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CHEM 1311A E. Kent Barefield Course web page http://web.chemistry.gatech.edu/~barefield/1311/chem1311a.html Two requests: cell phones to silent/off no lap tops in operation during class Bring your transmitter to class on Friday Outline for first exam period • • Atomic structure and periodic properties Structures and bonding models for covalent compounds of p-block elements – Lewis Structures, Valence Shell Electron Repulsion (VSEPR) concepts and oxidation state – – – Hybridization Composition and bond energies in binary p-block compounds Structure and bonding in organic compounds First Exam – Wednesday, September 10 Atomic structure and periodic properties • Early experiments concerning atomic structure and properties of electromagnetic radiation • • • • • • • Bohr model of the hydrogen atom Demise of Bohr model Wave equation and wave model for atom Wave functions and properties Orbital representations Multielectron atoms Periodic properties and their origin Properties of Atoms • Consist of small positively charged nucleus surrounded by negatively charged electrons, some at large distances from the nucleus • Nucleus consists of positively charged protons and neutral neutrons • • Charges of proton and electron are equal • The mass number of an atom is equal to the number of protons plus the number of neutrons • Isotopes are atoms with the same atomic number but different mass numbers, i.e., 1H, 2H, 3H or 12C, 13C, 14C The atomic number (and nuclear charge) of an atom is equal to the number of protons in its nucleus. Atomic Spectra Irradiation from electronically excited atoms is not continuous Visible region line spectra could be fitted to simple (empirical) formula 1/λ = 1.097 x 107 m-1 (1/22-1/n2) E = hc/λ = 2.178 x 10-18 J (1/22-1/n2) Later work showed several series of lines E = 2.178 x 10-18 J (1/n22-1/n12 ) (n2<n1) Spectrum of Electromagnetic Radiation Region Wavelength (Angstroms) Wavelength (centimeters) Frequency (Hz) Energy (eV) Radio > 109 > 10 < 3 x 109 < 10-5 Microwave 109 - 106 10 - 0.01 3 x 109 - 3 x 1012 10-5 - 0.01 Infrared 106 - 7000 0.01 - 7 x 10-5 3 x 1012 - 4.3 x 1014 0.01 - 2 Visible 7000 - 4000 Ultraviolet 4000 - 10 4 x 10-5 - 10-7 7.5 x 1014 - 3 x 1017 3 - 103 X-Rays 10 - 0.1 10-7 - 10-9 3 x 1017 - 3 x 1019 103 - 105 γ-Rays < 0.1 < 10-9 > 3 x 1019 > 105 7 x 10-5 - 4 x 10-5 4.3 x 1014 - 7.5 x 1014 2-3 Visible region of electromagnetic spectrum 400 nm 4000 Å 4x10-5 cm Blue green Green Yellow green Yellow Orange Red Purple Violet Indigo Blue 500 600 Wavelength, nm Red Blue Orange 400 Blue green Indigo Yellow Complementary color Violet Color of transmitted light Yellow green 700 nm 7000 Å 7x10-5 cm 700 800 Properties of Electromagnetic Radiation c = λν c = 2.998 x 108 m s-1 (vacuum); λ in meters; ν in cycles per sec or s-I 1 cycle per sec is 1 Hz (Hertz) E = hν = hc/λ With Einstein's relationship E = mc2 hc/λ = mc2 λ= h/mc Bohr Model Rule 1. Electron can exist in stationary states; requires fixed energy. Rule 2. Possible stationary states determined by quantization of angular momentum (mevr) in units of h/2π (mevr = nh/2π) Rule 3. Transitions between stationary states occur with emission or absorption of a quantum of energy, ΔE = hν For a stationary state to occur for the electron moving in a planetary