Glossary

5.3 Nearly free electron model

6 min readaugust 20, 2024

The extends the free electron model by incorporating weak periodic potentials from crystal lattices. It explains energy bands, gaps, and Brillouin zones, providing a more accurate description of electronic properties in solids.

This model introduces concepts like Bloch functions, , and Fermi surfaces. While it has limitations for strongly correlated systems, it remains useful for understanding , insulators, and simple , forming a basis for more advanced theories.

Origin of nearly free electron model

  • Developed as an extension of the free electron model to account for the periodic potential of the crystal lattice
  • Incorporates the effect of the weak periodic potential on the electron wave functions and energy levels
  • Provides a more accurate description of the electronic properties of solids compared to the free electron model

Assumptions in nearly free electron model

Weak periodic potential

Top images from around the web for Weak periodic potential

  • solid state physics - Bands in semiconductors: $E$ vs. $k$ diagram - Physics Stack Exchange View original

    Is this image relevant?

  • Nearly free electron model - Wikipedia View original

    Is this image relevant?

  • solid state physics - Bands in semiconductors: $E$ vs. $k$ diagram - Physics Stack Exchange View original

    Is this image relevant?

1 of 3

Top images from around the web for Weak periodic potential

  • solid state physics - Bands in semiconductors: $E$ vs. $k$ diagram - Physics Stack Exchange View original

    Is this image relevant?

  • Nearly free electron model - Wikipedia View original

    Is this image relevant?

  • solid state physics - Bands in semiconductors: $E$ vs. $k$ diagram - Physics Stack Exchange View original

    Is this image relevant?

1 of 3
  • The periodic potential due to the crystal lattice is assumed to be weak compared to the kinetic energy of the electrons
  • The weak periodic potential causes small perturbations to the free electron wave functions and energy levels
  • The perturbations lead to the formation of energy bands and gaps in the electronic structure

Electron wave functions

  • The electron wave functions are assumed to be similar to those of free electrons, with slight modifications due to the periodic potential
  • The wave functions are described by Bloch functions, which are plane waves modulated by a periodic function with the same periodicity as the lattice
  • The Bloch functions satisfy the Schrödinger equation in the presence of the weak periodic potential

Consequences of weak periodic potential

Bragg planes

  • The weak periodic potential leads to the formation of Bragg planes in reciprocal space
  • Bragg planes are defined by the condition 2kG=G22\mathbf{k} \cdot \mathbf{G} = G^2, where k\mathbf{k} is the electron wave vector and G\mathbf{G} is a reciprocal lattice vector
  • Electron waves undergo Bragg reflection at the Bragg planes, leading to the formation of standing waves and energy gaps

Energy gaps

  • The Bragg reflection at the Bragg planes results in the opening of energy gaps at specific wave vectors
  • The energy gaps occur at the boundaries of the Brillouin zones, which are defined by the Bragg planes
  • The size of the energy gaps depends on the strength of the periodic potential and the magnitude of the reciprocal lattice vectors

Brillouin zones

  • The Brillouin zones are the primitive cells of the reciprocal lattice, constructed using the Bragg planes as boundaries
  • The first is the Wigner-Seitz cell of the reciprocal lattice, containing all unique wave vectors
  • Higher-order Brillouin zones are obtained by translating the first Brillouin zone by reciprocal lattice vectors

E-k diagram

Reduced and periodic zone schemes

  • The E-k diagram represents the relationship between the electron energy and wave vector in the nearly free electron model
  • The reduced zone scheme shows the energy bands and gaps within the first Brillouin zone
    • The energy bands are folded back into the first Brillouin zone at the zone boundaries
    • The reduced zone scheme emphasizes the periodicity of the energy bands in reciprocal space
  • The periodic zone scheme shows the energy bands and gaps in extended
    • The energy bands are repeated periodically in reciprocal space
    • The periodic zone scheme provides a more intuitive representation of the electronic structure

Energy bands and gaps

  • The E-k diagram consists of energy bands separated by energy gaps
  • The energy bands represent the allowed energy states for electrons in the solid
  • The energy gaps represent the forbidden energy states, where no electron states exist
  • The width of the energy bands and the size of the energy gaps depend on the strength of the periodic potential

Effective mass

Definition of effective mass

  • The effective mass is a concept used to describe the response of electrons to external forces in a solid
  • It is defined as the inverse of the second derivative of the energy with respect to the wave vector: m=2(2Ek2)1m^* = \hbar^2 \left(\frac{\partial^2 E}{\partial k^2}\right)^{-1}
  • The effective mass can be positive (electron-like) or negative (hole-like), depending on the curvature of the energy bands

