February 8, 2017 Shown above is the Internal Photoemission (IPE) Measurement System, developed by Hoon Hahn Yoon, combined M.S./Ph.D. student of Natural Science at UNIST. Credit: UNIST

A team of researchers affiliated with UNIST has created a new technique that greatly enhances the performance of Schottky diodes used in electronic devices. Their research findings have attracted considerable attention within the scientific community by solving the contact resistance problem of metal semiconductors, which had remained unsolved for almost 50 years.

As described in the January issue of Nano Letters, the researchers have created a new type of diode with a graphene insertion layer sandwiched between metal and semiconductor. This new technique supplants previous attempts, and is expected to significantly contribute to the semiconductor industry's growth.

The Schottky diode is one of the oldest semiconductor devices, formed by the junction of a semiconductor with a metal. However, due to the atomic intermixing along the interface between two materials, it is impossible to produce an ideal diode. Professor Kibog Park solved this problem by inserting a graphene layer at the metal-semiconductor interface. In the study, the research team demonstrated that this graphene layer, consisting of a single layer of carbon atoms, not only suppresses the material intermixing substantially, but also matches well with the theoretical prediction.

"The sheets of graphene in graphite have a space between each sheet that shows a high electron density of quantum mechanics, in that no atoms can pass through," says Professor Park. "Therefore, with this single-layer graphene sandwiched between the metal and semiconductor, it is possible to overcome the inevitable atomic diffusion problem."

According to Hoon Hahn Yoon, the first author, the study also confirms the prediction that "in the case of silicon semiconductors, the electrical properties of the junction surfaces hardly change regardless of the type of metal they use."

The internal photoemission method was used to measure the electronic energy barrier of the newly fabricated metal/graphene/n-Si(001) junction diodes. The internal photoemission (IPE) measurement system in the image shown above has contributed greatly to these experiments.

Explore further: New theory establishes a path to high-performance 2D semiconductor devices

More information: Hoon Hahn Yoon et al, Strong Fermi-Level Pinning at Metal/n-Si(001) Interface Ensured by Forming an Intact Schottky Contact with a Graphene Insertion Layer, Nano Letters (2017). DOI: 10.1021/acs.nanolett.6b03137

Researchers at the Energy Department's National Renewable Energy Laboratory (NREL) have uncovered a way to overcome a principal obstacle in using two-dimensional (2D) semiconductors in electronic and optoelectronic devices.

Adding hydrogen to graphene could improve its future applicability in the semiconductor industry, when silicon leaves off. Researchers at the Center for Multidimensional Carbon Materials (CMCM), within the Institute for Basic ...

An HZB team headed by Prof. Silke Christiansen has made a surprising discovery about hybrid organic/inorganic solar cells. Contrary to expectations, a diode composed of the conductive organic PEDOT:PSS and an n-type silicon ...

Following a decade of intensive research into graphene and two-dimensional materials a new semiconductor material shows potential for the future of super-fast electronics.

Researchers at the University of Tokyo demonstrate that using germanides of metals at the metal-germanium interface with suitable surface crystal planes, greatly improves the contact resistance and device performance germanium ...

The old rules don't necessarily apply when building electronic components out of two-dimensional materials, according to scientists at Rice University.

Molybdenum disulfide (MoS2), which is ubiquitously used as a solid lubricant, has recently been shown to have a two-dimensional (2D) form that is similar to graphene. But, when thinned down to less than a nanometer thick, ...

Researchers have introduced a new type of "super-resolution" microscopy and used it to discover the precise walking mechanism behind tiny structures made of DNA that could find biomedical and industrial applications.

For the first time, Lawrence Livermore National Laboratory scientists and collaborators have captured a movie of how large populations of carbon nanotubes grow and align themselves.

Cellphones and other devices could soon be controlled with touchless gestures and charge themselves using ambient light, thanks to new LED arrays that can both emit and detect light.

Positron emission tomography plays a pivotal role for monitoring the distribution and accumulation of radiolabeled nanomaterials in living subjects. The radioactive metals are usually connected to the nanomaterial through ...

Last summer, researchers at the Harvard John A. Paulson School of Engineering and Applied Sciences (SEAS) announced a new, flat lens that could focus light with high efficiency within the visible spectrum. The lens used an ...

Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Read more here:

Engineering dream diodes with a graphene interlayer - Phys.org - Phys.Org