Supernova neutrino detection Kate Scholberg Duke University Neutrino
Supernova neutrino detection Kate Scholberg, Duke University Neutrino Champagne 2009
OUTLINE Neutrinos from supernovae Supernova neutrino detection Inverse beta decay Other CC interactions NC interactions Summary of current and near future detectors Farther future detectors Extra galactic neutrinos Relic neutrinos Pointing to a supernova with neutrinos Summary �
What do we want in a SN n detector? - Need ~ 1 kton for ~ few 100 interactions for burst at the Galactic center (8. 5 kpc away) - Must have bg rate << rate in ~10 sec burst (typically easy for underground detectors, even thinkable at the surface) Also want: Timing Energy resolution Pointing Flavor sensitivity Require NC sensitivity for nm, t , since SN n energies below CC threshold Sensitivity to different flavors and ability to tag interactions is key! ne vs nx
Good old CC inverse beta decay , the workhorse of neutrino physics, serves us well for SN neutrino detection: g Inverse Beta Decay (CC) e + p e + n + e Can often exploit delayed (~180 ms) coincidence of n + p d + g (or other neutron capture) as tag e + n 0. 511 Me. V g 2. 2 Me. V (also possibly g's from e+ annihilation) In any detector with lots of free protons (e. g. water, scint) this dominates by orders of magnitude
WATER CHERENKOV DETECTORS Volume of clear water viewed by PMTs - few 100 events/kton - typical energy threshold ~ several Me. V makes 2. 2 Me. V neutron tag difficult Super-Kamiokande IV 22. 5 kton f. v. : ~8000 inverse beta decay events @ 10 kpc
Possible enhancement: use gadolinium to capture neutrons for tag of ne e + p e+ + n Gd has a huge n capture cross-section: 49, 000 barns, vs 0. 3 b for free protons; n + Gd Gd* Gd + g Previously used in small scintillator detectors; may be possible for large water detectors with Gd compounds in solution Beacom & Vagins, hep-ph/0309300 R&D is currently underway for SK with half kton test tank in the Kamioka mine
LONG STRING WATER CHERENKOV DETECTORS ~kilometer long strings of PMTs in very clear water or ice Nominally multi-Ge. V energy threshold. . . but, may see burst of low energy ne's as coincident increase in single PMT count rates (Meff~ 0. 4 kton/PMT) cannot tag flavor, or other interaction info, but gives overall rate and time structure Ice. Cube at the South Pole
Halzen & Raffelt, ar. Xiv: 0908. 2317 Few ~ms timing may be possible @ 10 kpc w/Ice. Cube
SCINTILLATION DETECTORS Liquid scintillator Cn. H 2 n volume surrounded by photomultipliers - few 100 events/kton - low threshold, good neutron tagging possible - little pointing capability (light is ~isotropic) Kam. LAND (Japan) LVD (Italy) Mini-Boo. NE (USA) (+Cherenkov) +Double Chooz, Daya Bay and RENO Borexino (Italy) SNO+ (Canada)
NOn. A: long baseline oscillation experiment (Ash River, MN) 15 kton scintillator, near surface K. Arms, CIPANP ‘ 09
For most existing (and planned) large detectors, inverse beta decay dominates, (and is potentially taggable) so primary sensitivity is to ne CC interactions on nuclei play a role, too (cross-sections smaller for bound nucleons) ne + n p + e - : ne + (N, Z) (N-1, Z+1) + e- ne + p n + e + : ne + (N, Z) (N+1, Z-1) + e+ Observables for tagging - charged lepton e+/- possibly ejected nucleons - possibly de-excitation g's depends on nucleus Nuclear physics important in understanding cross-sections and observables!. . . often large uncertainties, need to measure!
