Plasmonic Modulators in Cryogenic Environment Featuring Bandwidths in Excess of 100 GHz and Reduced Plasmonic Losses.
Dominik BisangYannik HorstMaurus ThürigKiran MenacheryStefan M KoepfliManuel KohliEva De LeoMarcel DestrazValentino TedaldiNino Del MedicoClaudia HoessbacherBenedikt BaeuerleWolfgang HeniJuerg LeutholdPublished in: ACS photonics (2024)
Cryogenic quantum applications have a demand for an ever-higher number of interconnects and bandwidth. Photonic links are foreseen to offer data transfer with high bandwidth, low heat load, and low noise to enable the next-generation scalable quantum computing systems. However, they require high-speed and energy-efficient modulators operating at cryogenic temperatures for electro-optic signal conversion. Here, plasmonic organic electro-optic modulators operating at 4 K are demonstrated with a >100 GHz bandwidth, drive voltages as low as 96 mV, and a significant reduction in plasmonic propagation losses by over 40% compared to room temperature. Up to 160 Gbit/s and 256 Gbit/s cryogenic electro-optic signal conversion are demonstrated by performing data experiments using a plasmonic Mach-Zehnder modulator at around 1528 nm and a plasmonic ring-resonator modulator at around 1285 nm, respectively. This work shows that plasmonic modulators are ideally suited for future high-speed, scalable, and energy-efficient photonic interconnects in cryogenic environments.
Keyphrases
- high speed
- energy transfer
- atomic force microscopy
- single molecule
- small molecule
- room temperature
- label free
- high resolution
- optical coherence tomography
- electronic health record
- molecular dynamics
- big data
- machine learning
- quantum dots
- artificial intelligence
- electron microscopy
- air pollution
- deep learning
- heat stress