A low-power integrated magneto-optic modulator on silicon for cryogenic applications

TL;DR

This paper introduces a low-power, integrated magneto-optic modulator on silicon operable at cryogenic temperatures, enabling efficient optical data transmission for quantum computing systems with minimal energy use.

Contribution

It presents the first current-driven magneto-optic modulator operating below 4 K, demonstrating high data rates and ultra-low power consumption suitable for quantum applications.

Findings

Operates at temperatures below 4 K with data rates up to 2 Gbps.

Energy consumption per bit can be reduced to below 40 fJ with optimization.

Potential to enable scalable, low-power optical links for quantum information systems.

Abstract

A fundamental challenge of the quantum revolution is to efficiently interface the quantum computing systems operating at cryogenic temperatures with room temperature electronics and media for high data-rate communication. Current approaches to control and readout of such cryogenic computing systems use electrical cables, which prevent scalability due to their large size, heat conduction, and limited bandwidth1. A more viable approach is to use optical fibers which allow high-capacity transmission and thermal isolation. A key component in implementing photonic datalinks is a cryogenic optical modulator for converting data from the electrical to the optical domain at high speed and with low power consumption, while operating at temperatures of 4 K or lower. Cryogenic modulators based on the electro-optic effect have been demonstrated in a variety of material platforms, however they are voltage driven components while superconducting circuits are current based, resulting in a large impedance mismatch. Here, we present the first demonstration of an integrated current-driven modulator based on the magneto-optic effect operating over a wide temperature range that extends down to less than 4 K. The modulator works at data rates up to 2 Gbps with energy consumption below 4 pJ/bit, and we show that this figure can be reduced to less than 40 fJ/bit with optimized design and fabrication. This modulator is a hybrid device, where a current-driven magneto-optically active crystal (cerium substituted yttrium iron garnet, or Ce:YIG) is bonded to a high-quality silicon microring resonator. Because of its potential for extremely low power consumption under cryogenic conditions, the class of magneto-optical modulators demonstrated here has the potential to enable efficient data links in large-scale systems for quantum information processing.