Examples of CC interactions of SN n with nuclei: Interactions with oxygen in water e. g. Super-K, ~few tens @ 8. 5 kpc e + 16, 18 O e + 16 O 16, 18 F 16 N + e- + e+ Interactions with carbon in scintillator e. g. LVD, Kam. LAND, + 12 C 12 N + e. Borexino ~few @ 8. 5 kpc e e + 12 C 12 B+ e+
ICARUS: 600 ton LAr CC e + 40 Ar e- + 40 K* Ethr=1. 5 Me. V _ e + 40 Ar e- + 40 Cl* Ethr=7. 48 Me. V NC x + 40 Ar* ES e, x + e- - Tag modes with gamma spectrum (or lack thereof) - Excellent electron neutrino sensitivity Ethr=1. 46 Me. V
HALO at SNOLab e + 208 Pb 208 Bi* + e- CC, Ethr=18 Me. V 1 n, 2 n emission Relative rates depend on n energy spectral sensitivity (oscillation sensitivity) x + 208 Pb* + x NC 1 n, 2 n, g emission from T. Massicotte thesis SNO 3 He counters + 76 tons of Pb: ~85 events @ 10 kpc
Also: elastic scattering (CC and NC contributions) e, x + e- e, x In water Cherenkov and scintillator, few % of inverse bdk rate e- POINTING from Cherenkov cone: (degraded by isotropic bg) Super-K: expect few hundred ES for 10 kpc SN ~ 8 o pointing (probably best bet for pointing) Beacom & Vogel, astro-ph/9811359 Tomas et al. , hep-ph/0307050
We have sensitivity to electron flavor neutrinos via CC interactions. . . but ~2/3 of the luminosity is m and t flavor; can be detected via NC interactions only Typically, signature is nucleon emission or nuclear de-excitation products e. g. x + (A, Z) (A-1, Z) + n + x x + (A, Z)* + x (A, Z) + g Again, nuclear physics matters! sometimes good tag is possible
Examples of NC interactions K. Langanke et al. , nucl-th/9511032 Interactions with oxygen in water e. g. Super-K, ~few hundreds @ 8. 5 kpc x + 16 O* 16 O + g's Interactions with carbon in scintillator e. g. LVD, + 12 C + 12 C* x Kam. LAND, Borexino ~few tens @ 8. 5 kpc x 12 C +g 15. 11 Me. V
NC neutrino-proton elastic scattering x + p J. Beacom et al. , hep-ph/0205220 Recoil energy small, but visible in scintillator (accounting for 'quenching' ) Recoil spectrum in Kam. LAND Expect ~few 100 events/kton for 8. 5 kpc SN
Neutrino-nucleus NC elastic scattering in ultra-low energy detectors x + A C. Horowitz et al. , astro-ph/0302071 High x-scn but very low recoil energy (10's of ke. V) possibly observable in solar pp/DM detectors ~ few events per ton for Galactic SN nx energy information from recoil spectrum e. g. Ar, Ne, Xe, Ge, . . . DM detectors, e. g. CLEAN/DEAP Spherical Xe TPC Aune et al.
Summary of SN neutrino detection channels Inverse beta decay: e + p e+ + n - dominates for detectors with lots of free p (water, scint) - ne sensitivity; good E resolution; well known x-scn; some tagging, poor pointing CC interactions with nuclei: - lower rates, but still useful, ne tagging useful (e. g. LAr) - cross-sections not always well known Elastic scattering: few % of invbdk, but point! NC interactions with nuclei: - very important for physics, probes m and t flux - some rate in existing detectors, new observatories - some tagging; poor E resolution; x-scns not well known - coherent n-p, n-A scattering in low thresh detectors
Current supernova neutrino detectors Detector Type Location Mass (kton) Events Status @ 8 kpc Super-K Water Japan 32 8000 Running (SK IV) LVD Scintillator Italy 1 300 Running Kam. LAND Scintillator Japan 1 300 Running Borexino Scintillator Italy 0. 3 100 Running Ice. Cube Long string South Pole 0. 4/PMT N/A Running Baksan Scintillator Russia 0. 33 50 Running Mini. BOONE Scintillator USA 0. 7 200 Running Primary sensitivity is to electron antineutrinos via inverse beta decay e + p e+ + n
SNEWS: Supernova Early Warning System SNO (until 2006) LVD Super-K AMANDA/ Ice. Cube Borexino
Current and near-future supernova neutrino detectors Detector Type Location Mass (kton) Events @ 8 kpc Status Super-K Water Japan 32 8000 Running (SK IV) LVD Scintillator Italy 1 300 Running Kam. LAND Scintillator Japan 1 300 Running Borexino Scintillator Italy 0. 3 100 Running Ice. Cube Long string South Pole 0. 4/PMT N/A Running Baksan Scintillator Russia 0. 33 50 Running Mini. BOONE Scintillator USA 0. 7 200 Running HALO Lead Canada 0. 076 85 Under construction Icarus Liquid argon Italy 0. 6 230 Almost ready NO A Scintillator USA 15 3000 Construction started SNO+ Scintillator Canada 1 300 Funded Plus: reactor scint detectors, coherent n. A scattering detectors, geochemical
