond
41 bond It formed when orbitals overlap from end to end Example: i. overlapping s orbitals H + H H H 41 bond
42 ii. Overlapping of s and p orbitals P x orbital H + x H x bond 42
43 iii. Overlapping of p orbitals x + x x bond 43
44 Pi (π) Bond 1. Resulting from side to side overlap 2. Has two regions of electron density One above and one below the σ bond axis 3. One π bond hold two electrons that move through both regions of the bond 4. π bond restricts rotation
45 bond It formed when two p-orbitals of the same orientation overlap sideways Double bond consists of one σ bond and one π bond Example : y y y y + bond
46 bond Example : π π O = C = O σ σ CO 2 has two π bond and one σ bond Triple bond always consists of one σ bond and two π bond N N π σ π
47 How do I predict the hybridization of the central atom? Count the number of lone pairs AND the number of atoms bonded to the central atom No of Lone Pairs + No of Bonded Atoms Hybridization Examples sp sp 2 sp 3 BeCl 2 BF 3 CH 4, NH 3, H 2 O
48 48 Copyright The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
49 FORMATION OF sp HYBRIDIZATION Two equivalents sp hybrid orbitals that lie 180 apart 2 electron groups (from VSEPR theory) Electron group arrangement : linear Molecular shape : linear sp sp 180
50 FORMATION OF sp HYBRIDIZATION Lewis structure BeCl 2 σ σ Cl Be Cl Valence electron configuration Be O 1 : O 2 : 2s 2s 2p 2p Hybridisation sp sp 2p 2p sp orbitals Empty 2p orbitals One s orbital + one p orbital two equivalent sp orbitals
51 51
52 FORMATION OF sp 2 HYBRIDIZATION Three equivalents sp 2 hybrid orbitals that lie 120 apart 3 electron groups (from VSEPR theory) Electron group arrangement : trigonal planar Molecular shape : trigonal planar sp 2 sp 2 sp 2 120
53 Lewis structure FORMATION OF sp 2 HYBRIDIZATION Valence electron configuration B O 1 : O 2 : BF 3 2s 2s 2p 2p F σ σ F B σ F Hybridisation sp 2 sp 2 sp 2 2p sp 2 orbitals Empty 2p orbitals One s orbital + two p orbital three equivalent sp 2 orbitals
54 TRY DRAW THEM sp 2 hybrid!!
55 FORMATION OF sp 3 HYBRIDIZATION Bond angle : electron groups (from VSEPR theory) Electron group arrangement : tetrahedral Molecular shape : tetrahedral sp 3 sp 3 sp 3 sp
56 Lewis structure FORMATION OF sp 3 HYBRIDIZATION Valence electron configuration C O 1 : O 2 : CH 4 2s 2s 2p 2p H σ σ σ H C H σ H Hybridisation sp 3 sp 3 sp 3 sp 3 sp 3 orbitals Empty 2p orbitals One s orbital + three p orbital four equivalent sp 3 orbitals
57 TRY DRAW THEM sp 3!!
58 Example : Methane, CH 4 Ground state : C : 1s 2 2s 2 2p 2 Excitation: to have 4 unpaired electrons 1s 2s 2p Lewis Structure H H C H H H Excited state : 1s 2s 2p sp 3 sp 3 hybrid H sp 3 C sp 3 sp 3 H H shape: tetrahedral
59 sp 3 -Hybridized C atom in CH 4 sp 3 1s sp 3 sp 3 sp 3 1s 1s 59
60 sp 3 hybrid Mixing of s and three p orbitals sp 3 sp 3
61 Other Example: 1. BF 3 Lewis structure : Valence Electron configuration : F : B ground state : B hybrid : Molecular geometry Orbital overlap/hybridisation:
62 Example: BF 3 Pure p orbital sp2 sp 2 sp 2 F : 1s 2 2s 2 2p 5 Shape : trigonal planar
63 2. NH 3 Lewis structure : Other Example : Valence orbital diagram ; H : N ground state : N hybrid : Orbital Overlap : Molecular Geometry :
64 sp 3 1s sp 3 sp 3 sp 3 1s 1s 64
65 3. H 2 O Other Example: Lewis structure : Valence orbital diagram; O ground state : O hybrid : Molecular geometry Orbitals overlap: 65
66 HYBRIDISATION IN MOLECULES CONTAINING DOUBLE AND TRIPLE BONDS
67 FORMATION OF HYBRIDIZATION Lewis structure Valence electron configuration C O 1 : O 2 : C 2 H 4 2s 2s (ETHANE) 2p 2p H H σ C = C π H H Hybridisation sp 2 sp 2 sp 2 2p sp 2 orbitals UNHYBRIDIZED 2p orbitals One s orbital + two p orbital three equivalent sp 2 orbitals
