Many quantum computing and networking architectures employ photonic qubits with information encoded in polarization. Bradley Kerkhof, a grad student of UMD’s Electrical and Computer Engineering Department at the Institute for Research in Electronics and Applied Physics, utilized our 1343 nm Single-Frequency Raman Fiber Amplifier for their experiments in Quantum Frequency Conversion (QFC), where their aim is to create systems which allow for quantum networking experiments and proofs of concept. They used our amplifier to help pump both arms of the Sagnac loop to achieve phase stable, polarization diverse QFC. 

A wide array of our visible fiber lasers was used in an experiment to visualize 3D genome folding in situ in order to potentially identify new diagnostic and therapeutic biomarkers from 3D genomic architectures. Yale University utilized our 488 nm, 560 nm, 647 nm, and 750 nm visible fiber lasers for K-MADM-Trp53 lung chromatin tracing experiments. 

This paper discusses advancements in 4Pi single-molecule localization microscopy, which is a technique used to achieve super-resolution imaging. The authors introduced a method that improves the localization precision and accuracy of single molecules by using a coherent pupil-based localization approach. This enhancement allows for better three-dimensional imaging of biological samples at the nanoscale, which is crucial for understanding complex biological processes and structures.

This research presents a 325 nm high-power ultraviolet laser system for precise Rydberg excitation of ytterbium. The system leverages MPBC's Raman Fiber Amplifier, coupled with a waveguide SHG module, to efficiently convert wavelengths from 1300 nm to 650 nm as part of its two-stage frequency-doubling process. With over 800 mW output and low frequency noise, it demonstrates coherent excitation of the (6s71s)³S₁​ Rydberg state, enabling advancements in quantum simulation and computing.