Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
The scientific program for the first five years of LUNA-MV High current H+ (1 mA), 4He+ , 12C+ (150 μA) and 12C++ (100 eμA) beams in the energy range: 0.3-3.5 (7) MeV deep underground @LNGS. From hydrogen burning to helium and carbon burning Carlo Broggini INFN-Padova Nucleosynthesis: from p-p chain, CNO, NeNa and MgAl cycles to the region beyond Fe Stellar evolution: from Main Sequence stars to thermonuclear supernovae and core collapse supernovae 14N(p, g)15O 278 7297 14N+p (p,g) 13C 14N (p,g) b+ 13N - 504 15O 1/2 + 7276 7/2 + 6859 6793 5/2 + 3/2 + 6176 3/2 - 5241 5/2 + 1/2 + 5183 b+ (p,g) 12C -21 7556 (p,a) 15N The bottleneck reaction of the CNO cycle already studied by LUNA (2004-11) 1) “High” energy: solid target + HpGe, excellent energy resolution but small efficiency. Study of the 5 different radiative captures. 2) Low energy: gas target + BGO, bad energy resolution but excellent efficiency. Study of the total cross section. s(70 keV)=200 fb, 11 events/day (p,g) 16O 15O 0 1/2 - 3) Measurement with a clover detector in the energy region above the 259 keV resonance LUNA: St(0)=1.57±0.13 keV b Sgs(0)=0.20±0.05 keV b Adelberger et al. 2011 : St(0)=1.66±0.12 keV b Sgs(0)=0.27±0.05 keV b Q. Li et al. 2016, study over a wide energy region of 6.79 MeV and g.s. transitions: Sgs(0)=0.42±0.04 +009 -0.19 keV b It is mandatory to have a low background measurement over a wide energy region The solar abundance problem new spectroscopic determination of the solar photosphere, in particular C, N and O: 30-40% lower than before SSM predictions disagree with heliosysmology results Physical conditions in the solar core are determined by pp-chain, in particular the temperature profile, CNO luminosity ~1% cno = LF(S1,14,C+Ncore) probe of the (C+N) abundance in the Sun core Borexino: cno< 7.7*108 cm-2s-1 From A.Serenelli, Topical Issue on underground nuclear astrophysics and solar neutrinos EPJA 52(2016): Intrinsic error on the (C+N) determination of 11%, 2.6% from heavy element settling and 10.6% from nuclear cross sections (S17 and S114, ~7.5% each). CNO neutrino flux with 10% uncertainty C+N abundance in the Sun core with ~15% uncertainty 14N(p, g)15O @LUNA MV: day zero experiment to verify accelerator and solid target set-up + to reduce the error on S114 Set-up: several gamma ray detectors (if necessary, there is space for an array). Expected beam time: ~6 months 12C+ 12C the trigger of Carbon burning * The lower stellar mass bound Mup for the Carbon ignition: C-O white dwarf (+Nova or thermonuclear supernova) or massive O-Ne WD or core collapse supernova (+neutron star or black hole) * Protons and alpha injection for nucleosynthesis in massive stars Coulomb barrier: EC= 6.7 MeV 12C+12C 20Ne + a 12C+12C 23Na + p 12C+12C 24Mg + g 12C+12C 23Mg + n 12C+12C 16O + 2a 12C+12C 16O + 8Be Q=4.62 MeV Q=2.24 MeV Q=13.93 MeV negligible Q=-2.62 MeV endothermic Q=-0.12 MeV three particles Q=-0.21 MeV higher Coulomb barrier Energy (CM) region of interest: 0.9-3.4 MeV explosive C-burning from 0.7 MeV Relevant energy range in stars Eg = 440 keV Eg = 1634 keV 12C+12C 20Ne + ai + gi 12C+12C 23Na + pi + gi Detection: particles (Silicon detectors, ΔE-E telescopes, ionization chambers) and gammas (from the first excited