posted on 2019-01-22, 00:00authored byDun Mao, Thomas Kananen, Tiantian Li, Anishkumar Soman, Jeffrey Sinsky, Nicholas Petrone, James Hone, Po Dong, Tingyi Gu
Electrically contacting
layered materials on a complementary metal-oxide-semiconductor transistor
(CMOS)-processed lateral silicon homojunction offers a new platform
enabling postfabrication-free high-speed hybrid optoelectronic devices
on chip. Understanding detailed junction formation and radiofrequency
(RF) response on the multicomponent interface between directly contacted
silicon nanophotonic devices and low-bandgap materials is essential
for predicting the performance of those active components. Electrostatic
carrier distribution as well as the dynamics of externally injected
carriers are strongly influenced by spatially varying Schottky barriers
on the vertical heterojunctions. In this work, we analyze the high-speed
RF response of a graphene “bonded” lateral silicon p-i-n
junction. The multijunction structure on the hybrid structure is parametrized
by fitting a small-signal model to the broadband coherent radio frequency
response of the hybrid device at a series of different carrier injection
rates. By engineering the device dimensions, it is possible to suppress
the resistance–capacitance delay to be less than a picosecond
and enable sub-terahertz bandwidth operation.