Jove
Visualize
Contact Us
JoVE
x logofacebook logolinkedin logoyoutube logo
ABOUT JoVE
OverviewLeadershipBlogJoVE Help Center
AUTHORS
Publishing ProcessEditorial BoardScope & PoliciesPeer ReviewFAQSubmit
LIBRARIANS
TestimonialsSubscriptionsAccessResourcesLibrary Advisory BoardFAQ
RESEARCH
JoVE JournalMethods CollectionsJoVE Encyclopedia of ExperimentsArchive
EDUCATION
JoVE CoreJoVE BusinessJoVE Science EducationJoVE Lab ManualFaculty Resource CenterFaculty Site
Terms & Conditions of Use
Privacy Policy
Policies

Related Concept Videos

Interfacial Electrochemical Methods: Overview01:06

Interfacial Electrochemical Methods: Overview

Interfacial electrochemical methods focus on the phenomena occurring at the boundary between an electrode and a solution, as opposed to bulk methods that concentrate on the solution's overall properties. These interfacial methods are classified as either static or dynamic based on the presence of a nonzero current in the electrochemical cell and the consistency of analyte concentrations. Static methods, such as potentiometry, measure the cell's potential without any significant current passing...
Electrochemical Systems01:24

Electrochemical Systems

Electrochemical systems provide a fascinating insight into the dynamic interplay of charged species within various phases. One notable example is the interaction between a membrane permeable to K⁺ ions but not to Cl⁻ ions, separating an aqueous KCl solution from pure water. As K⁺ ions diffuse through the membrane, they generate net charges on each phase, leading to a potential difference between them.Similarly, when a piece of Zn is immersed in an aqueous ZnSO₄ solution, the Zn metal, composed...
Electrochemical Cells01:28

Electrochemical Cells

Electrochemical cells are systems that convert chemical energy into electrical energy or use electrical energy to drive chemical reactions. They consist of two electrodes in contact with an electrolyte, where redox reactions enable electron transfer. Most electrochemical cells include two half-cells connected by an external wire for electron flow and a salt bridge for ion flow. The salt bridge contains an electrolyte solution and maintains charge neutrality by allowing ions—not electrons—to...
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...
Design Example: Resistive Touchscreen01:14

Design Example: Resistive Touchscreen

A device engineer plays a crucial role in designing user interfaces for mobile devices. One such interface is the resistive touchscreen, which fundamentally consists of two metallic layers: a flexible upper layer and a rigid lower layer, separated by a narrow gap. The high resistance between these two layers is a key characteristic of this design.
When a user touches the screen, the two layers make contact at a specific point known as the touchpoint. This contact reduces the resistance between...
Types of Reversible Electrodes01:24

Types of Reversible Electrodes

For electrode reversibility to be maintained, all the reactants and products involved in the half-reaction must be present at the electrode. There are several types of reversible electrodes (half-cells).In metal-metal-ion electrodes, a metal balances electrochemically with a solution of its own ions. Examples are Cu2+|Cu and Zn2+|Zn. Metals that react with the solvent, like group 1 and most group 2 metals, which react with water, and zinc, which reacts with aqueous acidic solutions, cannot be...

You might also read

Related Articles

Articles linked to this work by shared authors, journal, and citation graph.

Sort by
Same author

Tuning Strain by Varying CaTiO<sub>3</sub> Thickness in Heteroepitaxially Grown La<sub>2/3</sub>Sr<sub>1/3</sub>MnO<sub>3</sub> Double-Clamped Resonators on Silicon.

ACS applied materials & interfaces·2026
Same author

Magnon interactions in a moderately correlated Mott insulator.

Nature communications·2024
Same author

Is Ba<sub>3</sub>In<sub>2</sub>O<sub>6</sub>a high-<i>T</i>superconductor?

