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Chemical Bonds

Chemical Bonds. Ionic Bond Formation of Ions Electron Configurations of Ions Ionic Size and Charge density, Relative Strength of Ionic Bonds Lattice Energy Steps in the Formation of an Ionic Compound The Born-Haber Cycle. Chemical Bonds. Covalent Bonds Electronegativity

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Chemical Bonds

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  1. Chemical Bonds • Ionic Bond • Formation of Ions • Electron Configurations of Ions • Ionic Size and Charge density, • Relative Strength of Ionic Bonds • Lattice Energy • Steps in the Formation of an Ionic Compound • The Born-Haber Cycle

  2. Chemical Bonds • Covalent Bonds • Electronegativity • Polarity of Covalent Bonds • Lewis Structures and the Octet Rule • Exceptions to the Octet Rule • Resonance Lewis Structures • Bond Energies • Calculating Enthalpy using Bond Energy • Molecular Shape - The VSEPR Model

  3. Review of Atomic Properties • Effective nuclear charge & Atomic Size: • effective nuclear charge increases left to right and decreases down a group; • electronic shell gets smaller left-to-right across period and gets bigger down a group; • Atomic size decreases left to right across period and increases top to bottom down a group:

  4. Review of Atomic Properties • Atomic Size and Ionization Energy: • L-to-R: atomic size decreases; ionization energy increases; • Top-to-bottom: atomic size increases; ionization energy decreases; • Ionization energy increases across period (L-to-R), but decreases down a group;

  5. Review of Atomic Properties • Electron affinity increases left to right and decreases top to bottom: smaller atoms have stronger attraction of added electron than larger atoms Nonmetals have higher tendency to gain electrons than metals and become anion

  6. Review of Atomic Properties • Atomic Size and Electron Affinity: • L-to-R: atomic size decreases, electron affinity increases; • Top-to-bottom: atomic size increases, electron affinity decreases; • Electron affinity increases across period (L-to-R), but decreases down a group;

  7. Ionic bonds • Attractions between cations and anions; • Bonds formed between metals and nonmetals

  8. Formation of Cations • Ions formed when metals react with nonmetals - metal atoms lose valence electrons to nonmetals; • Atoms of representative metals lose valence electrons to acquire the noble gas electron configuration; • Cations of representative group have noble gas electron configurations;

  9. Formation of Cations • From the alkali metals (1A): M  M+ + e- • From the alkaline Earth metals (2A): M  M2 + + 2e- • From Group 3A metals: M M3++ 3e- ;

  10. Formation of Ions • The nonmetal atoms gain electrons to the noble gas electron configuration; • Anions have noble gas electron configuration;

  11. Formation of Anions • From the halogen family (VIIA): X + e- X- • From the oxygen family (VIA): X + 2e- X2- • From N and P (in Group VA): X + 3e- X3-

  12. Common Ions of the Representative Elements • Ions isoelectronic to He (1s2): Li+ & H- • Ions isoelectronic to Ne (1s2 2s2 2p6): Na+, Mg2+, Al3+, F-, O2-, and N3- • Ions isoelectronic to Ar (1s2 2s2 2p6 3s2 3p6): K+, Ca2+, Sc3+, Cl-, S2-, and P3-

  13. Common Ions of the Representative Elements • Ions isoelectronic to Kr (1s22s22p63s23p64s23d104p6): Rb+, Sr2+, Y3+, Br-, and Se2-; • Ions isoelectronic to Xe (1s22s22p63s23p64s23d104p65s24d105p6) Cs+, Ba2+, La3+, I-, and Te2-;

  14. Ionic Radii Relative size of isoelectronic ions: • Al3+ < Mg2+ < Na+ < Ne < F- < O2- < N3-; • Sc3+ < Ca2+ < K+ < Ar < Cl- < S2- < P3-; Trend of ionic radii within a group: • Li+ < Na+ < K+ < Rb+ < Cs+; • F- < Cl- < Br- < I-;

  15. Cations From Transition Metals • Transition metal atoms lose variable number of electrons; • Cations have variable charges; • Cations do not acquire noble gas electron configurations

  16. Electron Configurations of Transition Metal Cations • Examples: Cr: [Ar] 4s13d5 Cr  Cr2+ + 2e-; Cr2+: [Ar] 3d4 Cr  Cr3+ + 3e-; Cr3+: [Ar] 3d3 Fe: [Ar] 4s23d6 Fe  Fe2+ + 2e-; Fe2+: [Ar] 3d6 Fe  Fe3+ + 3e-; Fe3+: [Ar] 3d5

  17. Charge Density and Strength Ionic Bond • Charge density = charge/size of ion Greater charge but small ionic radius High charge density  stronger ionic bond; • Stronger ionic bond  High lattice energy; • Stronger ionic bond  High melting point;

