Why do synthetic 2D materials often perform orders of magnitude worse than predicted? A new understanding of this scenario could improve the materials’ performance in future electronics, photonics, and memory storage.

2D materials are films only an atom or two thick. Researchers make 2D materials by the exfoliation method—peeling a slice of material off a larger bulk material—or by condensing a gas precursor onto a substrate. The former method provides higher-quality materials, but is not useful for making devices. The second method is well established in industrial applications, but yields low performance 2D films.

The researchers demonstrated, for the first time, why the quality of 2D materials grown by the chemical vapor deposition method have poor performance compared to their theoretical predictions. They report their results in Scientific Reports.

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Two discoveries could provide a simple and effective way to “stencil” high-quality 2D materials in precise locations and overcome a barrier to their use in next-generation electronics.

In 2004, the discovery of a way to isolate a single atomic layer of carbon—graphene —opened a new world of 2D materials with properties not necessarily found in the familiar 3D world. Among these materials are a large group of elements—transition metals—that fall in the middle of the periodic table.

When atoms of certain transition metals, for instance molybdenum, are layered between two layers of atoms from the chalcogenide elements, such as sulfur or selenium, the result is a three-layer sandwich called a transition metal dichalcogenide. TMDs have created tremendous interest among materials scientists because of their potential for new types of electronics, optoelectronics and computation.

“What we have focused on in this paper is the ability to make these materials over large areas of a substrate in precisely the places we want them,” says Joshua Robinson, associate professor of materials science and engineering at Penn State. “These materials are of interest for a variety of next-generation electronics, not necessarily to replace silicon, but to augment current technologies and ultimately to bring new chip functionality to silicon that we never had before.”

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Call for Papers: 2D Materials

Focus IssuesJSS Technical Editors: Fan Ren and Stefan De Gendt
and
Guest Editors: Lain-Jong (Lance) Li and Daniel S. P. Lau

invite you to submit to the:
JSS Focus Issue:
Properties, Devices, and Applications Based on 2D Layered Materials

Submission Deadline | May 18, 2016

This special issue of the ECS Journal of Solid State Science and Technology focuses on properties, devices, and applications of two-dimensional (2D) based materials including boron nitrides, black phosphorous, transition metal dichalcogenides/oxides, and other layered materials beyond graphene.

Review and contributed papers are welcome in the following domains:

  • Materials preparation
  • Novel growth technology
  • Growth chemistry
  • Metal contacts
  • Surface cleaning and passivation
  • Wet and dry etching
  • Device design and processing integration
  • Device Physics
  • Device and growth simulation
  • Applications of 2D material based devices and systems
  • Heterostructures based on 2D materials

Submission Deadline | May 18, 2016

Please submit manuscripts at http://ecsjournals.msubmit.net

(Be sure to specify your submission is for the JSS Focus Issue on Properties, Devices, and Applications Based on 2D Layered Materials.)

Papers accepted into this focus issue are published online within 10 days of acceptance. The issue is created online an article at a time with the final article published in October 2016.