AI Article Synopsis
- Graphene's unique properties, including its atomic layer thickness and semi-metallic behavior, can enhance integrated photonic devices by offering Fermi-level tunability for electro-optic modulation.
- The research explores two main device architectures: one using graphene directly in contact with silicon for fast carrier injection, providing ultrafast modulation speeds, and another integrating graphene with lithium niobate to improve performance with minimal losses.
- The results indicate promising enhancements in modulation speed (up to 67 GHz) and efficiency (improved electro-optic field overlap coefficient with lower voltage requirements).
Article Abstract
The atomic layer thin geometry and semi-metallic band diagram of graphene can be utilized for significantly improving the performance matrix of integrated photonic devices. Its semiconductor-like behavior of Fermi-level tunability allows graphene to serve as an active layer for electro-optic modulation. As a low loss metal layer, graphene can be placed much closer to active layer for low voltage operation. In this work, we investigate hybrid device architectures utilizing semiconductor and metallic properties of the graphene for ultrafast and energy efficient electro-optic phase modulators on semiconductor and dielectric platforms. (1) Directly contacted graphene-silicon heterojunctions. Without oxide layer, the carrier density of graphene can be modulated by the directly contact to silicon layer, while silicon intrinsic region stays mostly depleted. With doped silicon as electrodes, carrier can be quickly injected and depleted from the active region in graphene. The ultrafast carrier transit time and small RC constant promise ultrafast modulation speed (3dB bandwidth of 67 GHz) with an estimated V·L of 1.19 V·mm. (2) Graphene integrated lithium niobite modulator. As a transparent electrode, graphene can be placed close to integrated lithium niobate waveguide for improving coupling coefficient between optical mode profile and electric field with minimal additional loss (4.6 dB/cm). Numerical simulation indicates 2.5× improvement of electro-optic field overlap coefficient, with estimated V of 0.2 V.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7608027 | PMC |
| http://dx.doi.org/10.1109/jstqe.2020.3026357 | DOI Listing |
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