News of Tungsten from website:
The
discovery is also the first demonstration of an "n-type" WSe2
field-effect-transistor (FET), showing the tremendous potential of this
material for future low-power and high-performance integrated circuits.
Monolayer
WSe2 is similar to graphene in that it has a hexagonal atomic structure
and derives from its layered bulk form in which adjacent layers are
held together by relatively weak Van der Waals forces. However, WSe2 has
a key advantage over graphene.
“In
addition to its atomically smooth surfaces, it has a considerable band
gap of 1.6 eV,” explained Kaustav Banerjee, professor of electrical and
computer engineering and Director of the Nanoelectronics Research Lab at
UCSB. Banerjee’s research team also includes UCSB researchers Wei Liu,
Jiahao Kang, Deblina Sarkar, Yasin Khatami and Professor Debdeep Jena of
Notre Dame. Their study was published in the May 2013 issue of Nano
Letters.
“There
is growing worldwide interest in these 2D crystals due to the many
possibilities they hold for the next generation of integrated
electronics, optoelectronics and sensors,” commented Professor Pulickel
Ajayan, the Anderson Professor of Engineering at Rice University
and a world renowned authority on nanomaterials. “This result is very
impressive and an outcome of the detailed understanding of the physical
nature of the contacts to these 2D crystals that the Santa Barbara group
has developed.”
“Understanding
the nature of the metal-TMD interfaces was key to our successful
transistor design and demonstration,” explained Banerjee. Banerjee’s
group pioneered a methodology using ab-initio Density Functional Theory
(DFT) that established the key criteria needed to evaluate such
interfaces leading to the best possible contacts to the monolayer TMDs.
The
DFT technique was pioneered by UCSB professor emeritus of physics Dr.
Walter Kohn, for which he was awarded the Nobel Prize in Chemistry in
1998. “At a recent meeting with Professor Kohn, we discussed how this
relatively new class of semiconductors is benefitting from one of his
landmark contributions,” said Banerjee.
Wei
Liu, a post-doctoral researcher in Banerjee’s group and co-author of
the study, explained, "Guided by the contact evaluation methodology we
have developed, our transistors achieved ON currents as high as 210
uA/um, which are the highest reported value of drive current on any
monolayer TMD based FET to date.” They were also able to achieve
mobility of 142 cm2/V.s, which is the highest reported value for any
back-gated monolayer TMD FET.
“DFT
simulations provide critical insights to the various factors that
effectively determine the quality of the interfaces to these 2D
materials, which is necessary for achieving low contact resistances.”
added Jiahao Kang, a PhD student in Banerjee’s group and co-author of
the study.
“Nanoelectronics
and energy efficient computing technology are key areas of research at
UCSB, fields in which our faculty members are renowned for their
achievements. With these results, Professor Banerjee’s team continues to
make important research contributions to next-generation electronics,”
commented Rod Alferness, Dean of the College of Engineering at UCSB.
Their
research was supported by the National Science Foundation, the
California NanoSystems Institute at UC Santa Barbara, and the Materials
Research Laboratory at UCSB: an NSF MRSEC.
没有评论:
发表评论