Thermochemical nitrate reduction

A series of preliminary experiments was conducted directed at thermochemically converting nitrate to nitrogen and water. Nitrates are a major constituent of the waste stored in the underground tanks on the Hanford Site, and the characteristics and effects of nitrate compounds on stabilization techni...

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Bibliographic Details
Main Authors: Cox, J. L., Lilga, M. A., Hallen, R. T.
Other Authors: United States. Department of Energy.
Format: Report
Language:English
Published: Pacific Northwest Laboratory 1992
Subjects:
Urea
Aldehydes
Chromatography
Formates
Processing
Organic Compounds
Elements
Chemical Reaction Kinetics
Amides
Chemical Reactions
Numerical Data
Data
Monosaccharides
Hydrogen Compounds
Separation Processes
Kinetics
Methane
12 Management Of Radioactive And Non-Radioactive Wastes From Nuclear Facilities
Nitrogen Compounds
Oxygen Compounds
Carboxylic Acid Salts
Hydrocarbons
Gas Chromatography
Hydrides
Nitrates
Reducing Agents
Waste Processing 052001* > Nuclear Fuels > Waste Processing
Reaction Kinetics
Ammonia
Denitration
Experimental Data
Temperature Range
Information
Thermochemical Processes
Hydrogen
Chemical Reactors
Management
Radioactive Waste Management
Carbonic Acid Derivatives
Temperature Range 0400-1000 K
Carbohydrates
Radioactive Waste Processing
Waste Management
Organic Nitrogen Compounds
Nonmetals
Glucose
Reduction
Hexoses
Saccharides
Alkanes
Nitrogen Hydrides
Carbonic acid
Online Access:https://doi.org/10.2172/7077253
https://digital.library.unt.edu/ark:/67531/metadc1196345/
Description
Summary:A series of preliminary experiments was conducted directed at thermochemically converting nitrate to nitrogen and water. Nitrates are a major constituent of the waste stored in the underground tanks on the Hanford Site, and the characteristics and effects of nitrate compounds on stabilization techniques must be considered before permanent disposal operations begin. For the thermochemical reduction experiments, six reducing agents (ammonia, formate, urea, glucose, methane, and hydrogen) were mixed separately with {approximately}3 wt% NO{sub 3}{sup {minus}} solutions in a buffered aqueous solution at high pH (13); ammonia and formate were also mixed at low pH (4). Reactions were conducted in an aqueous solution in a batch reactor at temperatures of 200{degrees}C to 350{degrees}C and pressures of 600 to 2800 psig. Both gas and liquid samples were analyzed. The specific components analyzed were nitrate, nitrite, nitrous oxide, nitrogen, and ammonia. Results of experimental runs showed the following order of nitrate reduction of the six reducing agents in basic solution: formate > glucose > urea > hydrogen > ammonia {approx} methane. Airnmonia was more effective under acidic conditions than basic conditions. Formate was also effective under acidic conditions. A more thorough, fundamental study appears warranted to provide additional data on the mechanism of nitrate reduction. Furthermore, an expanded data base and engineering feasibility study could be used to evaluate conversion conditions for promising reducing agents in more detail and identify new reducing agents with improved performance characteristics.

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