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Posted: Apr 07, 2015

Nano-mechanical plasmonic phase modulator with potential for electronics

(Nanowerk News) Using standard semiconductor manufacturing equipment, a team from Argonne's Center for Nanoscale Materials (CNM), the National Institute of Standards and Technology (NIST), Rutgers University and the University of Colorado at Colorado Springs, has demonstrated a nano-mechanical plasmon phase modulator that can control and manipulate the flow of plasmons at the nanoscale without any degradation in optical performance. This novel device incorporates nano-mechanical elements to control the speed and wavelength of plasmons and may be a step towards faster computer architectures, as well as enabling other new electronics technologies ("Compact nanomechanical plasmonic phase modulators").
Optical interferometric picture of the actuated micromechanical bridges used to manipulate and control the flow of plasmons in the new plasmonic phase modulator
Optical interferometric picture of the actuated micromechanical bridges used to manipulate and control the flow of plasmons in the new plasmonic phase modulator. The device can introduce a maximum of 5 rad of phase modulation with low insertion and excess losses. (Image: Daniel López)
One of the critical technical barriers for integration of optical and electronic circuits is the large difference in sizes of their respective constitutive elements. Electronic circuit components transport information using electrons traveling down metallic nanostructures that can be fabricated at dimensions well below 100 nm. Optical circuits, on the other hand, use photons to transport information much faster than electrons, but the critical dimensions of its components need to be many times larger than the dimensions of conventional electronics (at least half the wavelength of the light). For smaller sizes, the propagation of light is obstructed by optical diffraction, which degrades the performance of the photonic circuits.
Tiny electron waves called plasmons may offer a solution to this size-compatibility problem, and have been considered potential candidates to merge electronics and photonics at the nanoscale. Plasmons combine the small size and manufacturability of electronics with the high speeds and data density of optics. They can be created by coupling light waves to electrons in metallic surfaces and can have dimensions much smaller than the wavelength of the original light, which opens the possibility of constructing miniaturized optoelectronic circuits with subwavelength components. To control and manipulate the flow of plasmons at the nanoscale still remains a very complicated task which is critical for nanophotonics optical communications architectures, on-chip optical switching, and reconfigurable plasmonic optics.
To begin to address this issue, the new nano-mechanical plasmon modulator consists of 11 deformable micron-size gold bridges suspended 270 nanometers on top of another metallic gold layer. Plasmons, created by a laser in the upper structure of the device, travel in the air-filled gap between the gold bridges and the bottom gold layer. When a voltage is applied, the bridges are electrostatically attracted toward the bottom layer, which reduces the size of the gap under the beams, slowing down the plasmons and reducing their wavelength. This effect can be used to selectively cancel the wave, allowing the devices to be used as an optical switch.
Nano-mechanical plasmon modulators incorporate nano-electro-mechanical-systems (NEMS) to precisely deform the path of a propagating plasmon. Since these NEMS were fabricated with conventional semiconductor fabrication processes and require actuation voltages compatible with the smallest high-speed transistors, the plasmon modulator can play a unique role as a building block for optoelectronic integration.
Although the current modulator is approximately 23 micrometers in length, calculations showed that the device could be shortened by a factor of 10, scaling the device’s footprint down by a factor of 100. By simultaneously reducing the device’s length and the size of the gap, the device’s modulation range was maintained without affecting its performance. The prototypes demonstrated that nano-mechanical phase tuning is efficient. This effect may be generalized to other tunable plasmonic devices that need to be made smaller, with more of them on the same chip, bringing them closer to practical applicaitons.
Small enough to serve in existing and future computer and communication architectures, this technology may also enable electrically tunable and switchable thin optical components that can be integrated into semiconductor devices using commercial semiconductor manufacturing processes. The prototypes were created using capabilities in CNM's Nanofabrication & Devices Group as well as at NIST.
Source: By Michelle Donovan, McMaster University
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