Current best neutrino detectors sensitive out to ~ few 100 kpc. . mostly just the Milky Way 3 1 per century
Looking beyond: number of sources α D 3 S. Ando et al. , astro-ph/0503321 singles{ doubles Mton SK With Mton scale detector, probability of detecting 1 -2 events reasonably close to ~1 at distances where rate is <~1/year Tagging signal over background becomes the issue ⇒ require double n's or grav wave/optical coincidence
Next generation mega-detectors (10 -20 years) DUSEL LBNE Hyper-K Memphys Megaton-scale water detector concepts 5 -100 kton-scale LAr detector concepts 10 -100 kton-scale scintillator detector concepts LENA, Hano
And going even farther out: we are awash in a sea of 'relic' or diffuse SN n's (DSNB), from ancient SNae flux 8 B Learn about star formation rate, which can constrain cosmological models hep flux M. Goodman SRN window! atm. e flux Difficulty is tagging for decent signal/bg (no burst, 2 n coincidences optical SNae. . . ) C. Lunardini
In water: e + p e + + n M. Nakahata, Neutrino 2008 talk - Worst background is 'invisible muons' below Cherenkov threshold from atmospheric neutrinos → reduce by tagging electron antineutrinos with Gd - But for a big detector requires low energy threshold ($) - LAr is also promising (no Cherenkov threshold)
DSNB Galactic SN ~300 events/kt/30 year ~0. 1 event/kt/year ~10 events/kt/yr more background less background low rate of return, but a sure thing risky in the short term, but you win in the very long term bonds vs stocks. . . (Of course if you build a big detector and run it a long time, you may get both! Diversify!) (But we must remember that no experiment is ‘too big to fail’. . . )
xtragalactic Galactic sensitivity Summary of supernova neutrino detectors Detector Type Location Mass (kton) Events @ 8 kpc Status Super-K Water Japan 32 8000 Running (SK IV) LVD Scintillator Italy 1 300 Running Kam. LAND Scintillator Japan 1 300 Running Borexino Scintillator Italy 0. 3 100 Running Ice. Cube Long string South Pole 0. 4/PMT N/A Running Baksan Scintillator Russia 0. 33 50 Running Mini. BOONE Scintillator USA 0. 7 200 Running HALO Lead Canada 0. 076 85 Under construction Icarus Liquid argon Italy 0. 6 230 Almost ready NO A Scintillator USA 15 3000 Construction started SNO+ Scintillator Canada 1 300 Funded LBNE LAr Liquid argon USA 5 1900 Proposed LBNE WC Water USA 300 78, 000 Proposed MEMPHYS Water Europe 440 120, 000 Proposed Hyper-K Water Japan 500 130, 000 Proposed LENA Scintillator Europe 50 15, 000 Proposed GLACIER Liquid argon Europe 100 38, 000 Proposed
POINTING to the supernova with future detectors (should be prompt if possible) Elastic scattering off electrons is the best bet e, x + e- e, x + e e, x In water Cherenkov few % of total rate e. G. Raffelt LBNE WC / Hyper-K / MEMPHYS: <~ 1 o pointing Other possibilities: - time triangulation - inv. bdk e+n separation - ~Te. V neutrinos (delayed) Tomas et al. hep-ph/0307050
Another pointing possibility: (if no WC detector running) Use the matter oscillation energy spectrum to find the pathlength L traveled in the Earth (assume parameters favorable, and well known) KS, A. Burgmeier, R. Wendell ar. Xiv: 0910. 3174 For a known pathlength, the supernova will be found on a ring on the sky
Inverse energy spectrum, L=6000 km Power spectra for different L A. S. Dighe, et al. hep-ph/ 0311172 Peak in power spectrum vs L for 500, 000 simulated SNae, 60, 000 events each (perfect energy resolution) measure kpeak to find allowed L values
Example skymaps One detector Perfect energy resolution 60, 000 neutrino events SN at dec=-60 o, RA=20 h, 0: 00 Finland Two detectors Finland+Hawaii Three detectors Finland+Hawaii+SD
Large statistics and good energy resolution needed! Scintillator-like energy resolution, one detector in Finland
Can improve using relative timing information Two scintillator detectors oscillation: red timing: dark One scintillator detector + Ice. Cube (assume ~ 1 ms timing) oscillation: red timing: dark
Summary Current detectors: - ~Galactic sensitivity (SK reaches barely to Andromeda) - sensitive mainly to the ne component of the SN flux Near future - more flavor sensitivity w/ HALO, Icarus Next generation of detectors: - extragalactic reach + DSNB - richer flavor sensitivity - very good neutrino-based pointing
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