state, Ge detectors) Main advantage deep underground @LNGS: gamma ray suppression in a shielded detector (~5 orders of magnitude) T. Spillane et al., Phys Rev Lett. 98 (2007) 122501 Several resonances spaced by 300-500 keV, typical width G≈10 keV Improvements @LNGS: With a shielded Ge detector bck of 52 cpd 425-455 keV and 1 cpd 1619-1649 keV Minimum energy 1955 for the proton channel (bck limited) and 1605 keV for the alpha channel (time limited). All this with 1mm thick carbon target, 5 keV spacing and 30% stat. error) Expected beam time: ~2.5 years Beam induced bck: 1H and 2H in the target Gamma detection: 2H(12C,p1 γ)13C and 1H(12C,γ )13N Particle detection (at backward angles): 2H(12C,2H)12C + 12C(d,p)13C Heating at high temperature is able to reduce the contamination D educe The neutrons for the s-process: nucleosynthesis of half of all elements heavier than Fe (e.g. W, Pd, La, Nd) Two components were identified and connected to stellar sites: Main s-process ~90<A<210 Weak s-process A<~90 TP-AGB stars massive stars > 10 M⊙ shell He-burning T9 ~ 0.1 K 107-108 cm-3 He-flash 0.25 ≤ T9 ~ 0.4 K 1010-1011 cm-3 13C(a,n)16O 22Ne(a,n)25Mg 13C(a,n) 22Ne(a,n) core He-burning 3-3.5·108 K 106 cm-3 shell C-burning ~109 K 1011-1012 cm-3 22Ne(a,n)25Mg 13C(a,n)16O S [MeV b ] Energy region of interest: 140-230 keV (T = 90 · 106 K) ´ 106 6 5 • large statistical uncertainties at low energies • large scatter in absolute values (normalization problem) • unknown systematic uncertainties • uncertainties in detection efficiencies • contribution from sub-threshold state (E=6.356 MeV in 17O) • contribution from electron screening Davids1968 Bair1973 Kellogg1989 Drotleff1993 Harrissopulos2005 Heil2008 4 3 fits/theory Hale1987 Kubono2003 Heil2008 2 1 0 0.1 0.2 0.3 LUNA400 range 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 Ec.m.[MeV] No data at low energy because of high neutron background in surface laboratories. Extrapolations differ by a factor ~4 (10% accuracy and precision would be required). Direct Kinematics energy range Ecm = 210 – 300 keV (Ebeam ~ 275 – 400 keV) at LUNA-400 energy range Ecm = 240 – 1060 keV (Ebeam ~ 0.3 – 1.4 MeV) at LUNA-MV 4He beam 13CH gas target (drawbacks: limit on the density, possible molecule cracking) 4 P = 1 mbar 2.5 1017 atoms/cm2 L = 10 cm 13C-enriched solid target (drawbacks: degradation and possible carbon deposition) density 2·1017-1018 at/cm2 (electron gun evaporation, implantation on Au/ Ta, synthetic diamonds……) beam induced background (α,n) reactions on target impurities or along the beam line ( 10B, 11B, 17O, 18O) neutron energy range: En = 2 – 3.5 MeV Inverse Kinematics (different systematics) 13C beam (only possible at LUNA-MV) 4He gas target P = 1 mbar 2.5 1017 atoms/cm2 L = 10 cm beam induced background: 13C reaction on 2H, 6Li, 7Li, 10B, 11B, neutron energy range: En = 2 – 5 MeV 16O, 19F 10 Both solid target and gas target solutions are tested @ LNL and LNGS: R&D+first measurement @LUNA400 Reaction rate with enriched 13C target (99%) and Ia = 200 μA Elab [keV] Ecm [keV] Rate [neutr/h] Nt = 1018 at/cm2 1200 918 2 105 Ia = 1 mA 1000 764 4 106 800 612 2 107 400 306 339 Lower beam current at high energy to reduce the neutron production (maximum acceptable rate: 2000 neutrons/s). 