Atkins & de Paula: Atkins' Physical Chemistry 9e. Checklist of key ideas. Chapter
7: Quantum Theory: Introduction and Principles ...
Atkins & de Paula: Atkins’ Physical Chemistry 9e Checklist of key ideas Chapter 7: Quantum Theory: Introduction and Principles
Chapter 7: Quantum Theory: Introduction and Principles � classical mechanics, the laws of motion introduced in the seventeenth century by Isaac Newton. � quantum mechanics, the laws of motion introduced in the twentieth century by Heisenberg and Schrödinger.
THE ORIGINS OF QUANTUM MECHANICS � electromagnetic field, an oscillating electric and magnetic disturbance that spreads as a harmonic wave through space. � electric field, a field that acts on charged particles. � magnetic field, a field that acts on moving charged particles.
Chapter 7: Quantum Theory: Introduction and Principles � wavelength, λ, the peak-to-peak distance of a wave. � frequency, v, the number of times per second that a displacement returns to its initial value. � wavenumber, vɶ , the reciprocal of the wavelength. � electromagnetic spectrum, the range of frequencies exhibited by the electromagnetic field and its classification into regions. 7.1 The failures of classical physics � black body, an object capable of emitting and absorbing all frequencies of radiation uniformly.
Chapter 7: Quantum Theory: Introduction and Principles 7.1 The failures of classical physics (cont…) � Rayleigh–Jeans law, dE = ρdλ, ρ = 8πkT/λ 4. � density of states, ρ, the proportionality constant between the range of wavelengths and the energy density in that range: dE = ρdλ. � ultraviolet catastrophe, the divergence of the energy density of black-body radiation at high frequencies. � quantization of energy, the limitation of energies to discrete values. � Planck’s constant, h = 6.626 08 × 10–34 J s.
Chapter 7: Quantum Theory: Introduction and Principles
7.1 The failures of classical physics (cont..) � Planck distribution, dE= ρdλ, ρ = (8πhc/λ5)/(ehc/λkT – 1). � Dulong and Petit’s law: the molar heat capacities of all monatomic solids are the same, and close to 25 J K–1 mol–1. � Einstein formula, CV,m = 3Rf, f = (θE/T)2{eθ_E/2T/(eθ_E/T – 1)} � Einstein temperature, θE = hv/k. 3
T � Debye formula, CV,m = 3Rf, f = 3 θD
∫
θD / T
0
x 4e x
(e
x
)
−1
2
dx .
Chapter 7: Quantum Theory: Introduction and Principles 7.1 The failures of classical physics (cont..)
� Debye temperature, θD = hvD/k. � spectrum, the record of intensity of light transmitted, absorbed, or scattered as a function of frequency, wavelength, or wavenumber. � spectroscopy, the detection and analysis of a spectrum. � spectroscopic transition, a change of state that gives rise to a feature in spectrum. � Bohr frequency transition, the relation between the change in energy and the frequency of the radiation emitted or absorbed: ∆E = hv.
Chapter 7: Quantum Theory: Introduction and Principles 7.2 Wave–particle duality � photon, a particle of electromagnetic radiation. � photoelectric effect, the ejection of electrons from metals when they are exposed to ultraviolet radiation: ½mev2 = hv – Φ. � work function, Φ, the energy required to remove an electron from the metal to infinity . � Davisson–Germer experiment, the diffraction of electrons by a crystal. � electron diffraction, the diffraction of electrons by an object in their path. � de Broglie relation, λ = h/p. � wave–particle duality, the joint particle and wave character of matter and radiation.
Chapter 7: Quantum Theory: Introduction and Principles THE DYNAMICS OF MICROSCOPIC SYSTEMS � wavefunction, ψ , a mathematical function obtained by solving the Schrödinger equation and which contains all the dynamical information about a system. 7.3 The Schrödinger equation � time-independent Schrödinger equation, –(ħ2/2m)(d2ψ/dx2) + V(x)ψ = Eψ. 7.4 The Born interpretation of the wavefunction � Born interpretation, the value of |ψ|2 at a point is proportional to the probability of finding the particle at that point.
