GHz-rate optical phase shift in light matter interaction-engineered, silicon-ferroelectric nematic liquid crystals

Organic electro-optic (OEO) materials have demonstrated promising performance in developing electro-optic phase shifters (EOPS) and modulators compared to their inorganic counterparts. Integration with other devices in a silicon photonic (SiP) process, simple nanofabrication, and temperature/aging robustness remain to be developed for this class of hybrid material platforms. In particular, electro-optic (EO) polymers need an electro-thermal poling method, which has limited their potential and utilization in large-scale SiP. Devices made of paraelectric nematic liquid crystals (PN-LC), another primary type of OEO material, feature a very efficient but slow phase shift mechanism. We present a general-purpose EOPS that applies to various modulator embodiments to address these concerns. Based on that, we report a GHz-fast phase shift in a newly discovered family of OEO, namely ferroelectric nematic liquid crystals (FN-LC), which finally enables liquid crystals to have significant second-order nonlinear optical coefficients and associated Pockels effect. The new material avoids poling issues associated with EO polymers and can pave the way for hybrid silicon-OEO systems with CMOS-foundry compatibility. Furthermore, we propose a finger-loaded, non-slotted waveguide that enhances light-matter interaction, allowing us to achieve DC and AC modulation efficiencies of ≈ 0.25 V.mm and 25.7 V.mm, respectively, an on-chip insertion loss of ≈ 4 dB, and an EO bandwidth of f_-6dB >4.18 GHz. The remaining figures of merit for our poling-free EOPS are equivalent to EO polymer-enabled devices with fewer manufacturing difficulties. We demonstrate an electrically and photonically packaged chip that contains >100 silicon-FN-LC modulators to evaluate the large-scale integration of our poling-free phase shifters and modulators.