Sub-mission:
Advance core understanding of cavitation–plasma coupling, energy pathways, and tunable water chemistries, while sharing results through responsible collaboration. AI tools are being developed and applied to accelerate PFAS research and support wider adoption of Plasmius technologies.

Status:

Early-stage R&D, with an expanding network of university collaborations and exploratory studies.

Active Research Areas

ROS/RNS Speciation
Investigating and tuning reactive oxygen and nitrogen species in Plasma-Activated Water (PAW) to achieve task-specific chemical outcomes for different treatment scenarios.

Standardized Bench Research Unit
Developing a compact High-Current Plasma (HCP) bench tool that can be loaned or ordered by universities and research labs. The goal is to enable consistent, reproducible experiments across institutions, supporting both mechanistic studies and application-driven research.

Element-Infusion Studies
Controlled addition of elements directly into the PAW reaction zone, exploring novel water chemistries and evaluating potential benefits for targeted applications in agriculture, water treatment, and environmental remediation.

Why This Matters

Fundamental research is the foundation for responsible innovation. By combining deep experimental science with modern AI tools, we aim to:

Map out the physics of cavitation–plasma interactions.

Clarify energy transfer and efficiency pathways.

Unlock new water treatment chemistries that are safer, tunable, and application-ready.

Provide open, collaborative tools for the research community.

AI-driven analytics and modeling also accelerate discovery by identifying promising conditions, predicting reaction dynamics, and guiding lab studies toward the most impactful directions.

Broader Vision

This work helps bridge scientific discovery and practical application. By building standardized research platforms and fostering open collaboration, Plasmius seeks to:

Empower universities, labs, and partners with shared tools.

Enable faster validation of novel plasma-water interactions.

Reduce barriers for translating deep research into scalable, real-world technologies.