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Semiconductors01:22

Semiconductors

There is variation in the electrical conductivity of materials - metals, semiconductors, and insulators that are showcased with the help of the energy band diagrams.
Metals such as copper (Cu), zinc (Zn), or lead (Pb) have low resistivity and feature conduction bands that are either not fully occupied or overlap with the valence band, making a bandgap non-existent. This allows electrons in the highest energy levels of the valence band to easily transition to the conduction band upon gaining...
Types of Semiconductors01:20

Types of Semiconductors

Intrinsic semiconductors are highly pure materials with no impurities. At absolute zero, these semiconductors behave as perfect insulators because all the valence electrons are bound, and the conduction band is empty, disallowing electrical conduction. The Fermi level is a concept used to describe the probability of occupancy of energy levels by electrons at thermal equilibrium. In intrinsic semiconductors, the Fermi level is positioned at the midpoint of the energy gap at absolute zero. When...
Electrical Conductivity01:13

Electrical Conductivity

In perfect conductors, the electric field inside is always zero due to the abundance of free electrons, which nullify any field by flowing. As a result, any residual charge resides on the surface.
In a practical conductor, an applied electric field may be sustained, causing a flow of electrons, which produce a current. The differential form of the current, the current density, is related to the electric field.
More generally, it is related to the force per unit charge, which involves the...
Metal-Semiconductor Junctions01:24

Metal-Semiconductor Junctions

The contact of metal and semiconductor can lead to the formation of a junction with either Schottky or Ohmic behavior.
Schottky Barriers
Schottky barriers arise when a metal with a work function (Φm) contacts a semiconductor with a different work function (Φs). Initially, electrons transfer until the Fermi levels of the metal and semiconductor align at equilibrium. For instance, if Φm > Φs, the semiconductor Fermi level is higher than the metal's before contact. The semiconductor's...
Band Theory02:35

Band Theory

When two or more atoms come together to form a molecule, their atomic orbitals combine and molecular orbitals of distinct energies result. In a solid, there are a large number of atoms, and therefore a large number of atomic orbitals that may be combined into molecular orbitals. These groups of molecular orbitals are so closely placed together to form continuous regions of energies, known as the bands.
The energy difference between these bands is known as the band gap.
Conductor, Semiconductor,...
Resistivity01:22

Resistivity

When a voltage is applied to a conductor, an electrical field is generated, and charges in the conductor feel the force due to the electrical field. The current density that results depends on the electrical field and the properties of the material. In some materials, including metals at a given temperature, the current density is approximately proportional to the electrical field. In these cases, the current density can be modeled as:

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Related Experiment Video

Updated: May 30, 2026

Fabrication of Nano-engineered Transparent Conducting Oxides by Pulsed Laser Deposition
10:27

Fabrication of Nano-engineered Transparent Conducting Oxides by Pulsed Laser Deposition

Published on: February 27, 2013

Conductivity in transparent oxide semiconductors.

P D C King1, T D Veal

  • 1School of Physics and Astronomy, University of St Andrews, North Haugh, St Andrews KY16 9SS, UK. philip.d.c.king@physics.org

Journal of Physics. Condensed Matter : an Institute of Physics Journal
|August 5, 2011
PubMed
Summary
This summary is machine-generated.

The origin of conductivity in transparent conducting oxides (TCOs) is still unclear. Hydrogen impurities and surface effects are emerging as key factors, challenging the long-held assumption of oxygen vacancies as the primary cause.

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Ohmic Contact Fabrication Using a Focused-ion Beam Technique and Electrical Characterization for Layer Semiconductor Nanostructures
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Ohmic Contact Fabrication Using a Focused-ion Beam Technique and Electrical Characterization for Layer Semiconductor Nanostructures

Published on: December 5, 2015

Area of Science:

  • Materials Science
  • Solid-State Physics
  • Semiconductor Engineering

Background:

  • Transparent conducting oxides (TCOs) are crucial for transparent electronics, but their high unintentional conductivity remains poorly understood despite decades of research.
  • Current efforts focus on enhancing conductivity, finding alternatives, and controlling carrier density for next-generation multifunctional devices.
  • Understanding the microscopic origins of carrier density is essential for TCO advancement.

Purpose of the Study:

  • To review recent developments in understanding the origins of conductivity in wide band gap TCO semiconductors.
  • To critically evaluate the role of oxygen vacancies and explore alternative contributors like hydrogen impurities and surface effects.
  • To discuss models explaining both bulk and surface conductivity in TCOs and their interplay with transparency.

Main Methods:

  • Review of theoretical and experimental evidence from existing literature on TCO conductivity.
  • Analysis of defect and impurity contributions, including oxygen vacancies, native defects, complexes, and hydrogen.
  • Examination of surface conductivity phenomena and comparison with conventional semiconductors.

Main Results:

  • Evidence suggests oxygen vacancies may not be the sole or primary source of conductivity, potentially acting as deep donors.
  • Hydrogen impurities are identified as a leading contender for unintentional conductivity in various TCOs.
  • TCO surfaces can exhibit high carrier densities, significantly impacting conductivity in thin films and nanostructures.

Conclusions:

  • The understanding of TCO conductivity requires moving beyond the oxygen vacancy hypothesis to include hydrogen and surface contributions.
  • Further research is needed to clarify the stability and site occupancy of hydrogen in TCOs.
  • A comprehensive understanding of bulk and surface conductivity, and its relationship with transparency, is vital for TCO design and application.