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e-book Integrated nanophotonic resonators : fundamentals, devices, and applications

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Introduction

This research involves any or all of fundamental theoretical work, rigorous device design, and experimental work. Nanophotonics may be able to address a number of major challenges in state-of-the-art microelectronics, as well as in next-generation telecom networks and future quantum information technologies including quantum communication and computation.

We are interested in device-level innovation that addresses major technological and fundamental challenges in these areas. Energy efficiency and power constraints are the factors limiting performance in modern electronic circuit design. Nanophotonics may in principle be able to provide energy efficient on-chip communication, but current photonic device technologies are far too power hungry.

Revolutionary device concepts and innovation are needed to achieve highly energy efficient devices that can enable future link budgets of a few femtojoules per bit.

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We are interested in new concepts and implementations of ultra-energy-efficient nanophotonic components for on-chip networks and communication links, including: Energy-efficient modulators and hitless switches for on-chip interconnects, analog signal processing and remote sensing High-fidelity passive components for on-chip communication such as waveguide crossing arrays, crossbars and switches High-efficiency fiber-chip and die-to-die optical waveguide coupling Ultra-sensitive CMOS-compatible detectors We have previously demonstrated the first high-index-contrast telecom-grade channel add-drop filters, the first polarization transparent nanophotonic circuit and true-hitless switch.

In previous work, we demonstrated the first nanophotonic devices in a 65nm bulk-Si CMOS process, and designed another chip recently fabricated in a 32nm process, through a collaboration with Profs.

Stojanovic and R. Ram at MIT. This research involves any or all of fundamental theoretical work, rigorous device design, and experimental device characterization. Beam forming and phased array concepts are well-known in microwave engineering.


  1. Integrated Nanophotonic Resonators: Fundamentals, Devices, and Applications - CRC Press Book!
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In the optical regime, there are new opportunities for leveraging these techniques, as well as new physics concepts to be employed to control far-field radiation. Diffractive nanophotonic elements have already been designed to provide efficient fiber-to-chip coupling through mode matching.

However, nanophotonic phased array concepts may have numerous other potential applications, from 3D imaging and sensing, through optical trapping and chip-scale quantum computing, to maskless lithography. We are interested in the design of novel nanophotonic radiative elements and devices that may address some of these technological opportunities. This research involves fundamental theoretical work, rigorous device design, and experimental work.

Photonics and Nanostructures - Fundamentals and Applications

For more information on these projects, please contact Milos Popovic. We are always interested in establishing the fundamental limitations on devices that rely on the physics of light. This also leads to insights into new device concepts and technologies such as time-variant and nonlinear systems like light-force-based nanooptomechanics which may not share all of the established limitations. For example, we have established a fundamental bound on a geometrical phase of the scattering matrix of a generic lossy photonic circuit.

This concept offers guidance in the design of efficient nanophotonic circuits, e. Similar considerations have led to the invention of loop-coupled resonant filters that can circumvent Kramers-Kronig amplitude-dispersion constraints, and of a new class of interferometers called universally balanced interferometers UBIs. We are also pursuing new research in a number of other directions that are not large enough to categorize as a separate area above. For more information on these and other projects, please contact Milos Popovic.

In previous work, we demonstrated the first nanophotonic devices in a 65nm bulk-Si CMOS process, and designed another chip recently fabricated in a 32nm process, through a collaboration with Profs.

Silicon nanophotonics for scalable quantum coherent feedback networks

Stojanovic and R. Ram at MIT. This research involves any or all of fundamental theoretical work, rigorous device design, and experimental device characterization. Beam forming and phased array concepts are well-known in microwave engineering.


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  • LOW-LOSS INTEGRATED PHOTONICS.
  • Nanophotonics.
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  • In the optical regime, there are new opportunities for leveraging these techniques, as well as new physics concepts to be employed to control far-field radiation. Diffractive nanophotonic elements have already been designed to provide efficient fiber-to-chip coupling through mode matching.

    However, nanophotonic phased array concepts may have numerous other potential applications, from 3D imaging and sensing, through optical trapping and chip-scale quantum computing, to maskless lithography. We are interested in the design of novel nanophotonic radiative elements and devices that may address some of these technological opportunities.

    This research involves fundamental theoretical work, rigorous device design, and experimental work. For more information on these projects, please contact Milos Popovic.

    Homepage of Svetlana V. Boriskina - publications

    We are always interested in establishing the fundamental limitations on devices that rely on the physics of light. This also leads to insights into new device concepts and technologies such as time-variant and nonlinear systems like light-force-based nanooptomechanics which may not share all of the established limitations. For example, we have established a fundamental bound on a geometrical phase of the scattering matrix of a generic lossy photonic circuit.

    This concept offers guidance in the design of efficient nanophotonic circuits, e.

    12222 Submission Categories

    Similar considerations have led to the invention of loop-coupled resonant filters that can circumvent Kramers-Kronig amplitude-dispersion constraints, and of a new class of interferometers called universally balanced interferometers UBIs. We are also pursuing new research in a number of other directions that are not large enough to categorize as a separate area above.

    For more information on these and other projects, please contact Milos Popovic.

    Harry A. Atwater plenary presentation: Tunable and Quantum Metaphotonics

    Research Overview We are interested in nanophotonic device concepts and circuit design motivated by challenges in system level applications in areas including telecommunications, on-chip interconnects, sensing and imaging, energy conversion and control, and classical and quantum computation and information processing. Active and Passive Nanophotonic Devices for Ultra-Energy-Efficient Communication and Computation Nanophotonics may be able to address a number of major challenges in state-of-the-art microelectronics, as well as in next-generation telecom networks and future quantum information technologies including quantum communication and computation.

    Nanophotonic Engineering and Control of Optical Radiation Beam forming and phased array concepts are well-known in microwave engineering. Photonic Circuit Theory We are always interested in establishing the fundamental limitations on devices that rely on the physics of light. Dual-microring resonator nanophotonic system designed to trap nanomechanical movable parts using light forces paper J Design of a trapping potential using light forces in a dual microring cavity; decorating the journal cover paper J Loop-coupled resonator concept also enables dispersionless slow-light structures that circumvent fundamental Kramers-Kronig constraints papers C