orbital about the nucleus, the centripetal force must equal the electrostatic attraction of the electron by the nucleus or Employing the expression for angular momentum from Rule 2: Note that radius of orbits increase with n2 and decrease with Z Total Energy for atom (E) = Kinetic Energy (KE)+ Potential Energy (PE) from the previous slide so Substituting for r : E = -(2.18 x 10-18 J) Z2/n2 E = -(13.6 eV) Z2/n2 Constants me = 9.10939 x 10-11 kg e = 1.60218 x 10-19 C c = 8.8538 x 10-12 C2 m-1 J-1 h = 6.62608 x 10-34 J s 1 eV = 1.6022 x 10-19 J ΔE = final energy – initial energy ΔE = -13.6 Z2 eV (1/nf2 - 1/ni2) Further evidence for unique properties of light Photoelectric Effect K.E.(ejected electrons) = hν(impinging light) - w(work function) Compton Effect Momentum and energy conserved in collisions of light (photons) with electrons Demise of Bohr Model - Introduction of Wave Model Heisenberg Indeterminacy (Uncertainty) Principle Δx•Δ(mv) ≥ h/2π Exact position and exact momentum cannot both be known simultaneously De Broglie's Hypothesis λ = h/mv Particles have wave lengths; proof came from diffraction of electron beam Schroedinger's Wave Equation ∂2Ψ/∂x2 + ∂2Ψ/∂y2 + ∂2Ψ/∂z2 + 8π2m/h2(E-V)Ψ = 0 (HΨ=EΨ) Solution of this equation requires conversion to spherical polar coordinates and the introduction of three constants, which are what we know as quantum numbers, n, ℓ, mℓ Interpretation of Schrödinger equation solutions • • • Each combination of n, ℓ, and mℓ, value corresponds to an orbital n values relate to the energy and size of the orbitals. n = 1, 2, 3··· ℓ values specify the total angular momentum of the electron and determines the angular shape of the orbital. ℓ’s have letter equivalents: ℓ = 0 (s), 1 (p), 2 (d), 3 (f), 4 (g), etc. ℓ = 0 ··· n-1 • mℓ, specifies the orientation of the orbitals in space and the angular momentum with respect to direction. mℓ = -ℓ··· 0 ··· +ℓ • With introduction of the fourth quantum number, ms = +1/2, -1/2 and the Pauli principle, which states that no two eIectrons in a given atom can have the same four quantum numbers, the development of electron configurations for multielectron atoms is straight-forward. • E = -me4Z2/8εo2n2h2 = -13.6 eV Z2/n2 Same as for Bohr model!!! Wave Functions ⎡ 4Z 3 (n − l − 1)! ⎤ Rn,l (r ) = ⎢ 4 3 3⎥ ⎢⎣ n ao [( n + l )! ] ⎥⎦ Ψn,ℓ,m (r,θ,φ) = Rn,ℓ(r)·Θℓ,m ·Φm ℓ 1/ 2 ⎛ 2Zr ⎜⎜ ⎝ nao ℓ ℓ ⎞ − Zr / nao 2l +1 ⎟⎟e Ln + l ⎠ R1,0(r) = 2Z3/2ao-3/2e-Zr/a o R2,0(r)= (1/2√2)Z3/2ao-3/2(2-Zr/ao)e-Zr/2a o R2,1(r) = (1/2√6)Z3/2ao-3/2(Zr/ao)e-Zr/2a o R3,0(r) = (1/4√3)Z3/2ao-3/2(27-18Zr/ao+2Z2r2/9ao2)e-Zr/3a o ℓ mℓ Θ φ Θℓ,mℓ(θ) = sinmℓ2·Pℓ(cos θ) 0 0 1/√2 1/√2π Φm (φ) = (1/√2π)e±imℓφ 1 0 (√3/2)cos θ 1/√2π 1 ±1 (√3/2)sin θ 1/√2πe±iφ 2 0 (√5/8)(3cos2θ-1) 1/√2π ℓ 1s Radial functions 30 6 25 5 20 4 R1,0(r) = 2ao-3/2e-r/a o 15 3 R1,02(r) = 4ao-3e-2r/a o 10 2 r2R1,02(r) = 4ao-3r2e-2r/a o 5 1 0 0 0 1 2 3 r, ao 4 5 Representation of the 1s orbital 2s Radial functions 3.5 3 2.5 2 1.5 1 0.5 0 -0.5 0.7 0.6 0.5 0.4 0.3 0.2 0.1 0 -0.1 R2,0(r)= (1/2√2)ao-3/2(2-r/ao)e-r/2a o R2,02(r)= (1/8)ao-3(4-2r/ao+r2/ao2)e-r/a o r2R2,02(r)= (1/8)ao-3(4-2r/ao+r2/ao2)r2e-r/a o 0 5 10 r, ao 15 Representations of p orbitals Θℓ,mℓ(θ) = sinmℓ2·Pℓ(cos Φm (φ) = (1/√2π)e±imℓφ ℓ θ) ℓ mℓ Θ φ 0 0 1/√2 1/√2π 1 0 (√3/2)cos θ 1/√2π 1 ±1 (√3/2)sin θ 1/√2πe±iφ 2 0 (√5/8)(3cos2θ-1) 