Applications

NEAT formulations use patented TAML catalysts to intensify oxidation processes while improving efficiencies and reducing costs in many industries.

Pharmaceutical Waste Removal

NEAT has been shown to effectively oxidize 20+ compounds across 10+ drug classes, at a lower cost than conventional treatment options. With NEAT, results are achievable in 30-240 minutes, at both low and high concentrations.

ELECTROCHEMICAL + NEAT

Recycled Fiber Bleaching

With NEAT, recycled fiber manufacturers can expand feedstock sources, reduce quality constraints, and remove a wide range of feedstock contaminants including phenols.

Low Temperature Textile Bleaching

Conventional textile bleaching is energy, water, and chemical intensive and produces significant material waste. With NEAT, manufacturers can dramatically reduce energy and water use, replace use of harsh chemicals, return higher fiber yields, and reduce total costs.

Wastewater Dye Removal

With low-dose NEAT, oxidation systems can increase aqueous dye removal capabilities and lower treatment costs. With NEAT, these systems can remove all dye classes greater than or equal to 2 wt% 3-times faster than conventional methods.

Experiment with Us

NEAT’s highly flexible formulas can be utilized in a wide range of aqueous oxidation systems. We are actively seeking partners and pilots to test NEAT’s capabilities and to explore further applications of our technology.

  • Oxidation of pyrites in ore slurry using NEAT and any oxidant.

  • Degradation of low dose Bisphenol A and tetramethyl, tetrachloro, and tetrabromo substituted derivatives, using nM doses of NEAT NT7 and mM doses of peroxide. Proven effective in removing BPA and other contaminants from recycled stock materials prior to processing.

  • Quick treatment response to legionella detection in open recirculating cooling towers using NEAT to improve the operational response time and effective containment and control of a potential outbreak.

  • Rapid and complete degradation proven of Tannic Acid using peracetic acid and NEAT as a model for removal of macro organics in aqueous streams.

  • Increased degradation rate of acetonitrile under simulated process conditions when comparing NEAT catalyzed treatment to that of a conventional strong oxidizer.

  • Proven initiation of polyaromatic hydrocarbon breakdown using NEAT precursor and peroxide for rural surface water remediation efforts.

  • Full deactivation of the anthrax spore surrogate, Bacillus atrophaeus, proven within 15 minutes of exposure to NEAT precursor and hydrogen peroxide, demonstrating effective and rapid response to difficult challenges involving bacterium.