375 287 103 350 268 28 300 229 1.3 275 210 0.2 250 191 0.02 ≈ 1-2 months beam time with bck = 0 Work in progress to optimize the neutron detector efficiency for the measurement @LUNA400: 3He proportional counters inside a polyethylene cube • 3He tubes in two concentric ring: r1 inner radius, r2 outer radius • Polyethylene cube of L ~ 40 cm • 18 stainless tubes (1 inch diameter, • 25 or 40 cm long, P = 10 atm) • Expected efficiency @ 2 MeV › 30% r2 r1 A different neutron detector might be developed for LUNA-MV in addition to 3He counters: panels of 6Li loaded plastic scintillator surrounding a polyethylenegraphyte moderator 22Ne(a,n)25Mg Eth= 0.57 MeV - Very complex level scheme of 26Mg - The lowest well studied resonance at Eα=832 keV dominates the rate - The influence of a possible resonance at 635 keV has been ruled out because of parity conservation - Only upper limits at: 570<Eα<800 keV (~10 pb), the energy region of interest for AGB stars. Extrapolations may be affected by unknown resonances @T9 < 0.18 the competing reaction 22Ne(α,γ)26Mg (Q=10.6 MeV) should become dominant (400 kV accelerator). For the measurement @LUNA: 22Ne windowless gas target + 3He counters inside moderator. To fully exploit LNGS low background we need: shielded detector, selected tubes, pulse shape discrimination, remove 11B (because of 11B(a,n)14N)… to reach the level of ~10 n/day. Scientific program of LUNA-MV (first run January 2019) ˃ 10 years mainly devoted to the study of helium and carbon burning First 5 years: 14N(p,g)15O: the bottleneck reaction of the CNO cycle in connection with the solar abundance problem 12C + 12C: the trigger of carbon burning in star, White Dwarf (+Nova or thermonuclear SN) or O-Ne WD or core collapse SN (+neutron star or black hole) Sources of the neutrons responsible for the S-process: 50% of the elements beyond Iron (neutron capture followed by beta decay): 13C(a,n)16O: isotopes with A≥90 during helium burning shell in low mass AGB stars (4 solar masses) 22Ne(a,n)25Mg: isotopes with A‹90 during He burning in high mass AGB stars and during He and C burning in massive stars 12C(a,g)16O: the flagship reaction of the next 5 year plan 1979 proposed by A. Zichichi , 1989 MACRO experiment ON 1400 m of dolomite rock, CaMg(CO3)2, (~3800 m w.e.) Surf.: 17 800 m2, Vol.: 180 000 m3, Ventilation: 1 vol / 3.5 hours (Rn in air 20-80 Bq m-3) Muon flux: 1.1 m-2h-1, 6 orders of magnitude reduction Neutron flux, mainly from (a,n): 2.92 10-6 cm-2s-1 (0-1 keV), 0.86 10-6 cm-2s-1 (> 1 keV), 3 orders of magnitude reduction Gamma rays: only 1 order of magnitude reduction, but with thick shield about 5 orders of magnitude in the region of natural radioactivity and 4-5 orders above 3.2 MeV without any shield Alpha particles: factor ~15 below 3 MeV (shielded Si detector) ≥ 1 month ≥ 308 day - Terminal voltage Ripple (Rms): 20 -80 V Underground accelerators LUNA JUNA Bck. Acceler. Beam intensity Program Expected start Notes LNGS LUNA 400 ~300 mA 13C(a,n) 2017 Solid + gas target 400 kV – ECR 10 mA ! ~ 2 OoM better et al., 25Mg(p,g) 13C(a,n) Mid 2016 2019 12C(a,g) CASPAR ~ LUNA Old 1 MV 150 mA 14N(p,g) ? 13C(a,n) 22Ne(a,n) LUNA MV LNGS 3.5 MV + ECR 1 mA 14N(p,g) + 12C 13C(a,n) 22Ne(a,n) 12C(a,g) 12C Mid 2016 ? ? 2019 ? ? ? ? Gas target + 3He tubes in liq. Scint. Gas target + 3He tubes