329 research outputs found
LUNA: Status and Prospects
The essential ingredients of nuclear astrophysics are the thermonuclear
reactions which shape the life and death of stars and which are responsible for
the synthesis of the chemical elements in the Universe. Deep underground in the
Gran Sasso Laboratory the cross sections of the key reactions responsible for
the hydrogen burning in stars have been measured with two accelerators of 50
and 400 kV voltage right down to the energies of astrophysical interest. As a
matter of fact, the main advantage of the underground laboratory is the
reduction of the background. Such a reduction has allowed, for the first time,
to measure relevant cross sections at the Gamow energy. The qualifying features
of underground nuclear astrophysics are exhaustively reviewed before discussing
the current LUNA program which is mainly devoted to the study of the Big-Bang
nucleosynthesis and of the synthesis of the light elements in AGB stars and
classical novae. The main results obtained during the study of reactions
relevant to the Sun are also reviewed and their influence on our understanding
of the properties of the neutrino, of the Sun and of the Universe itself is
discussed. Finally, the future of LUNA during the next decade is outlined. It
will be mainly focused on the study of the nuclear burning stages after
hydrogen burning: helium and carbon burning. All this will be accomplished
thanks to a new 3.5 MV accelerator able to deliver high current beams of
proton, helium and carbon which will start running under Gran Sasso in 2019. In
particular, we will discuss the first phase of the scientific case of the 3.5
MV accelerator focused on the study of C+C and of the two
reactions which generate free neutrons inside stars:
C(,n)O and Ne(,n)Mg.Comment: To be published in Progress in Particle and Nuclear Physics 98C
(2018) pp. 55-8
Cosmic-ray induced background intercomparison with actively shielded HPGe detectors at underground locations
The main background above 3\,MeV for in-beam nuclear astrophysics studies
with -ray detectors is caused by cosmic-ray induced secondaries. The
two commonly used suppression methods, active and passive shielding, against
this kind of background were formerly considered only as alternatives in
nuclear astrophysics experiments. In this work the study of the effects of
active shielding against cosmic-ray induced events at a medium deep location is
performed. Background spectra were recorded with two actively shielded HPGe
detectors. The experiment was located at 148\,m below the surface of the Earth
in the Reiche Zeche mine in Freiberg, Germany. The results are compared to data
with the same detectors at the Earth's surface, and at depths of 45\,m and
1400\,m, respectively.Comment: Minor errors corrected; final versio
Primordial nucleosynthesis
Big Bang nucleosynthesis (BBN) describes the production of light nuclei in the early phases of the Universe. For this, precise knowledge of the cosmological parameters, such as the baryon density, as well as the cross section of the fusion reactions involved are needed. In general, the energies of interest for BBN are so low (E < 1MeV) that nuclear cross section measurements are practically unfeasible at the Earth’s surface. As of today, LUNA (Laboratory for Underground Nuclear Astrophysics) has been the only facility in the world available to perform direct measurements of small cross section in a very low background radiation. Owing to the background suppression provided by about 1400 meters of rock at the Laboratori Nazionali del Gran Sasso (LNGS), Italy, and to the high current offered by the LUNA accelerator, it has been possible to investigate cross sections at energies of interest for Big Bang nucleosynthesis using protons, 3He and alpha particles as projectiles. The main reaction studied in the past at LUNA is the 2H(4He, (Formula presented.))6Li. Its cross section was measured directly, for the first time, in the BBN energy range. Other processes like 2H(p, (Formula presented.))3He , 3He(2H, p)4He and 3He(4He, (Formula presented.))7Be were also studied at LUNA, thus enabling to reduce the uncertainty on the overall reaction rate and consequently on the determination of primordial abundances. The improvements on BBN due to the LUNA experimental data will be discussed and a perspective of future measurements will be outlined. © 2016, SIF, Springer-Verlag Berlin Heidelberg
Response of Multi-strip Multi-gap Resistive Plate Chamber
A prototype of Multi-strip Multi-gap Resistive Plate chamber (MMRPC) with
active area 40 cm 20 cm has been developed at SINP, Kolkata. Detailed
response of the developed detector was studied with the pulsed electron beam
from ELBE at Helmholtz-Zentrum Dresden-Rossendorf. In this report the response
of SINP developed MMRPC with different controlling parameters is described in
details. The obtained time resolution () of the detector after slew
correction was 91.53 ps. Position resolution measured along ()
and across () the strip was 2.80.6 cm and 0.58 cm, respectively.