  18. Lattice Energy (UL) • Lattice energy - energy released when gaseous ions combine to form solid ionic compound: M+(g) + X-(g) MX(s); UL = Lattice energy • Examples: Na+(g) + Cl-(g) NaCl(s); UL = -787 kJ/mol • Li+(g) + F- (g) LiF(s); UL = -1047 kJ/mol

  19. Lattice energy Lattice energyk(q1q2/r2) q1 and q2= charge magnitude on ions; r = distance between nuclei, and k = proportionality constant. Lattice energy increases with charge magnitude but decreases with ionic size

  20. Lattice Energies of Some Ionic Compounds • Lattice Energy, UL(kJ/mol) The energy required to separate a mole of ionic solids into the gaseous/vapor ions; MX(s)  M+(g) + X-(g) • Mn+/Xn- F- Cl- Br- I- O2- • Li+ 1047 853 807 757 2942 • Na+ 923 787 747 704 2608 • K+ 821 715 682 649 2311 • Mg2+ 2957 2526 2440 2327 3919 • Ca2+ 2628 2247 2089 2059 3570 ______________________________________________________________________

  21. The Born-Haber Cycle for NaCl • Na+(g) + Cl(g) _______________ • -349 kJ • +496kJ _______ Na+(g) + Cl-(g) • Na(g) + Cl(g)___________ • +121 kJ • Na(g) + ½Cl2(g)________ ? kJ • +108 kJ • Na(s) + ½Cl2(g)________ • -411 kJ • NaCl(s)_________________

  22. Chemical Processes in the Formation of NaCl • Na(s) Na(g); DHs = +108 kJ • ½Cl2(g) Cl(g); ½BE = +121 kJ • Na(g) Na+(g) + e-; IE = +496 kJ • Cl(g) + e- Cl-(g); EA = -349 kJ • Na+(g) + Cl-(g) NaCl(s); UL = ? kJ • Na(s) + ½Cl2(g) NaCl(s); DHf = -411 kJ UL = DHf – (DHs + ½BE + IE + EA) (DHs = Enthalpy of sublimation; IE = Ionization energy; BE = Bond energy; EA = Electtron affinity; UL = Lattice energy; DHf = Enthalpy of formation)

  23. The Born-Haber Cycle for LiF • Li+(g) + F(g) _______________ • -328 kJ • +520kJ _______Li+(g) + F-(g) • Li(g) + F(g)___________ • +77 kJ • Li(g) + ½F2(g)________ ? kJ • +161 kJ • Li(s) + ½F2(g)________ • -617 kJ • LiF(s)_________________

  24. Chemical Processes in the Formation of LiF • Li(s) Li(g); DHs = +161 kJ • ½F2(g) F(g); ½BE = +77 kJ • Li(g) Li+(g) + e-; IE = +520 kJ • F(g) + e- F-(g); EA = -328 kJ • Li+(g) + F-(g) LiF(s); UL = ? • Li(s) + ½F2(g) LiF(s); DHf = -617 kJ UL = DHf – (DHs + ½BE + IE + EA) (DHs = Enthalpy of sublimation; IE = Ionization energy; BE = Bond energy; EA = Electtron affinity; UL = Lattice energy; DHf = Enthalpy of formation)

  25. The Born-Haber Cycle for MgO • Mg2+(g) + O2-(g) _____________ • +737 kJ • Mg2+(g) + O(g)________ • +2180 kJ • Mg(g) + O(g)_________ • +247 kJ • Mg(g) + ½O2(g)________ ? kJ • +150 kJ • Mg(s) + ½O2(g)________ • -602kJ • MgO(s)_________________

  26. Chemical Processes in the Formation of MgO • Mg(s) Mg(g); DHs = +150 kJ • ½O2(g) O(g); ½BE = +247 kJ • Mg(g)Mg2+(g)+ 2e-; IE = +2180 kJ • O(g) + 2e-O2-(g); EA = +737 kJ • Mg2+(g)+ O2-(g) MgO(s); UL = ? kJ • Mg(s) + ½O2(g) MgO(s); DHf = -602 kJ UL = DHf – (DHs + ½BE + IE + EA) (DHs = Enthalpy of sublimation; IE = Ionization energy; BE = Bond energy; EA = Electron affinity; UL = Lattice energy; DHf = Enthalpy of formation)

  27. Covalent Bonds • Bonds between two nonmetals or between a semimetal and a nonmetal atoms • Bonds formed by sharing electron pairs; • One, two or three pairs of electrons shared between two atoms; • A pair of atoms may form single, double, or triple covalent bonds;

  28. Potential energy of H-atoms during the formation of H2 molecule

  29. Polarity of Covalent Bonds • Covalent bonds - polar or nonpolar; • Nonpolar covalent bonds - bonds between identical atoms or atoms having the same electronegativity. • Polar covalent bonds - bonds between atoms with different electronegativity;

  30. Polar Covalent Bonds • Bonds have partial ionic character • Bond polarity depends on DEN; DEN = differencein electronegativity of bonded atoms

  31. Electronegativity • Electronegativity =relative ability of bonded atom to pull shared electrons. Electronegativity Trend: increases left-to-right across periods; decreases down the group.