1/√2π Representations of p orbitals Representations of orbitals Conical node in dz2 is a sum of two planes: dz2 = dz2–x2 + dz2–y2 Representations of orbitals (+) (-) (-) (+) (+) (+) (-) (+) (-) (+) (-) (+) (-) (-) (+) (+) (-) (-) (+) Comparison of ns radial distribution functions 1.2 1 1s 0.8 0.6 2s 0.4 3s 0.2 0 0 2 4 6 8 10 r, ao 12 14 16 18 Comparison of 1s, 2s and 2p radial distribution functions 1.2 1 1s 0.8 0.6 2p 0.4 2s 0.2 0 0 2 4 6 r, ao 8 10 12 Angular functions as contour maps • Angular nodes • Radial nodes • Relative size Contour plots of H 2p and C 2p 3 2 Contour lines are set at 0.316 of maximum values of Ψ2(r,θ,φ) 1 0 -1.5 -1 -0.5 0 -1 -2 -3 0.5 1 1.5 Multi-electron atoms; Aufbau Principle n=1 s H p 1 0.8 0.4 0.2 [He] Be [He] B [He] C [He] N [He] O [He] F s 1.2 0.6 He Li n=2 [He] Ne [He] 0 0 2 4 6 r, ao 8 10 12 More on multi-electron atoms • Electron configurations in the third period (n=3) mirror those for the second period • In the fourth period (n=4) the 3d orbital energies are lower than the 4p so that these orbitals fill before the 4p. The elements with d electrons are referred to as transition elements. • Electron configurations of the first transition element series are 4s23dn except for Cr and Cu, which are 4s13d5 and 4s13d10, respectively. These irregularities are a result of lower electronelectron repulsion energies. • All transition metal cations with + 2 or greater charge have dn electron configurations. Mn: [Ar]4s23d5 Mn2+: [Ar]4s03d5 Ti: Ti3+: [Ar]4s23d2 Ni: [Ar]4s23d8 [Ar]4s03d1 Ni2+: [Ar]4s03d8 The Periodic Table and the Aufbau Principle (n)s (n)p n =1 2 3 4 5 6 7 (n–2)f (n–1)d Periodic properties • • • • Ionization energy Atomic and ionic radii Electron Affinity Electronegativity Ionization energy Ionization energy is the minimum energy required to remove an electron from a gaseous atom (or other species). E = E+ + e2500 1500 1000 2500 500 2000 0 0 20 40 60 Z 80 IE/eV IE/kJ mol-1 2000 1500 1000 500 0 0 4 8 12 Z 16 Effective nuclear charge s & p orbital energies vs Z 0 -10 s p E/eV -20 Zeff = Z – shielding constant -30 -40 -50 -60 Li Be B C N O F Effective nuclear charges 1s 2s 2p H 1.0 Li 1.28 He 1.69 Be 1.91 B 2.58 2.42 C 3.22 3.14 N 3.85 3.83 O 4.49 4.45 F 5.13 5.10 Ne 5.76 5.76 Atomic and ionic radii Atomic radii as function of Z Radii of some common ions, Å Li+ 0.59 Be2+ 0.27 N31.71 O21.40 F1.33 Na+ 1.02 Mg2+ 0.72 Al3+ 0.53 P32.12 S21.84 Cl1.81 K+ 1.38 Ca2+ 1.00 Ga3+ 0.62 As32.22 Se21.98 Br1.96 Rb+ 1.49 Sr2+ 1.16 In3+ 0.79 Cs+ 1.70 Ba2+ 1.36 Tl3+ 0.88 Fe2+ 0.75, Fe3+ 0.69 I2.20 Radial distribution functions for alkali metal ions Electron affinity Electron affinity is the energy change associated with addition of an electron to a atom or ion. E + e- = E400 EA/kJ mol-1 300 200 100 0 -100 -200 H Li Be B C N O F Na Mg Al Si P S Cl K Ca Note that EA’s have been historically recorded as the negative of the energy associated with the electron attachment reaction. Electronegativity Electronegativity is the ability of an atom to attract electron density to itself in a chemical bond Pauling electronegativities H 2.20 Li 0.98 Be 1.57 B 2.04 C 2.55 N 3.04 O 3.44 F 3.98 Na 0.93 Mg 1.31 Al 1.61 Si 1.90 P 2.19 S 2.58 Cl 3.16 K 0.82 Ca 1.00 Ga 1.81 Ge 2.01 As 2.18 Se 2.55 Br 2.96 Rb 0.82 Sr 0.95 In 1.78 Sn 1.96 Sb 2.05 Te 2.10 I 2.66 Cs 0.79 Ba 0.89