Journal of physics. Condensed matter : an Institute of Physics journal·2024
Same author

Publisher Correction: Absence of 3a<sub>0</sub> charge density wave order in the infinite-layer nickelate NdNiO<sub>2</sub>.

Nature materials·2024
Same author

Absence of 3a<sub>0</sub> charge density wave order in the infinite-layer nickelate NdNiO<sub>2</sub>.

Nature materials·2024
Same author

Gapped Collective Charge Excitations and Interlayer Hopping in Cuprate Superconductors.

Physical review letters·2022
Same journal

Erratum for the Research Article "Detecting supramolecular organic nanoparticles during heat wave".

Science (New York, N.Y.)·2026
Same journal

Local signals, systemic decline.

Science (New York, N.Y.)·2026
Same journal

The mechanics of liver regeneration.

Science (New York, N.Y.)·2026
Same journal

Computing in a memory with physics.

Science (New York, N.Y.)·2026
Same journal

Retraction.

Science (New York, N.Y.)·2026
Same journal

Making time.

Science (New York, N.Y.)·2026
See all related articles

Related Experiment Video

Updated: Jun 14, 2026

Translating Extracellular Electron Transfer Activities with Organic Electrochemical Transistors
10:44

Translating Extracellular Electron Transfer Activities with Organic Electrochemical Transistors

Published on: January 31, 2025

Oxide interfaces--an opportunity for electronics.

J Mannhart1, D G Schlom

  • 1Center for Electronic Correlations and Magnetism, University of Augsburg, 86135 Augsburg, Germany. jochen.mannhart@physik.uni-augsburg.de

Science (New York, N.Y.)
|March 27, 2010
PubMed
Summary
This summary is machine-generated.

Complex oxide interfaces create unique electron systems with potential for future electronic devices. Research explores their properties, applications, and challenges in this emerging field.

More Related Videos

Bridging the Bio-Electronic Interface with Biofabrication
16:38

Bridging the Bio-Electronic Interface with Biofabrication

Published on: June 6, 2012

High Throughput Microfluidic Rapid and Low Cost Prototyping Packaging Methods
07:51

High Throughput Microfluidic Rapid and Low Cost Prototyping Packaging Methods

Published on: December 23, 2013

Related Experiment Videos

Last Updated: Jun 14, 2026

Translating Extracellular Electron Transfer Activities with Organic Electrochemical Transistors
10:44

Translating Extracellular Electron Transfer Activities with Organic Electrochemical Transistors

Published on: January 31, 2025

Bridging the Bio-Electronic Interface with Biofabrication
16:38

Bridging the Bio-Electronic Interface with Biofabrication

Published on: June 6, 2012

High Throughput Microfluidic Rapid and Low Cost Prototyping Packaging Methods
07:51

High Throughput Microfluidic Rapid and Low Cost Prototyping Packaging Methods

Published on: December 23, 2013

Area of Science:

  • Materials Science
  • Condensed Matter Physics
  • Solid-State Chemistry

Background:

  • Complex oxides exhibit unique electronic properties at interfaces.
  • Well-defined interfaces are crucial for emergent electron systems.
  • Recent advancements highlight the potential of oxide interfaces in electronics.

Purpose of the Study:

  • To review the current state of research on electron systems at complex oxide interfaces.
  • To discuss the fundamental properties and potential applications of these systems.
  • To identify challenges and future directions in the field of oxide electronics.

Main Methods:

  • Literature review of experimental and theoretical studies.
  • Analysis of key findings in the field of complex oxide interfaces.
  • Synthesis of information on device potential and challenges.

Main Results:

  • Extraordinary electron systems are reliably generated at complex oxide interfaces.
  • These interfacial electron systems possess tunable properties with device potential.
  • The field is rapidly advancing, with significant progress in understanding and application.

Conclusions:

  • Complex oxide interfaces are a promising platform for next-generation electronics.
  • Further research is needed to overcome challenges and realize full device potential.
  • This field represents a significant frontier in materials science and condensed matter physics.