en.Wedoany.com Reported - Since pioneering gas injection treatment technology in 2008 and entering the recreational water market in 2012, AQUADEI has deployed nanobubble solutions across multiple sectors globally, including swimming pools and spas, agriculture, aquaculture, and lake and pond restoration. The company's core technology, Quantum Particle Technology™, generates billions of nanobubbles that remain suspended far longer than traditional aeration technologies, significantly enhancing the transfer efficiency of oxygen, ozone, and carbon dioxide into water.
AQUADEI's platform spans multiple industries: in the pool and spa sector, it achieves low-chemical water purification by injecting oxygen, ozone, and carbon dioxide; in agriculture, it increases dissolved oxygen to promote crop health; in aquaculture, it creates healthier fish environments and superior water quality; and in lake and pond restoration, it reverses conditions leading to harmful algal blooms through reoxygenation.
The company has established research partnerships with universities and federal agencies including Arizona State University, University of Notre Dame, California Polytechnic State University (Cal Poly), Pennsylvania State University (Penn State), University of Maine, University of Florida, the National Oceanic and Atmospheric Administration (NOAA), the U.S. Department of Agriculture (USDA), and the National Aeronautics and Space Administration (NASA). Notably, NOAA's research found that ozone nanobubble technology can effectively remediate harmful algal blooms, validating the core mechanism of AQUADEI's system. In August 2016, AQUADEI's patented technology was analyzed at the Photonics Department Laboratory of Osaka University in Japan, confirming bubble sizes on the order of 100 nanometers. Additionally, AQUADEI is the exclusive distributor of the Blase X nanobubble measurement unit in North America, a platform that combines Nanoparticle Tracking Analysis, Dynamic Light Scattering, and zeta potential analysis to detect and characterize nanobubbles at concentrations approaching one billion per milliliter.









