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CHE-20028: PHYSICAL & INORGANIC CHEMISTRY QUANTUM CHEMISTRY: LECTURE 3

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Presentation on theme: "CHE-20028: PHYSICAL & INORGANIC CHEMISTRY QUANTUM CHEMISTRY: LECTURE 3"— Presentation transcript:

1 CHE-20028: PHYSICAL & INORGANIC CHEMISTRY QUANTUM CHEMISTRY: LECTURE 3
Dr Rob Jackson Office: LJ 1.16

2 Use of the Schrödinger Equation in Chemistry
The Schrödinger equation introduced What it means and what it does Applications: The particle in a box The harmonic oscillator The hydrogen atom CHE QC lecture 3

3 Learning objectives for lecture 3
What the terms in the equation represent and what they do. How the equation is applied to two general examples (particle in a box, harmonic oscillator) and one specific example (the hydrogen atom). CHE QC lecture 3

4 The Schrödinger Equation introduced
The equation relates the wave function to the energy of any ‘system’ (general system or specific atom or molecule). In the last lecture we introduced the wave function, , and defined it as a function which contains all the available information about what it is describing, e.g. a 1s electron in hydrogen. CHE QC lecture 3

5 What does the equation do?
It uses mathematical techniques to ‘operate’ on the wave function to give the energy of the system being studied, using mathematical functions called ‘operators’. The energy is divided into potential and kinetic energy terms. CHE QC lecture 3

6 The equation itself The simplest way to write the equation is: H = E
This means ‘an operator, H, acts on the wave function  to give the energy E’. Note – don’t read it like a normal algebraic equation! CHE QC lecture 3

7 More about the operator H
Remember, energy is divided into potential and kinetic forms. H is called the Hamiltonian operator (after the Irish mathematician Hamilton). The Hamiltonian operator contains 2 terms, which are connected respectively with the kinetic and potential energies. William Rowan Hamilton (1805–1865) CHE QC lecture 3

8 Obtaining the energy So when H operates on the wave function we obtain the potential and kinetic energies of whatever is being described – e.g. a 1s electron in hydrogen. The PE will be associated with the attraction of the nucleus, and the KE with ‘movement’ of the electron. CHE QC lecture 3

9 What does H look like? We can write H as:
H = T + V, where ‘T’ is the kinetic energy operator, and ‘V’ is the potential energy operator. The potential energy operator will depend on the system, but the kinetic energy operator has a common form: CHE QC lecture 3

10 The kinetic energy operator
The operator looks like: Which means: differentiate the wave function twice and multiply by means ‘h divided by 2’ and m is, e.g., the mass of the electron CHE QC lecture 3

11 Examples Use of the Schrödinger equation is best illustrated through examples. There are two types of example, generalised ones and specific ones, and we will consider three of these. In each case we will work out the form of the Hamiltonian operator. CHE QC lecture 3

12 Particle in a box The simplest example, a particle moving between 2 fixed walls: A particle in a box is free to move in a space surrounded by impenetrable barriers (red). When the barriers lie very close together, quantum effects are observed. CHE QC lecture 3

13 Particle in a box: relevance
2 examples from Physics & Chemistry: Semiconductor quantum wells, e.g. GaAs between two layers of AlxGa1-xAs  electrons in conjugated molecules, e.g. butadiene, CH2=CH-CH=CH2 References for more information will be given on the teaching pages. CHE QC lecture 3

14 See http://www.chem.uci.edu/undergrad/applets/dwell/dwell.htm
Particle in a box – (i) The derivation will be explained in the lecture, but the key equations are: (i) possible wavelengths are given by:  = 2L/n (L is length of the box), n = 1,2,3 ... See (ii) p = h/  = nh/2L (from de Broglie equation) CHE QC lecture 3

15 Particle in a box – (ii) (iii) the kinetic energy is related to p (momentum) by E = p2/2m Permitted energies are therefore: En = n2h2/8mL2 (with n = 1,2,3 ...) So the particle is shown to only be able to have certain energies – this is an example of quantisation of energy. CHE QC lecture 3

