Solar neutrino spectroscopy

Wurm, M.

doi:10.1016/j.physrep.2017.04.002

Cited by 21 publications

(21 citation statements)

References 139 publications

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“…Astro-neutrinos such as solar neutrinos and supernova neutrinos are interesting in view of both neutrino physics and astrophysics. The observations of solar neutrinos provide evidences for the neutrino matter oscillations as well as nuclear fusion reactions in the sun, and those of the supernova neutrinos probe the explosion process, as described extensively in the review articles [6,7,8,9,10]. So, these observations have opened the new field of neutrino astronomy.…”

Section: Nuclear Responses For Astro-neutrinos and Neutrino Nucleosynthesismentioning

confidence: 96%

“…Historical reviews and extensive previous works on the neutrino-nuclear responses are given in [1,2,3,4,5] and references therein, those on astro-neutrinos in, e.g. [6,7,8,9,10,11,12,13,14] and references therein, and reviews on DBDs are given in, e.g. [15,16,17,18,19,20,21,22,23,24] and references therein.…”

Section: Neutrino-nuclear Responses and Neutrino Studies In Nucleimentioning

confidence: 99%

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Neutrino–nuclear responses for astro-neutrinos, single beta decays and double beta decays

2019

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Neutrino-nuclear responses associated with astro-neutrinos, single beta decays and double beta decays are crucial in studies of neutrino properties of interest for astro-particle physics. The present report reviews briefly recent studies of the neutrino-nuclear responses from both experimental and theoretical points of view in order to obtain a consistent understanding of the many facets of the neutrino-nuclear responses. Subjects discussed in this review include (i) experimental studies of neutrino-nuclear responses by means of single beta decays, charge-exchange nuclear reactions, muon-photon-and neutrino-nuclear reactions, and nucleon-transfer reactions, (ii) implications of and discussions on neutrino-nuclear responses for single beta decays, for astroneutrinos, and for astro-neutrino nucleosynthesis, (iii) theoretical aspects of neutrino-nuclear responses for beta and double beta decays, for nuclear muon capture and for neutrino-nucleus scattering, and (iv) critical discussions on nucleonic and non-nucleonic spin-isospin correlations and renormalization (quenching or enhancement) effects on the axial weak coupling. Remarks are given on perspectives of experimental and theoretical studies of the neutrino-nuclear responses and on future experiments of double beta decays.

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Section: Nuclear Responses For Astro-neutrinos and Neutrino Nucleosynthesismentioning

confidence: 96%

Section: Neutrino-nuclear Responses and Neutrino Studies In Nucleimentioning

confidence: 99%

Neutrino–nuclear responses for astro-neutrinos, single beta decays and double beta decays

2019

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“…Direct constraints on the first second of the explosion are expected from the future detection of neutrinos (e.g. Wurm et al 2012, Müller et al 2014a) and gravitational waves (Ott 2009, Kotake 2013, Müller et al 2013) from a Galactic supernova. The future detection of the diffuse neutrino background will globally constrain both the physics of the explosion and the supernova rate (Beacom 2010).…”

Section: Observational Evidence For Asymmetric Explosionsmentioning

confidence: 99%

The Explosion Mechanism of Core-Collapse Supernovae: Progress in Supernova Theory and Experiments

Foglizzo

Kazeroni

Guilet

et al. 2015

Publ. Astron. Soc. Aust.

158

102

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The explosion of core-collapse supernova depends on a sequence of events taking place in less than a second in a region of a few hundred kilometers at the centre of a supergiant star, after the stellar core approaches the Chandrasekhar mass and collapses into a proto-neutron star, and before a shock wave is launched across the stellar envelope. Theoretical efforts to understand stellar death focus on the mechanism which transforms the collapse into an explosion. Progress in understanding this mechanism is reviewed with particular attention to its asymmetric character. We highlight a series of successful studies connecting observations of supernova remnants and pulsars properties to the theory of corecollapse using numerical simulations. The encouraging results from first principles models in axisymmetric simulations is tempered by new puzzles in 3D. The diversity of explosion paths and the dependence on the pre-collapse stellar structure is stressed, as well as the need to gain a better understanding of hydrodynamical and MHD instabilities such as standing accretion shock instability and neutrino-driven convection. The shallow water analogy of shock dynamics is presented as a comparative system where buoyancy effects are absent. This dynamical system can be studied numerically and also experimentally with a water fountain. The potential of this complementary research tool for supernova theory is analysed. We also review its potential for public outreach in science museums.

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“…The precision measurements of low‐energy neutrinos from the Sun in the ongoing and forthcoming solar neutrino experiments will not only provide us with more accurate values of neutrino oscillation parameters , but also offer a precious opportunity to test the Mikheyev‐Smirnov‐Wolfenstein (MSW) matter effect and to probe the solar properties, such as the core metallicity (by measuring the CNO neutrino flux) and the total luminosity (through determining the

p p

neutrino flux). Furthermore, the observations of solar neutrinos in the future water‐Cherenkov detector Hyper‐Kamiokande and liquid‐scintillator detectors SNO+ , JUNO , RENO50 and LENA will greatly improve current knowledge about the electromagnetic properties of neutrinos.…”

Section: Future Astrophysical Probes Of Electromagnetic Neutrinosmentioning

confidence: 99%

“…There will be a liquid‐scintillator detector with a 20 kiloton target mass and a high energy resolution of

3 % / \sqrt{E / MeV}

at JUNO, and the LENA detector will be 2.5 times larger. In consequence, JUNO (LENA ) will register about four thousand (ten thousand) 7 Be elastic

ν_{e}

‐

e^{-}

events per day in its detectable window above 250 keV, which means that the statistical uncertainties can be negligible after years of data taking. Therefore, the achievable limit on the neutrino magnetic dipole moment mainly depends on the systematics, and in particular on the radioactive and cosmogenic backgrounds.…”

Section: Future Astrophysical Probes Of Electromagnetic Neutrinosmentioning

confidence: 99%

Electromagnetic neutrinos in laboratory experiments and astrophysics

Giunti

Kouzakov

et al. 2015

Annalen der Physik

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An overview of neutrino electromagnetic properties, which open a door to the new physics beyond the Standard Model, is given. The effects of neutrino electromagnetic interactions both in terrestrial experiments and in astrophysical environments are discussed. The experimental bounds on neutrino electromagnetic characteristics are summarized. Future astrophysical probes of electromagnetic neutrinos are outlined.Comment: 18 pages, 2 figures, Revised version, Annalen der Physik [Ann. Phys. (Berlin)] in press. arXiv admin note: substantial text overlap with arXiv:1403.634

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Solar neutrino spectroscopy

Cited by 21 publications

References 139 publications

Neutrino–nuclear responses for astro-neutrinos, single beta decays and double beta decays

Neutrino–nuclear responses for astro-neutrinos, single beta decays and double beta decays

The Explosion Mechanism of Core-Collapse Supernovae: Progress in Supernova Theory and Experiments

Electromagnetic neutrinos in laboratory experiments and astrophysics

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