Subsequent projects
Scalable fabrication of non-polarizing hybrid MoS2-SiO2 photonic crystal nanocavities for cavity enhanced valleytronics
University of Augsburg, Lehrstuhl für Experimentalphysik I
University of California, Riverside, Chemistry Department
During the final stage of our initial BaCaTeC project, we established the design and fabrication of novel hybrid MoS2-SiO2 photonic crystal nanocavities. Our devices also amplify the light emission from the optically active 2D semiconductor due to dramatic enhancement of the light-matter interaction. Our approach offers two unique advantages over alternative implementations:
- Our large-area grown 2D semiconductors enables fully scalable fabrication schemes. These in turn pave the way towards truly large scale nanophotonic circuits.
- The cavity material SiO2 is an isotropic optical material. Thus, we can use the polarization of light to directly program the spins of electron in the 2D semiconductor.
Our Subsequent Funding project is guided by the vision to jointly realize ultimately-scaled quantum photonic devices on this platform using fully scalable fabrication methods. Here, we can build on our newly established joint expertise: growth of 2D semiconductors, for instance MoS2 or WSe2, will be conducted at UC Riverside. The design and cleanroom fabrication of the hybrid photonic device, as well as the optical experiments will be performed at Universität Augsburg.
Primary project: Synthesis, spectroscopy and acousto-electric control of few- and monolayer MoS2 on LiNbO3