Calculation from E-k diagram

  • The effective mass can be calculated from the E-k diagram by fitting a parabola to the energy bands near the band extrema
  • For a parabolic band, the effective mass is constant and given by m=2(2Ek2)1m^* = \hbar^2 \left(\frac{\partial^2 E}{\partial k^2}\right)^{-1}
  • For non-parabolic bands, the effective mass varies with the wave vector and can be obtained by numerical differentiation of the E-k diagram

Density of states

Effect of energy bands on density of states

  • The (DOS) represents the number of electronic states per unit energy interval
  • The shape of the energy bands in the E-k diagram determines the density of states
  • The DOS is high near the band edges, where the energy bands are relatively flat
  • The DOS is low in the middle of the energy bands, where the bands are more dispersive

Van Hove singularities

  • Van Hove singularities are sharp peaks or discontinuities in the density of states
  • They occur at critical points in the Brillouin zone, where the gradient of the energy band vanishes (kE=0)(\nabla_k E = 0)
  • The type of Van Hove singularity depends on the local topology of the energy band (saddle points, maxima, or minima)
  • Van Hove singularities can have significant effects on the electronic and optical properties of solids

Fermi surfaces

Construction of Fermi surfaces

  • The is the surface in reciprocal space that separates the occupied and unoccupied electronic states at zero temperature
  • It is constructed by plotting the wave vectors of the highest occupied electronic states in the Brillouin zone
  • The shape of the Fermi surface depends on the electronic structure and the filling of the energy bands
  • Fermi surfaces can have various topologies (closed surfaces, open surfaces, or a combination of both)

Electron and hole pockets

  • Electron pockets are regions of the Fermi surface where the energy bands are electron-like (positive curvature)
  • Hole pockets are regions of the Fermi surface where the energy bands are hole-like (negative curvature)
  • The presence of electron and hole pockets indicates the existence of multiple types of charge carriers in the solid
  • The size and shape of the electron and hole pockets can be determined from the Fermi surface topology

Limitations of nearly free electron model

Strongly correlated systems

  • The nearly free electron model assumes weak electron-electron interactions and a weak periodic potential
  • In strongly correlated systems (transition metal oxides, heavy fermion materials), the electron-electron interactions are strong and cannot be neglected
  • The nearly free electron model fails to capture the complex electronic properties of strongly correlated systems, such as metal-insulator transitions and unconventional superconductivity

Failures in describing band gaps

  • The nearly free electron model often underestimates the size of the band gaps in semiconductors and insulators
  • This is because the model assumes a weak periodic potential, which may not be sufficient to describe the strong ionic potentials in these materials
  • More advanced models (, density functional theory) are needed to accurately predict the band gaps and electronic structure of semiconductors and insulators

Applications of nearly free electron model

Semiconductors and insulators

  • The nearly free electron model can provide a qualitative understanding of the electronic structure of semiconductors and insulators
  • It explains the formation of energy bands and gaps, which are crucial for the electronic properties of these materials
  • The model can be used to estimate the effective masses of electrons and holes, which determine the transport properties
  • However, quantitative predictions of band gaps and other properties often require more sophisticated models

Metals and alloys

  • The nearly free electron model is particularly useful for describing the electronic structure of simple metals (alkali metals) and alloys
  • It can explain the formation of energy bands, the shape of the Fermi surface, and the presence of electron and hole pockets
  • The model can be used to calculate the density of states, which is important for understanding the electronic and thermal properties of metals
  • The nearly free electron model provides a foundation for more advanced models (pseudopotential theory) used to study the electronic structure of complex metals and alloys

Key Terms to Review (18)