16 The harmonic oscillator
The harmonic oscillator is a general example of solution of the Schrödinger equation with relevance in chemistry, especially in spectroscopy. ‘Classical’ examples include the pendulum in a clock, and the vibrating strings of a guitar or other stringed instrument. CHE QC lecture 3

17 Example of a harmonic oscillator: a diatomic molecule
H H If one of the atoms is displaced from its equilibrium position, it will experience a restoring force F, proportional to the displacement. F = - kx where x is the displacement, and k is a force constant. Note negative sign: force is in the opposite direction to the displacement CHE QC lecture 3

18 Restoring force and potential energy
And by integration, we can get the potential energy: V(x) = k  x dx = ½ kx2 So we can write the Hamiltonian for the harmonic oscillator: H = CHE QC lecture 3

19 1-dimensional harmonic oscillator summarised
F = - kx where x is the displacement, and k is a force constant. Note negative sign: force is in the opposite direction to the displacement And by integration, we can get the potential energy: V(x) = k  x dx = ½ kx2 So we can write the Hamiltonian for the harmonic oscillator: H = CHE QC lecture 3

20 Allowed energies for the harmonic oscillator - 1
If we have an expression for the wave function of a harmonic oscillator (outside module scope!), we can use Schrödinger’s equation to get the energy. It can be shown that only certain energy levels are allowed – this is a further example of energy quantisation. CHE QC lecture 3

21 Allowed energies for the harmonic oscillator - 2
En = (n+½)   is the circular frequency, and n= 0, 1, 2, 3, 4 An important result is that when n=0, E0 is not zero, but ½ . This is the zero point energy, and this occurs in quantum systems but not classically – a pendulum can be at rest! CHE QC lecture 3

22 Allowed energies for the harmonic oscillator - 3
The energy levels are the allowed energies for the system, and are seen in vibrational spectroscopy. CHE QC lecture 3

23 Quantum and classical behaviour
Quantum behaviour (atomic systems) - characterised by zero point energy, and quantisation of energy. Classical behaviour (pendulum, swings etc) – systems can be at rest, and can accept energy continuously. We now look at a specific chemical system and apply the same principles. CHE QC lecture 3

24 The hydrogen atom Contains 1 proton and 1 electron. So there will be:
potential energy of attraction between the electron and the proton kinetic energy of the electron (we ignore kinetic energy of the proton - Born-Oppenheimer approximation). CHE QC lecture 3

25 The Hamiltonian operator for hydrogen - 1
H will have 2 terms, for the electron kinetic energy and the proton-electron potential energy H = Te + Vne Writing the terms in full, the most straightforward is Vne : Vne = -e2/40r (Coulomb’s Law) Note negative sign - attraction CHE QC lecture 3

26 The Hamiltonian operator for hydrogen - 2
The kinetic energy operator will be as before but in 3 dimensions: A shorthand version of the term in brackets is 2. We can now re-write Te and the full expression for H. CHE QC lecture 3

27 The Hamiltonian operator for hydrogen – 3
H = Te + Vne So, in full: H = (-ħ2/2m) 2 -e2/40r The Schrödinger equation for the H atom is therefore: {(-ħ2/2m) 2 -e2/40r}  = E  CHE QC lecture 3

28 Hamiltonians for molecules
When there are more nuclei and electrons the expressions for H get longer. H2+ and H2 will be written as examples. Note that H2 has an electron repulsion term: +e2/40r CHE QC lecture 3

29 (RH: Rydberg’s constant)
Energies and orbitals Solve Schrödinger’s equation using the Hamiltonian, and an expression for the wavefunction, : En = -RH/n2 (n=1, 2, 3 …) (RH: Rydberg’s constant) The expression for the wavefunction is: (r,,) = R(r) Y(, ) s-functions don’t depend on the angular part, Y(, ); only depend on R(r). CHE QC lecture 3

30 Conclusions on lecture
The Schrödinger equation has been introduced (and the Hamiltonian operator defined), and applied to: The particle in a box The harmonic oscillator The hydrogen atom In all cases, the allowed energies are found to be quantised. CHE QC lecture 3

31 Final conclusions from the Quantum Chemistry lectures
Two important concepts have been introduced: wave-particle duality, and quantisation of energy. In each case, experiments and examples have been given to illustrate the development of the concepts. CHE QC lecture 3


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