Plasmonics provides a possible route to overcome both the speed limitations of electronics and the critical dimensions of photonics. We present an all-plasmonic 116-gigabits per second electro-optical modulator in which all the elements-the vertical grating couplers, splitters, polarization rotators, and active section with phase shifters-are included in a single metal layer. The device can be realized on any smooth substrate surface and operates with low energy consumption. Our results show that plasmonics is indeed a viable path to an ultracompact, highest-speed, and low-cost technology that might find many applications in a wide range of fields of sensing and communications because it is compatible with and can be placed on a wide variety of materials.
A scheme for the direct conversion
of millimeter and THz waves
to optical signals is introduced. The compact device consists of a
plasmonic phase modulator that is seamlessly cointegrated with an
antenna. Neither high-speed electronics nor electronic amplification
is required to drive the modulator. A built-in enhancement of the
electric field by a factor of 35 000 enables the direct conversion
of millimeter-wave signals to the optical domain. This high enhancement
is obtained via a resonant antenna that is directly coupled to an
optical field by means of a plasmonic modulator. The suggested concept
provides a simple and cost-efficient alternative solution to conventional
schemes where millimeter-wave signals are first converted to the electrical
domain before being up-converted to the optical domain.
We report on an optical chip-to-chip interconnect solution, thereby demonstrating plasmonics as a solution for ultra-dense, high-speed short-reach communications. The interconnect comprises a densely integrated plasmonic Mach-Zehnder modulator array that is packaged with standard driving electronics. On the receiver side, a germanium photodetector array is integrated with trans-impedance amplifiers. A multicore fiber provides a compact optical interface to the array. We demonstrate 4 × 20 Gb/s on-off keying signaling with direct detection.
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