Band Structure: Band structure refers to the range of energy levels that electrons can occupy in a solid and is fundamental to understanding the electrical, thermal, and optical properties of materials. This concept is crucial for explaining how symmetry operations affect electron behavior, how reciprocal lattice vectors define allowed states, and how various models such as free electron, tight-binding, and nearly free electron contribute to our understanding of materials. The implications of band structure extend to applications like quantum wells, wires, dots, and advanced materials like carbon nanotubes and graphene.
Bloch Theorem: Bloch Theorem states that the wave functions of electrons in a periodic potential, such as that found in a crystal lattice, can be expressed as a product of a plane wave and a function with the same periodicity as the lattice. This theorem is fundamental in solid state physics as it describes how electrons behave in crystalline materials, linking to concepts like reciprocal lattice, energy bands, and effective mass.
Brillouin Zone: A Brillouin zone is a uniquely defined region in reciprocal space that represents the set of points in momentum space where wave vectors can be considered equivalent due to periodicity in a crystal lattice. It provides critical insights into the electronic properties and phonon dispersion of solids, facilitating the understanding of phenomena such as band structure, electron mobility, and collective excitations.
Conduction Band: The conduction band is the range of electron energy levels in a solid where electrons can move freely, allowing for electrical conductivity. When electrons gain enough energy, they can jump from the valence band to the conduction band, facilitating current flow in materials like metals and semiconductors. The presence and width of the conduction band are crucial in determining the electrical properties of materials.
Density of States: Density of states (DOS) is a concept that quantifies the number of available quantum states per unit energy interval for particles in a system, typically electrons or phonons. It is crucial in understanding how particles populate energy levels and significantly influences the physical properties of solids, impacting phenomena like conductivity and specific heat.
Effective mass: Effective mass is a concept in solid-state physics that describes how the motion of charge carriers, like electrons and holes, behaves under the influence of external forces in a periodic lattice. It simplifies the complex interactions within a crystal by allowing us to treat these carriers as if they have a different mass than their actual mass, making calculations and predictions about their behavior easier. This concept is crucial for understanding phenomena such as band structure, conductivity, and mobility in various materials.
Electron scattering: Electron scattering refers to the process in which electrons collide with atoms or other particles, leading to a change in their direction and energy. This phenomenon is crucial in understanding the behavior of electrons in materials and plays a significant role in the nearly free electron model, as it helps explain how electron motion is affected by periodic potentials in a crystal lattice.
Felix Bloch: Felix Bloch was a prominent physicist known for his contributions to solid state physics, particularly in the development of the nearly free electron model. His work significantly advanced the understanding of electron behavior in periodic potentials, paving the way for insights into band theory and the electronic properties of materials.
Fermi surface: The Fermi surface is a representation of the collection of quantum states in a solid at absolute zero temperature, marking the boundary between occupied and unoccupied electron energy levels. It plays a crucial role in understanding the electronic properties of metals and semiconductors, as well as their behavior under various conditions such as temperature and pressure.
Fourier Transform: The Fourier Transform is a mathematical operation that transforms a function of time (or space) into a function of frequency, allowing us to analyze the frequency components of signals or periodic structures. This transformation is essential in understanding how complex periodic structures, like crystals, can be decomposed into simpler sine and cosine functions, revealing their underlying symmetry and properties.
K-space: K-space, or reciprocal space, is a mathematical representation used in solid state physics to describe the wave vectors of particles, especially electrons, in a crystalline lattice. This space helps visualize and understand the properties of materials, including band structure and electron dynamics, by translating real space coordinates into a framework where periodic structures can be analyzed effectively. K-space is fundamental in connecting momentum and energy states of particles in a crystal lattice.
Metals: Metals are a group of elements characterized by their ability to conduct electricity and heat, exhibit ductility and malleability, and possess a shiny luster. These properties make metals crucial in various applications, including electronics, construction, and manufacturing. Understanding the behavior of metals in different conditions helps us grasp how they expand with heat, how they behave as electron conductors, and how defects can affect their overall properties.
Nearly free electron model: The nearly free electron model describes the behavior of electrons in a solid where the potential energy experienced by the electrons is only slightly perturbed from that of a free electron gas. This model is crucial for understanding how weak periodic potentials, such as those found in crystal lattices, influence the electronic band structure and ultimately the properties of materials.
Planck's constant: Planck's constant is a fundamental physical constant that relates the energy of a photon to its frequency, represented as $$E = h u$$, where $$E$$ is energy, $$h$$ is Planck's constant, and $$\nu$$ is frequency. This constant plays a crucial role in quantum mechanics, particularly in explaining phenomena like quantization of energy levels in systems such as harmonic oscillators and the behavior of electrons in solid-state physics.
Semiconductors: Semiconductors are materials that have electrical conductivity between that of conductors and insulators, allowing them to control the flow of electrical current. Their unique properties arise from their energy band structure, which includes the presence of a bandgap that can be manipulated through doping and temperature variations, making them essential for various electronic applications.
Tight-binding model: The tight-binding model is a theoretical framework used to describe the electronic properties of solids, focusing on how electrons can hop between localized atomic orbitals in a crystal lattice. This model helps explain the formation of energy bands in solids and is essential for understanding various phenomena, such as conductivity and band structure. It connects well with concepts like Brillouin zones, effective mass, and the Fermi surface, giving insight into how electrons behave in a periodic potential.
Valence Band: The valence band is the energy band in a solid that contains the electrons responsible for bonding between atoms. It plays a crucial role in determining the electrical and optical properties of materials, and its relationship with the conduction band influences conductivity, semiconducting behavior, and light absorption.
Walter Heitler: Walter Heitler was a prominent physicist known for his significant contributions to quantum mechanics and solid-state physics, particularly the nearly free electron model. His work played a crucial role in understanding the behavior of electrons in periodic potentials, which is essential for studying the electronic properties of materials.
© 2024 Fiveable Inc. All rights reserved.
AP® and SAT® are trademarks registered by the College Board, which is not affiliated with, and does not endorse this website.
Back
Practice QuizGlossary
Practice QuizGlossary
Next guide