A Green, Efficient, and Catalytic Method to Produce Chlorine Dioxide for the Purification and Treatment of Water

Publication:

Umile, T.; Groves, J.T. ¿Catalytic Generation of Chlorine Dioxide from Chlorite Using a Water-Soluble Manganese Porphyrin¿, Angew. Chem., 2011, 50(3), 721-724

Background

Chlorine dioxide gas (ClO₂) is a potent oxidizing agent for the bleaching of paper, the disinfection of water and air, and the treatment of wastewater.  The dangers and energy costs of the production of ClO₂, however, have limited its use in the disinfection of drinking water to the pre-treatment before disinfection with chlorine, and to the small-scale disinfection of water in remote areas that have little access to high-tech purification methods.

Cl0₂ offers a number of advantages compared with the use of chlorine gas for the disinfection of drinking water.  ClO₂ is a stronger oxidizing agent above pH 7 and in the presence of other chemicals such as ammonia and amine, and is less corrosive.  Cl0₂ is more effective than chlorine for killing water-borne pathogenic microbes including viruses, Legionella and other bacteria, and protozoa including the cysts of Giardia and the oocysts of Cryptosporidium.  In addition, disinfection with Cl0₂ does not form the toxic organochlorine byproducts produced during the chlorine disinfection process.  

Current methods for the production of Cl0₂ in large quantities require extreme reaction conditions, hazardous reagents such as strong acids or oxidants, or an energy-intensive electrochemical process.  ClO₂ gas is highly unstable when high concentrations are reached in air, decomposing explosively into Cl₂ and O₂. Thus Cl0₂ gas is typically produced on-site, dissolved in cold water at low concentrations, and used immediately rather than transported.  Safer, low-tech kits for the production of Cl0₂ are available only for small-scale production and typically require long wait periods. 

The method developed by Professor John T. Groves at Princeton University utilizes the chemistry of a water-soluble manganese porphyrin catalyst to produce Cl0₂ from chlorite ions.  The manganese porphyrin catalyst consumes chlorite ions, an undesirable byproduct in other methods producing Cl0₂.  The catalyst is also active when immobilized on clay materials, allowing for facile recovery of the catalyst.  The clay-immobilized catalyst could be used for the construction of flow systems which continually produce chlorine dioxide on a larger scale.

Inventor:

John T. Groves

John T. Groves is the Hugh Stott Taylor Chair and Professor of the department of Chemistry at Princeton University.  Professor Groves¿ research efforts focus at the interface of organic, inorganic, and biological chemistry, and one major focus is the design and characterization of novel biomimetic catalysts.  He received the Hans Fischer Award in Porphyrin Chemistry in 2010.

Intellectual property and technology status:

Patent pending

Industrial collaborators are sought to further establish this opportunity as a green alternative for the purification of water and production of chlorine dioxide. The research in this area continues in the identification of more effective and economical catalysts.

Contacts:

Laurie Tzodikov

Princeton University Office of Technology Licensing ¿ (609) 258-7256¿ tzodikov@princeton.edu