Chapter 7: Quantum Theory: Introduction and Principles 7.4 The Born interpretation of the wavefunction (cont..)
� Born interpretation, the value of |ψ|2 at a point is proportional to the probability of finding the particle at that point. � probability density, the probability of finding a particle in a region divided by the volume of the region. � probability amplitude, the square-root of the probability density (the wavefunction itself). � normalization constant, N = 1/{∫ψ*ψ dx}1/2. � spherical polar coordinates, the radius r, the colatitude θ, and the azimuth φ. The volume element in spherical coordinates is r2sin θ drdθdφ. � quantization, confinement of a dynamical observable to discrete values.
Chapter 7: Quantum Theory: Introduction and Principles 7.4 The Born interpretation of the wavefunction (cont..)
� constraints on the wavefunction, the conditions a wavefunction must obey (be continuous, have a continuous first derivative, be single-valued, and be square-integrable). QUANTUM MECHANICAL PRINCIPLES 7.5 The information in a wavefunction � node, a point where a wavefunction passes through zero . � operator, something that carries out a mathematical operation on a function. � hamiltonian operator, the operator for the total energy of a system, Hˆ ψ = E ψ .
Chapter 7: Quantum Theory: Introduction and Principles 7.5 The information in a wavefunction (cont..)
ˆ ψ = ωψ . � eigenvalue, the constant ω in the eigenvalue equation Ω ˆ ψ = ωψ . � eigenfunction, the function ψ in the eigenvalue equation Ω ˆ ψ = ωψ . � eigenvalue equation, an equation of the form Ω
� observable, measurable properties of a system. � position operator, xˆ = x ×. � momentum operator, pˆx = (ħ/i)d/dx. � hermitian operator, an operator for which it is true that ∗ ∗ ˆ ∗ ˆ ψ Ωψ dx = ψ Ωψ dx
∫
i
j
{∫
j
i
}
Chapter 7: Quantum Theory: Introduction and Principles 7.5 The information in a wavefunction (cont..)
� orthogonal functions, ∫ψi*ψ j dτ = 0. � linear combination of two functions, c1f + c2g. � superposition, a linear combination of wavefunctions. � complete set of functions, functions that can be used to express any arbitrary function as a linear combination.
ˆ ψdτ . � expectation value, Ω = ∫ψ ∗Ω 7.6 The uncertainty principle � Heisenberg uncertainty principle: it is impossible to specify simultaneously, with arbitrary precision, both the 1 momentum and the position of a particle; ∆p∆q ≥ ℏ . 2
Chapter 7: Quantum Theory: Introduction and Principles 7.6 The uncertainty principle (cont..)
� wave packet, a localized wavefunction formed by superimposing a series of wavefunctions. � complementary observables, observables corresponding to non-commuting operators.
[
]
ˆ 1, Ω ˆ 2 = 0. � commuting operators, operators for which Ω
[
]
ˆ 1, Ω ˆ2 =Ω ˆ 1Ω ˆ 2 −Ω ˆ 2Ω ˆ1 � commutator, Ω
� general form of the Heisenberg uncertainty principle: 1 ˆ ˆ ∆Ω 1∆Ω 2 ≥ Ω1 , Ω 2 2
[
]
Atomic Units
SI
atomic unit
h →1 2π m e = 9.10938 ×10 -31 kg → 1 ℏ=
mass of an electron : charge :
e (1.602176 ×10 -19 C ) → 1
4πε 0 ℏ 2 -11 length : Bohr radius a 0 = = 5 . 29177 × 10 m →1 2 me e vacuum permittivi ty ε 0 : 4πε 0 → 1 energy : 27.21eV = 627.5095kc al/mol = 4.184 × 627.5095 × 10 3 J/mol = 1 hartree
