Light switches have only two stable positions: ‘on’ or ‘off’. Such
‘bistability’ provides an approach for implementing microscale switches in
novel electronic devices.
Faster signal storage and optical processing in nanomachined devices
edge closer to realization
A system that has only two
possible stable states, such as a light switch, is called bistable by
scientists and engineers. Bistability in microscale devices could pave the way
to compact optical switching and memory elements. In the bistable systems found
so far, however, switching between states takes too long to make the approach
practical. Now, thanks to the recent observation of bistability in an array of
micrometer-sized rings, fast microscale optical switches in novel photonic
devices are a step closer to development.
Yefeng Yu of the A*STAR Data
Storage Institute and his co-workers in Singapore and France observed this
bistability in a device consisting of two 60-micrometer-wide silicon rings into
which they could feed laser light of wavelengths specific to the particular
ring geometry they used1. One segment of each ring hung above a gap, and these
free-hanging arcs deformed slightly as light flowed through the ring. The
deformation of the rings, in turn, changed their optical properties. As a
result of this interplay between optical and mechanical forces, the researchers
observed stable behavior at two wavelengths of the light; not at one, as
expected. By changing the wavelength of the incoming light, Yu and co-workers
could conveniently switch between these two states.
“To our knowledge, this is the
first time that optical bistability has been induced by optical forces acting
on mechanical motion,” explains Yu. “Similar phenomena are usually produced by
thermal effects.” Relying on heating mechanisms, however, means that the
typical times required to switch between the two stable states are relatively
long, on the order of milliseconds. Using optical effects gave Yu and his
co-workers a much faster means to control the switching process. “The switching
time in our system is currently at the microsecond level,” says Yu. “But there
is some space for reducing this time through design optimization.”
This thousand-fold acceleration
should assist practical applications. The two stable states of the system, for
example, can be used to encode information in terms of ‘zeros’ and ‘ones’, as
it is in digital computers. But instead of using electrons to process
information, the two states of Yu and his co-workers’ optomechanical device
should allow the representation of information.
“We envisage using our new system
to implement optical logic gates for data processing,” Yu says. But there may
be many more possible uses for these devices. “Applications we want to explore
include tunable lasers, biosensor and optomechanical memories.”
The A*STAR-affiliated researchers
contributing to this research are from the Data Storage Institute
References
- Yu, Y. F., Zhang, J. B., Bourouina, T. & Liu
A. Q. Optical-force-induced bistability in nanomachined ring resonator
systems. Applied Physics Letters 100, 093108
(2012). | article
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