Breaking the energy-bandwidth limit of electro-optic modulators: theory and a device proposal

TL;DR

This paper derives a fundamental energy-bandwidth limit for electro-optic modulators and proposes a dual cavity device that surpasses this limit, achieving ultra-low energy consumption at very high bandwidths.

Contribution

It introduces a theoretical energy-bandwidth limit for intra-cavity electro-optic modulators and proposes a novel dual cavity device to overcome this limit with high bandwidth and low energy.

Findings

Derived a formal energy-bandwidth limit (Eq. 10) for electro-optic modulators.

Proposed a dual cavity modulator device with >200 GHz bandwidth.

Achieved an ultra-low switching energy of 0.26 aJ, over three orders of magnitude better than current devices.

Abstract

In this paper, we quantitatively analyzed the trade-off between energy per bit for switching and modulation bandwidth of classical electro-optic modulators. A formally simple energy-bandwidth limit (Eq. 10) is derived for electro-optic modulators based on intra-cavity index modulation. To overcome this limit, we propose a dual cavity modulator device which uses a coupling modulation scheme operating at high bandwidth (> 200 GHz) not limited by cavity photon lifetime and simultaneously features an ultra-low switching energy of 0.26 aJ, representing over three orders of magnitude energy consumption reduction compared to state-of-the-art electro-optic modulators.