9.4 Free electron model of metals

University physics volume 3 Page 1 / 9

By the end of this section, you will be able to:

Describe the classical free electron model of metals in terms of the concept electron number density
Explain the quantum free-electron model of metals in terms of Pauli’s exclusion principle
Calculate the energy levels and energy-level spacing of a free electron in a metal

Metals, such as copper and aluminum, are held together by bonds that are very different from those of molecules. Rather than sharing and exchanging electrons, a metal is essentially held together by a system of free electrons that wander throughout the solid. The simplest model of a metal is the free electron model . This model views electrons as a gas. We first consider the simple one-dimensional case in which electrons move freely along a line, such as through a very thin metal rod. The potential function U ( x ) for this case is a one-dimensional infinite square well where the walls of the well correspond to the edges of the rod. This model ignores the interactions between the electrons but respects the exclusion principle. For the special case of $T = 0 K,$ N electrons fill up the energy levels, from lowest to highest, two at a time (spin up and spin down), until the highest energy level is filled. The highest energy filled is called the Fermi energy .

The one-dimensional free electron model can be improved by considering the three-dimensional case: electrons moving freely in a three-dimensional metal block. This system is modeled by a three-dimensional infinite square well. Determining the allowed energy states requires us to solve the time-independent Schrödinger equation

- \frac{h^{2}}{2 m_{e}} (\frac{\partial^{2}}{\partial x^{2}} + \frac{\partial^{2}}{\partial y^{2}} + \frac{\partial^{2}}{\partial z^{2}}) ψ (x, y, z) = E ψ (x, y, z),

where we assume that the potential energy inside the box is zero and infinity otherwise. The allowed wave functions describing the electron’s quantum states can be written as

ψ (x, y, z) = (\sqrt{\frac{2}{L_{x}}} sin \frac{n_{x} π x}{L_{x}}) (\sqrt{\frac{2}{L_{y}}} sin \frac{n_{y} π y}{L_{y}}) (\sqrt{\frac{2}{L_{z}}} sin \frac{n_{z} π z}{L_{z}}),

where $n_{x}, n_{y},$ and $n_{z}$ are positive integers representing quantum numbers corresponding to the motion in the x -, y -, and z -directions, respectively, and $L_{x}, L_{y}, and L_{z}$ are the dimensions of the box in those directions. [link] is simply the product of three one-dimensional wave functions. The allowed energies of an electron in a cube $(L = L_{x} = L_{y} = L_{z})$ are

E = \frac{π^{2} ℏ^{2}}{2 m L^{2}} (n_{1}^{2} + n_{2}^{2} + n_{3}^{2}) .

Associated with each set of quantum numbers $(n_{x}, n_{y}, n_{z})$ are two quantum states, spin up and spin down. In a real material, the number of filled states is enormous. For example, in a cubic centimeter of metal, this number is on the order of $10^{22} .$ Counting how many particles are in which state is difficult work, which often requires the help of a powerful computer. The effort is worthwhile, however, because this information is often an effective way to check the model.

Energy of a metal cube

Consider a solid metal cube of edge length 2.0 cm. (a) What is the lowest energy level for an electron within the metal? (b) What is the spacing between this level and the next energy level?

Strategy

An electron in a metal can be modeled as a wave. The lowest energy corresponds to the largest wavelength and smallest quantum number:

n_{x}, n_{y}, n_{z} = (1, 1, 1) .

[link] supplies this “ground state” energy value. Since the energy of the electron increases with the quantum number, the next highest level involves the smallest increase in the quantum numbers, or

(n_{x}, n_{y}, n_{z}) = (2, 1, 1), (1, 2, 1),

or (1, 1, 2).

Solution

The lowest energy level corresponds to the quantum numbers

n_{x} = n_{y} = n_{z} = 1 .

From [link] , the energy of this level is

\begin{matrix} E (1, 1, 1) & = \frac{π^{2} h^{2}}{2 m_{e} L^{2}} (1^{2} + 1^{2} + 1^{2}) \\ = \frac{3 π^{2} {(1.05 \times 10 - 34 J \cdot s)}^{2}}{2 (9.11 \times 10^{−31} kg) {(2.00 \times 10^{−2} m)}^{2}} \\ = 4.48 \times 10^{−34} J = 2.80 \times 10^{−15} eV . \end{matrix}

The next-higher energy level is reached by increasing any one of the three quantum numbers by 1. Hence, there are actually three quantum states with the same energy. Suppose we increase $n_{x}$ by 1. Then the energy becomes

\begin{matrix} E (2, 1, 1) & = \frac{π^{2} h^{2}}{2 m_{e} L^{2}} (2^{2} + 1^{2} + 1^{2}) \\ = \frac{6 π^{2} {(1.05 \times 10 - 34 J \cdot s)}^{2}}{2 (9.11 \times 10^{−31} kg) {(2.00 \times 10^{−2} m)}^{2}} \\ = 8.96 \times 10^{−34} J = 5.60 \times 10^{−15} eV . \end{matrix}

The energy spacing between the lowest energy state and the next-highest energy state is therefore

E (2, 1, 1) - E (1, 1, 1) = 2.80 \times 10^{−15} eV .

Significance

This is a very small energy difference. Compare this value to the average kinetic energy of a particle,

k_{B} T

, where

k_{B}

is Boltzmann’s constant and T is the temperature. The product

k_{B} T

is about 1000 times greater than the energy spacing.

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Source: OpenStax, University physics volume 3. OpenStax CNX. Nov 04, 2016 Download for free at http://cnx.org/content/col12067/1.4

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