The measured absolute efficiency of the detector for minimum ionizing particle
like electron was 95.81.3 . Better timing resolution of the detector
can be achieved by restricting the events to a single strip. The response of
the detector was mainly in avalanche mode but a few percentage of streamer mode
response was also observed. A comparison of the response of these two modes
with trigger rate was studiedComment: 19 pages, 26 figure
First measurement of the 14N(p,gamma)15O cross section down to 70 keV
In stars with temperatures above 20*10^6 K, hydrogen burning is dominated by
the CNO cycle. Its rate is determined by the slowest process, the
14N(p,gamma)15O reaction. Deep underground in Italy's Gran Sasso laboratory, at
the LUNA 400 kV accelerator, the cross section of this reaction has been
measured at energies much lower than ever achieved before. Using a windowless
gas target and a 4pi BGO summing detector, direct cross section data has been
obtained down to 70 keV, reaching a value of 0.24 picobarn. The Gamow peak has
been covered by experimental data for several scenarios of stable and explosive
hydrogen burning. In addition, the strength of the 259 keV resonance has been
remeasured. The thermonuclear reaction rate has been calculated for
temperatures 90 - 300 *10^6 K, for the first time with negligible impact from
extrapolations
Determination of gamma-ray widths in N using nuclear resonance fluorescence
The stable nucleus N is the mirror of O, the bottleneck in the
hydrogen burning CNO cycle. Most of the N level widths below the proton
emission threshold are known from just one nuclear resonance fluorescence (NRF)
measurement, with limited precision in some cases. A recent experiment with the
AGATA demonstrator array determined level lifetimes using the Doppler Shift
Attenuation Method (DSAM) in O. As a reference and for testing the
method, level lifetimes in N have also been determined in the same
experiment. The latest compilation of N level properties dates back to
1991. The limited precision in some cases in the compilation calls for a new
measurement in order to enable a comparison to the AGATA demonstrator data. The
widths of several N levels have been studied with the NRF method. The
solid nitrogen compounds enriched in N have been irradiated with
bremsstrahlung. The -rays following the deexcitation of the excited
nuclear levels were detected with four HPGe detectors. Integrated
photon-scattering cross sections of ten levels below the proton emission
threshold have been measured. Partial gamma-ray widths of ground-state
transitions were deduced and compared to the literature. The photon scattering
cross sections of two levels above the proton emission threshold, but still
below other particle emission energies have also been measured, and proton
resonance strengths and proton widths were deduced. Gamma and proton widths
consistent with the literature values were obtained, but with greatly improved
precision.Comment: Final published version, minor grammar changes, 10 pages, 4 figures,
8 tables; An addendum is published where the last section is revised: T.
Sz\"ucs and P. Mohr, Phys. Rev. C 92, 044328 (2015) [arXiv:1510.04956
Efficiency determination of resistive plate chambers for fast quasi-monoenergetic neutrons
Composite detectors made of stainless steel converters and multigap resistive
plate chambers have been irradiated with quasi-monoenergetic neutrons with a
peak energy of 175MeV. The neutron detection efficiency has been determined
using two different methods. The data are in agreement with the output of Monte
Carlo simulations. The simulations are then extended to study the response of a
hypothetical array made of these detectors to energetic neutrons from a
radioactive ion beam experiment.Comment: Submitted to Eur.Phys.J. A; upgraded version correcting some typos
and updating ref.
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