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New Ideas in Long Range Reactor Monitoring with Neutrinos

New Ideas in Long Range Reactor Monitoring with Neutrinos. John G. Learned and Stephen T. Dye Dept. of Physics and Astronomy University of Hawaii. Introduction. Previously we have used just neutrino rates to separate detectors. Can indeed be done. Requires multiple large detectors.

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New Ideas in Long Range Reactor Monitoring with Neutrinos

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  1. New Ideas in Long Range Reactor Monitoring with Neutrinos John G. Learned and Stephen T. Dye Dept. of Physics and Astronomy University of Hawaii

  2. Introduction • Previously we have used just neutrino rates to separate detectors. • Can indeed be done. • Requires multiple large detectors. • Best if done far from other reactors.

  3. 3-ν Mixing: Reactor Neutrinos Pee=1-{ cos4(θ13) sin2(2θ12) [1-cos(Δm212L/2E)] + cos2(θ12) sin2(2θ13) [1-cos(Δm213L/2E)] + sin2(θ12) sin2(2θ13) [1-cos(Δm223L/2E)]}/2 • Survival probability: 3 oscillating terms each cycling in L/E space (~t) with own “periodicity” (Δm2~ω) • Amplitude ratios ~13.5 : 2.5 : 1.0 • Oscillation lengths ~110 km (Δm212) and ~4 km (Δm213~Δm223) at reactor peak ~3.5 MeV • In energy space it is like a chirped signal… very good for correlations. mixing angles mass diffs

  4. Use Long Wave Nu Oscillations for Ranging Locations

  5. Conclusion for GEONUS • We can make good measurements of any georeactors which exist, and find them accurately even with Hanohano • This information is needed for backgrounds for long range reactor monitoring. • Study needed to determine how well we can deconvolve distributions of natural sources in the presence of world power reactors (~1 TW total).

  6. Hypothetical Monitoring Application 100,000 ton Water Cerenkov detectorin China @ 131 km 10 MWt reactor Take 10MT detector just inside China, 131 km from Yongbyon. Can we detect a 10 MWt reactor? Answer definitely yes and know what we are seeing.

  7. Next Step: Use Sig. Proc. Techn. To Improve Resolution of Signal and Background • Situation similar to that in radio astronomy and elsewhere, where one knows the point spread function. • Can use MEM or CLEAN algorithms. • Get much sharper distance and then power resolution. • Limits will depend upon how many and disposition of background (distant power reactors) plus of course location and power of target reactor. • Work needed with realistic sets of hypotheses.

  8. Required Detector Size versus Reactor Range

  9. Summary of Present Long Range Reactor Monitoring Abilities • Scaled for a 10 MWt Reactor

  10. Detect Clandestine Weapons Too

  11. Summary of New Approaches • Given knowledge of distant reactors, and location (few km) of reactor to be monitored, we can do better separation than had been thought previously. • Sophisticated signal processing may be able to extract interesting information for both geoneutrinos and reactor monitoring. • Some further cards to be played include direction and multiple detectors.

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