68 HOW TO DRAW?
69 bonds bond 69
70 70
71 FORMATION OF HYBRIDIZATION Lewis structure Valence electron configuration C O 1 : O 2 : C 2 H 2 2s 2s (ACETYLENE) 2p 2p H σ C C π π H Hybridisation sp sp 2p 2p sp orbitals UNHYBRIDIZED 2p orbitals One s orbital + one p orbital two equivalent sp orbitals
72 HOW TO DRAW?
73 73
74 FORMATION OF HYBRIDIZATION Lewis structure C 6 H 6 (BENZENE) Valence electron configuration C O 1 : O 2 : 2s 2s 2p 2p Hybridisation sp 2 sp 2 sp 2 2p sp 2 orbitals UNHYBRIDIZED 2p orbitals One s orbital + two p orbital three equivalent sp 2 orbitals
75 BENZENE???? (Look at the notes!)
76 QUESTIONS: For each of the following, draw the orbital overlap to show the formation of covalent bond a) H 2 O b) N 2 c) CH 3 Cl d) AlCl 3 76
77 INERTNESS OF NITROGEN MOLECULE 1. Nitrogen is a very electronegative element. 2. It is an inert (unreactive) element. 3. Inertness due to 2 factors : a) Strong triple bond b) Non polarity of N 2 4. Bond energy N N is very high due to triple bond. 5. This strong bond must be broken first, then it can form with other compounds. 6. A lot of energy needed to break 7. Only at high temperature, nitrogen can react with other elements to form compounds. 8. Nitrogen molecules is non-polar. The absence of polarity on the molecule explains why nitrogen is unreactive.
78 COVALENT CHARACTER IN IONIC COMPOUNDS 1. Not all compounds are ionic, and not all compounds are covalent. 2. Polarisation of chemical bonds also occur in an ionic bond. 3. Most ionic compounds have covalent character due to incomplete transfer of electrons. 4. If a small cation with high electric charge approaches a large anion, the cation will attract the electron cloud from the negative ion. 5. It causes a distortion of the electron cloud of an anion. 6. These distortion produces a certain amount of covalent character in the bond. 7. Polarisation : The distortion of electron cloud of the anion by a neighbouring cation.
79 COVALENT CHARACTER IN IONIC COMPOUNDS 8. Polarising power : The extent to which a cation (positive ion) can polarise an anion (negative ion) 9. Percentage of covalent character in an ionic bond depends on the polarisibility of anion. 10. The larger the size of an anion, the weaker the attraction between nucleus and electrons. Then, electron cloud is easier to be polarised. 11. The greater the degree of polarisation of the anion, the greater the amount of covalent character in the ionic bond.
80 COVALENT CHARACTER IN IONIC COMPOUNDS 12. The polarising power of a cation towards an anion is proportional to the charge density. charge charge density = ionic radius (size) 13. Small and highly charged cations such as Li + and Al 3+ have high charge density, so, high polarising power. Covalent character Al 2 Cl 6, BeCl 3 Ionic bond with slightly covalent bond Al 2 O 3, BeO 2 Small cations, high charge, high charge density, high polarising power
81 Question 1 Arrange the following chlorides in order of increasing covalent character. Explain your answer. NaCl, MgCl 2, AlCl 3
82 Answer 1 NaCl < MgCl 2 < AlCl 3 The charge density of the cations increases in the order : Na + < Mg 2+ < Al 3+ Hence, polarising power of the cations towards the Cl _ ion increases in the same order. Polarising power of Al 3+ is high so, it is a covalent compound.
83 Question 2 Arrange two compounds of beryllium order of increasing covalent character. BeF 2, BeI 2
84 ANSWER 2 The size of I ion is larger than F ion, hence it is easier to be polarised by the Be 2+ ion BeI 2 is expected to have a high degree of covalent character.
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