PHz Electronic Device Design and Simulation for Waveguide-Integrated Carrier-Envelope Phase Detection

TL;DR

This paper presents the design and simulation of integrated plasmonic nanoantennas coupled with waveguides for on-chip carrier-envelope phase detection, enabling compact, high-speed optical waveform measurements.

Contribution

It introduces a fully-integrated plasmonic nanoantenna-waveguide system for CEP detection, advancing from free-space to integrated photonic platforms.

Findings

Suitable for direct on-chip CEP detection with realistic sources

Estimated 30 dB signal-to-noise ratio at 50 kHz resolution

Analyzed effects of power loss and pulse parameters on sensitivity

Abstract

Carrier-envelope phase (CEP) detection of ultrashort optical pulses and low-energy waveform field sampling have recently been demonstrated using direct time-domain methods that exploit optical-field photoemission from plasmonic nanoantennas. These devices make for compact and integratable solid-state detectors operating at optical frequency that work in ambient conditions and require minute pulse energies (picojoule-level). Applications include frequency-comb stabilization, visible to near-infrared time-domain spectroscopy, compact tools for attosecond science and metrology and, due to the high electronic switching speeds, petahertz-scale information processing. However, these devices have been driven by free-space optical waveforms and their implementation within integrated photonic platforms has yet to be demonstrated. In this work, we design and simulate fully-integrated plasmonic bow-tie nanoantennas coupled to a Si$_3$N$_4$-core waveguide for CEP detection. We find that when coupled to realistic on-chip, few-cycle supercontinuum sources, these devices are suitable for direct time-domain CEP detection within integrated photonic platforms. We estimate a signal-to-noise ratio of 30 dB at 50 kHz resolution bandwidth. We address technical details, such as the tuning of the nanoantennas plasmonic resonance and the waveform's CEP slippage in the waveguide. Moreover, we evaluate power losses due to absorption and scattering and we study the device sensitivity to pulse duration and pulse peak field intensity. Our results provide the basis for future design and fabrication of time-domain CEP detectors and allow for the development of fully-integrated attosecond science applications, frequency-comb stabilization and light-wave-based PHz electronics.