Hydrothermal processing of Hanford tank waste. Organic destruction technology development task annual report -- FY 1993

Orth, R.J.; Schmidt, A.J.; Zacher, Alan H.

doi:10.2172/10185226

Cited by 2 publications

(3 citation statements)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For an activation energy of 25 kcal/mole, approximately that reported for gas generation and related reactions (Delegard 1980;Ashby et al 1993;Meisel et al 1993;Orth et al 1993;Schmidt et al 1993Schmidt et al , 1994), a one-degree difference in temperature from 90°C would yield a 10% change in rate, a two-degree difference would yield a 20% change in rate, and a five-degree difference would yield a 60% change. The l-L reaction vessels were independently temperaturecontrolled and monitored throughout the tests to within f0.5"C, leading to a 5% error because of changes in thermal reaction rates and assuming a 25 kcal/mole activation energy.…”

Section: Experimental Methods For Gas Measurements and Sample Irradiamentioning

confidence: 77%

Thermal and combined thermal and radiolytic reactions involving nitrous oxide, hydrogen, nitrogen, and ammonia in contact with tank 241-SY-101 simulated waste

Bryan¹,

Pederson²

1996

View full text Add to dashboard Cite

Tank 241-SY-101 simulated waste. Flammable gases generated by the radiolysis of water and by the thermal and radiolytic decomposition of organic waste constituents may themselves participate in further reactions. Examples include the decomposition of nitrous oxide to yield nitrogen and oxygen, the reaction of nitrous oxide and hydrogen to produce nitrogen and water, and the reaction of nitrogen and hydrogen to produce ammonia. The composition of the gases trapped in bubbles in the wastes might therefore change continuously as a function of the time that the gas bubbles are retained.The decomposition of nitrous oxide, reactions between nitrous oxide and hydrogen, reactions between nitrogen and hydrogen, and decomposition reactions of ammonia in contact with Tank 241-SY-101 simulated waste under thermal and combined thermal and radiolytic conditions were investigated in the temperature range of 60 to 150°C. Radiation doses ranged from 0 to more than 10 Mrad ( @ ' C O ) , while reaction times extended to 70 hours. Reactions were performed in stainless steel vessels that allowed continuous monitoring of gas pressures. Gas compositions were evaluated using mass spectrometry and infrared spectrometry.The primary radiolytic and thermal products of nitrous oxide decomposition were nitrogen, oxygen, and nitrogen dioxide. Under thermal-only conditions, the extent of nitrous oxide decomposition was less than that for the companion experiment under combined thermal and radiolytic conditions. However, the thermal decomposition in the presence of simulated waste was significant compared with that observed in earlier tests in the absence of simulated waste (Bryan and Pederson 1995). G-values measured for the decomposition of nitrous oxide in the presence of simulated waste showed a significant temperature dependence, consistent with a surface reaction with nitrous oxide contributing to the decomposition reaction. G(N20) ranged in value from -7 to -17 in the systems containing wet and dried simulated waste.In contrast, G(N20) for the gas phase decomposition of nitrous oxide was determined to be constant at -12 molecules/100 eV, in good agreement with literature values. No temperature dependence of G(-N20) was apparent from 60 to 150°C. Nitrogen dioxide yields decreased with increasing temperature, while nitrogen yields increased with increasing temperature. Assuming a gamma dose rate of lo00 R/h in the actual wastes, and assuming that nitrous oxide composes 530% of the gases trapped in the nonconvecting layer, it is estimated that = 1 % of the retained nitrous oxide could be consumed by these gas-phase radiolytic reactions per year. However, the thermal decomposition of nitrous oxide contributes significantly to the total decomposition of nitrous oxide when in contact with simulated waste. iii Catalysis of nitrous oxide decomposition by solid phases is a significant possibility. At least some of the gases will be retained as bubbles attached to solid particles, in response to surface tension forces. Thus the gases will be in in...

show abstract

Section: Experimental Methods For Gas Measurements and Sample Irradiamentioning

confidence: 77%

Thermal and combined thermal and radiolytic reactions involving nitrous oxide, hydrogen, nitrogen, and ammonia in contact with tank 241-SY-101 simulated waste

Bryan¹,

Pederson²

1996

View full text Add to dashboard Cite

show abstract

“…Successful oxidation of organic complexants in these thermal studies was anticipated from the observed behavior of wastes in Tank 241-SY-101. Orth et al (1993) heated simulated Tank 241-SY-101 waste containing various organic complexants at 200 "C for various times. He observed rapid oxidation of HEDTA and glycolate at 200 "C. Orth (1993) also found that at 200 "C EDTA decomposed at a reasonable rate but that NTA did not.…”

Section: Thermal Oxidationmentioning

confidence: 99%

“…Orth et al (1993) heated simulated Tank 241-SY-101 waste containing various organic complexants at 200 "C for various times. He observed rapid oxidation of HEDTA and glycolate at 200 "C. Orth (1993) also found that at 200 "C EDTA decomposed at a reasonable rate but that NTA did not. A temperature of 250 "C was required before NTA was oxidized at an appreciable rate.…”

Section: Thermal Oxidationmentioning

confidence: 99%

In-tank processes for destruction of organic complexants and removal of selected radionuclides

Schulz¹,

Kupfer²,

McKeon³

1995

View full text Add to dashboard Cite

Hydrothermal processing of Hanford tank waste. Organic destruction technology development task annual report -- FY 1993

Cited by 2 publications

References 0 publications

Thermal and combined thermal and radiolytic reactions involving nitrous oxide, hydrogen, nitrogen, and ammonia in contact with tank 241-SY-101 simulated waste

Thermal and combined thermal and radiolytic reactions involving nitrous oxide, hydrogen, nitrogen, and ammonia in contact with tank 241-SY-101 simulated waste

In-tank processes for destruction of organic complexants and removal of selected radionuclides

Contact Info

Product

Resources

About