  32. Electronegativity Most electronegative element is at top right corner of Periodic Table Fluorine is most electronegative with EN = 4.0 Least electronegative element is at bottom left corner of Periodic Table Francium is least electronegative with EN = 0.7

  33. General trends: • Electronegativity increases from left to right across a period • For the representative elements (s and p block) the electronegativity decreasesas one goes down a group • Electronegativity trend for transition metals is less predictable.

  34. Electronegativity and Bond Polarity • In F2 electrons are shared equally and bond is nonpolar • In HF the fluorine is more electronegativity than hydrogen - electrons are drawn closer to fluorine. • H―F bond is very polar

  35. Electronegativity and bond polarity The H-F bond can thus be represented as: • The 'd+' and 'd-' symbols indicate partial positive and negative charges. • The arrow indicates the "pull" of electrons off the hydrogen and towards the more electronegative atom. • In lithium fluoride the much greater relative electronegativity of the fluorine atom completely strips the electron from the lithium and the result is an ionic bond (no sharing of the electron)

  36. Predicting Bond Type From Electronegativity General rule of thumb for bonds: • DEN = 0-0.5, bond is non-polar covalent; • DEN > 0.5, but < 2.0, bond is polar covalent • DEN > 2.0, bond is considered ionic.

  37. Potential Energy Diagram for Covalent Bond Formation

  38. Bond Length Bond length - distance between the nuclei of bonded atoms.  The larger the atoms that are bonded, the greater the bond length. Bond length: single bonds > double bonds > triple bonds . . .

  39. Bond Energy Bond energy - the energy required to break the bonds between two atoms.  The shorter the bond, the greater the bond energy. Bond energy: Triple bonds > double bonds > single bond

  40. Bond Length and Bond Energies • Bond length (pm) and bond energy (kJ/mol) • Bond Length Energy Bond Length Energy _________________________________________________________________________________________________________ • H─H 74 432 H─C 109 413 • C─C 154 347 H─N 101 391 • N─N 145 160 H─O 96 467 • O─O 148 146 H─F 92 565 • F─F 142 154 H─Cl 127 427 • Cl─Cl 199 243 H─Br 141 363 • Br─Br 228 193 H─I 161 295 • I─I 267 149        C─F 135 485 • C─S 182 259 C─Cl 177 339 • C─C 154 347 C─Br 194 276 • C─N 147 305 C─I 214 240 • C─O 143 358     C─C 154 347 • O─O 148 146 C=C 134 614 • O=O 121 495 C≡C 120 839     • C=O 123 745 N=N ? 418 • C=N 138 615 N≡N 110 945

  41. Bond Breaking and Bond Formation in the Reaction to form H2O

  42. Using Bond Energy to Calculate Enthalpy • Chemical reactions in the gaseous state only involve: the breaking of covalent bonds in reactants and the formation of covalent bonds in products. • Bond breaking requires energy • Bond formation releases energy DHreaction =S(Energy of bond breaking) + S(Energy of bond formation)

  43. Calculating Enthalpy ReactionUsing Bond Energy Example: use bond energy to calculate DH for the following reaction in gaseous state: CH3OH + 2 O2 CO2 + 2H2O; DHreaction =S{BE(in reactants)} - S{BE(in products)}

  44. Using bond energy to calculate enthalpy S{BE(in reactants) = 3 x BE(C─H) + BE(C─O) + BE(O─H) + 2 x BE(O═O) = (3 x 413) + 358 + 467 + (2 x 495) = 3054 kJ S{BE(in products) = 2 x BE(C═O)* + 4 x BE(O─H) = (2 x 799) + (4 x 495) = 3578 kJ DHreaction = S{BE(in reactants)} - S{BE(in products)} DHreaction = 3054  3578 = -524 kJ

  45. Lewis Structures for Molecules or Polyatomic ions Step-1: • Calculate number of valence electrons; • For polyatomic ions, add one additional electron for each negative charge, or subtract one for each positive charge on the ion.

  46. Lewis Structures for Molecules and Polyatomic ions Step-2: • Choose a central atom (the least electronegative atom) (Hydrogen and Fluorine cannot become central atoms) • Connect other atoms to the central atom with single bonds (a pair of electrons).

  47. Lewis Structures for Molecules and Polyatomic ions Step-3: • Complete the octet state of all terminal atoms, except hydrogen. • Place remaining pairs of electrons (if present) on central atom as lone pairs.

  48. Octet State of Central Atom Step-4: • If central atom has not acquired octet state but no more electrons available, move lone-pair electrons from terminal atoms, one pair at a time, to form double or triple bonds to complete octet of the central atom.

  49. Lewis Symbols and Formation of Covalent Molecules

  50. Lewis Structures of CH4, NH3 and H2O

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