Our current work consists of:
- The use of chemical robotics driven combinatorial library for the discovery of new materials for different optoelectronic applications
- The characterization of ionic and electronic transport properties of hybrid organic-inorganic perovskites
- The synthesis and development of hybrid organic-inorganic perovskites for high radiation energy sensors
For more information, check out our publications.
The use of chemical robotics driving combinatorial library for the discovery of new perovskites within optoelectronic applications
- Utilize equipment commonly seen in the biological field to create combinatorial Libraries of hybrid perovskites
- High throughput characterization to characterize these libraries efficiently
- Use machine learning data analysis (after synthesis and characterization) to determine outliers and any areas of interest
The characterization of ionic and electronic transport properties of hybrid organic-inorganic perovskites using scanning probe microscopy techniques
- Utilize a variety of characterization techniques, such as scanning probe microscopy, to characterize local properties at the bulk and interfaces.
- Perform chemical imaging techniques, such as time-of-flight secondary ions spectrometry to understand ionic transport properties
- Study bulk transport properties with the focus on defects in collaboration with Charles University in Prague
The synthesis and development of hybrid organic-inorganic perovskites for high radiation energy sensors
- An advantage to using hybrid perovskite single crystals for radiation sensing is their comparatively low-cost of synthesis as compared to classical radiation sensors.
- These single crystals can be developed for both X-ray/gamma and neutron sensing.
