Rutgers & North Carolina University Food Science

Designed specifically for advanced research and production applications, this innovative system generates Plasma-Activated Water (PAW) with precision and efficiency. The compact unit integrates a high-performance power source (up to 1 kW) and supports PAW production of up to 3 liters per hour, making it ideal for laboratory and pilot-scale operations. Engineered for reliability, scalability, and ease of use, it empowers researchers in food science to explore sustainable solutions and cutting-edge applications for plasma technology.

Rutgers University Food Science

High-Capacity Plasma-Activated Water Production System for Agricultural Research

This advanced Plasma-Activated Water (PAW) system is designed for large-scale experimental applications, providing reliable and efficient plasma treatment for agricultural studies. Equipped with a power source of up to 3 kW, it enables the production of PAW in higher volumes, making it ideal for extensive field trials and greenhouse experiments. This system was successfully utilized for irrigation of research plants in controlled greenhouse environments, demonstrating its potential for enhancing sustainable agriculture and optimizing plant health through innovative plasma technology.

Drexel Plasma Institute

Plasma-Activated Water System for Produce Disinfection, designed for advanced food safety research, this integrated PAW system was developed to explore innovative methods for disinfecting fruits and vegetables. Combining plasma technology with a streamlined PAW generation unit, the system provides efficient and chemical-free disinfection, ensuring enhanced microbiological safety for fresh produce. Tailored for controlled laboratory experiments, it enables researchers to investigate the efficacy of plasma treatment in reducing contaminants while preserving food quality.

Rutgers University Food Science

This Dielectric Barrier Discharge (DBD) plasma system is designed for fog treatment applications, utilizing up to 1 kW power to generate reactive plasma species. The treated gas is then applied to plant foliage, enhancing disinfection and insect protection without the need for chemical pesticides. Engineered for precision and scalability, the system supports advanced agricultural research aimed at improving crop resilience and sustainable farming practices through plasma-based interventions.

Dielectric Barrier Discharge (DBD) 

High-Capacity Dielectric Barrier Discharge (DBD) Plasma Reactor for Ozone Generation

This advanced DBD plasma reactor is engineered for large-scale ozone production, utilizing a high-power discharge system to generate significant quantities of reactive oxygen species. Designed for industrial and research applications, it offers efficient ozone synthesis with precise control over plasma conditions, ensuring optimal performance for disinfection, air purification, and chemical processing.

Drexel Plasma Institute 

This DBD plasma-based purification system offers an advanced method for regenerating activated carbon, enabling its reuse instead of disposal. By leveraging high-energy plasma reactions, the system efficiently removes contaminants, restoring carbon’s adsorption capacity for secondary applications. This sustainable approach reduces waste and supports environmental conservation, demonstrating the potential of plasma technology in circular economy solutions.

Prototype Breathing System

Prototype Breathing System with UV Disposal for Infection Prevention

This innovative respiratory protection system integrates ultraviolet (UV) disposal technology to actively prevent bacterial and viral transmission. Designed for laboratory biological helmets, it functions bidirectionally - ensuring that healthy users remain protected from airborne pathogens while preventing contagious individuals from spreading bacteria. By utilizing UV sterilization, the system offers an advanced, chemical-free method for maintaining clean air pathways, making it ideal for research, healthcare, and high-containment environments.