Observation of the isotopic evolution of pressurized water reactor fuel using an antineutrino detector

Bowden, N. S.; Bernstein, Adam; Dazeley, S.; Svoboda, R.; Misner, Alex C.; Palmer, Todd S.

doi:10.1063/1.3080251

Cited by 49 publications

(43 citation statements)

References 12 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Previous experiments have demonstrated variations in the total reactor antineutrino flux with fuel evolution [17,18] while providing indications that a change in the spectral shape with fuel evolution may be present [18]. In this Letter, we report the direct observation of a change in the reactor antineutrino flux and spectrum with reactor fuel evolution.…”

mentioning

confidence: 63%

Getting to the Bottom of an Antineutrino Anomaly

Fallot

2017

Physics

View full text Add to dashboard Cite

mentioning

confidence: 63%

Getting to the Bottom of an Antineutrino Anomaly

Fallot

2017

Physics

View full text Add to dashboard Cite

“…Additionally, the effects of misreported power shifts can give insight to the test's sensitivity to detector drifts. The detector used in this analysis has not been deployed long enough to study these effects, but the SONGS1 detector showed a less than 1% drift while taking data [21].…”

Section: B Rate Evolution Analysismentioning

confidence: 99%

Antineutrino monitoring of thorium reactors

Akindele

Bernstein

Norman

2016

Journal of Applied Physics

View full text Add to dashboard Cite

Various groups have demonstrated that antineutrino monitoring can be successful in assessing the plutonium content in water-cooled nuclear reactors for nonproliferation applications. New reactor designs and concepts incorporate nontraditional fuels types and chemistry. Understanding how these properties affect the antineutrino emission from a reactor can extend the applicability of antineutrino monitoring. Thorium molten salt reactors (MSR) breed 233 U, that if diverted constitute a direct use material as defined by the International Atomic Energy Agency (IAEA). The antineutrino spectrum from the fission of 233 U has been estimated for the first time, and the feasibility of detecting the diversion of 8 kg of 233 U, within a 30 day timeliness goal has been evaluated. The antineutrino emission from a thorium reactor operating under normal conditions is compared to a diversion scenario by evaluating the daily antineutrino count rate and the energy spectrum of the detected antineutrinos at a 25 meter standoff. It was found that the diversion of a significant quantity of 233 U could not be detected within the current IAEA timeliness detection goal using either tests. A rate-time based analysis exceeded the timeliness goal by 23 days, while a spectral based analysis exceeds this goal by 31 days.

show abstract

“…Reactor monitoring withν e has been demonstrated using the inverse beta-decay reac- [72] tion [2,18]. In recent demonstrationsν e monitoring has been able to successfully monitor the isotopic evolution of fuel in a reactor, detect on-off status .…”

Section: Monitoring Of Nuclear Reactors For Nuclear Safeguardsmentioning

confidence: 99%

A G/NARRLI Effort. Measuring the Ionization Yield of Low-Energy Nuclear Recoils in Liquid Argon

Joshi¹

2014

View full text Add to dashboard Cite

Liquid argon has long been used for particle detection due to its attractive drift properties, ample abundance, and reasonable density. The response of liquid argon to lowenergy O(10 2 − 10 4 eV) interactions is, however, largely unexplored. Weakly interacting massive particles such as neutrinos and hypothetical dark-matter particles (WIMPs) are predicted to coherently scatter on atomic nuclei, leaving only an isolated low-energy nuclear recoil as evidence. The response of liquid argon to low-energy nuclear recoils must be studied to determine the sensitivity of liquid argon based detectors to these unobserved interactions. Detectors sensitive to coherent neutrino-nucleus scattering may be used to monitor nuclear reactors from a distance, to detect neutrinos from supernova, and to test the predicted behavior of neutrinos. Additionally, direct detection of hypothetical weakly interacting dark matter would be a large step toward understanding the substance that accounts for nearly 27% of the universe. In this dissertation I discuss a small dual-phase (liquid-gas) argon proportional scintillation counter built to study the low-energy regime and several novel calibration and characterization techniques developed to study the response of liquid argon to low-energy O(10 2 − 10 4 eV) interactions.

show abstract

Observation of the isotopic evolution of pressurized water reactor fuel using an antineutrino detector

Cited by 49 publications

References 12 publications

Getting to the Bottom of an Antineutrino Anomaly

Getting to the Bottom of an Antineutrino Anomaly

Antineutrino monitoring of thorium reactors

A G/NARRLI Effort. Measuring the Ionization Yield of Low-Energy Nuclear Recoils in Liquid Argon

Contact Info

Product

Resources

About