M. P. Takács
Dresden University of Technology
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Featured researches published by M. P. Takács.
Physical Review Letters | 2016
C. G. Bruno; D. A. Scott; M. Aliotta; A. Formicola; A. Best; A. Boeltzig; D. Bemmerer; C. Broggini; A. Caciolli; F. Cavanna; G. F. Ciani; P. Corvisiero; Thomas Davinson; R. Depalo; A. Di Leva; Z. Elekes; F. Ferraro; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; G. Imbriani; M. Junker; R. Menegazzo; V. Mossa; F. R. Pantaleo; D. Piatti; P. Prati; E. Somorjai
The ^{17}O(p,α)^{14}N reaction plays a key role in various astrophysical scenarios, from asymptotic giant branch stars to classical novae. It affects the synthesis of rare isotopes such as ^{17}O and ^{18}F, which can provide constraints on astrophysical models. A new direct determination of the E_{R}=64.5 keV resonance strength performed at the Laboratory for Underground Nuclear Astrophysics (LUNA) accelerator has led to the most accurate value to date ωγ=10.0±1.4_{stat}±0.7_{syst} neV, thanks to a significant background reduction underground and generally improved experimental conditions. The (bare) proton partial width of the corresponding state at E_{x}=5672 keV in ^{18}F is Γ_{p}=35±5_{stat}±3_{syst} neV. This width is about a factor of 2 higher than previously estimated, thus leading to a factor of 2 increase in the ^{17}O(p, α)^{14}N reaction rate at astrophysical temperatures relevant to shell hydrogen burning in red giant and asymptotic giant branch stars. The new rate implies lower ^{17}O/^{16}O ratios, with important implications on the interpretation of astrophysical observables from these stars.
Physical Review D | 2015
M. P. Takács; K. Zuber; D. Bemmerer; T. Szücs
The 3He({\alpha},{\gamma})7Be reaction affects not only the production of 7Li in Big Bang nucleosynthesis, but also the fluxes of 7Be and 8B neutrinos from the Sun. This double role is exploited here to constrain the former by the latter. A number of recent experiments on 3He({\alpha},{\gamma})7Be provide precise cross section data at E = 0.5-1.0 MeV center-of-mass energy. However, there is a scarcity of precise data at Big Bang energies, 0.1-0.5 MeV, and below. This problem can be alleviated, based on precisely calibrated 7Be and 8B neutrino fluxes from the Sun that are now available, assuming the neutrino flavour oscillation framework to be correct. These fluxes and the standard solar model are used here to determine the 3He(alpha,gamma)7Be astrophysical S-factor at the solar Gamow peak, S(23+6-5 keV) = 0.548+/-0.054 keVb. This new data point is then included in a re-evaluation of the 3He({\alpha},{\gamma})7Be S-factor at Big Bang energies, following an approach recently developed for this reaction in the context of solar fusion studies. The re-evaluated S-factor curve is then used to re-determine the 3He({\alpha},{\gamma})7Be thermonuclear reaction rate at Big Bang energies. The predicted primordial lithium abundance is 7Li/H = 5.0e-10, far higher than the Spite plateau.
European Physical Journal A | 2015
T. Szücs; D. Bemmerer; Tobias P. Reinhardt; Konrad Schmidt; M. P. Takács; A. Wagner; L. Wagner; D. Weinberger; K. Zuber
Abstract.The main background above 3MeV for in-beam nuclear astrophysics studies with
European Physical Journal A | 2018
F. Ferraro; M. P. Takács; D. Piatti; V. Mossa; M. Aliotta; D. Bemmerer; A. Best; A. Boeltzig; C. Broggini; C. G. Bruno; A. Caciolli; F. Cavanna; T. Chillery; G. F. Ciani; P. Corvisiero; L. Csedreki; T. Davinson; R. Depalo; G. D’Erasmo; A. Di Leva; Z. Elekes; E. M. Fiore; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; G. Imbriani; M. Junker
\gamma
EPL | 2018
D. Bemmerer; F. Cavanna; R. Depalo; M. Aliotta; M. Anders; A. Boeltzig; C. Broggini; C. G. Bruno; A. Caciolli; T. Chillery; P. Corvisiero; T. Davinson; Z. Elekes; F. Ferraro; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; R. Menegazzo; V. Mossa; F. R. Pantaleo; P. Prati; D. A. Scott; K. Stöcker; O. Straniero; T. Szücs; M. P. Takács; D. Trezzi
-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 148m 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 45m and 1400m, respectively.
Physical Review C | 2015
T. Szücs; D. Bemmerer; A. Caciolli; Zs. Fülöp; R. Massarczyk; C. Michelagnoli; T. P. Reinhardt; R. Schwengner; M. P. Takács; C. A. Ur; A. Wagner; L. Wagner
Abstract.The experimental study of nuclear reactions of astrophysical interest is greatly facilitated by a low-background, high-luminosity setup. The Laboratory for Underground Nuclear Astrophysics (LUNA) 400kV accelerator offers ultra-low cosmic-ray induced background due to its location deep underground in the Gran Sasso National Laboratory (INFN-LNGS), Italy, and high intensity, 250-500μA, proton and
Astronomy and Astrophysics | 2017
O. Straniero; C. G. Bruno; M. Aliotta; A. Best; A. Boeltzig; D. Bemmerer; C. Broggini; A. Caciolli; F. Cavanna; G. F. Ciani; P. Corvisiero; S. Cristallo; T. Davinson; R. Depalo; A. Di Leva; Z. Elekes; F. Ferraro; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; G. Gyürky; G. Imbriani; M. Junker; R. Menegazzo; V. Mossa; F. R. Pantaleo; D. Piatti; Luciano Piersanti
\alpha
Physical Review C | 2016
R. Depalo; F. Cavanna; M. Aliotta; M. Anders; D. Bemmerer; A. Best; A. Boeltzig; C. Broggini; C. G. Bruno; A. Caciolli; G. F. Ciani; P. Corvisiero; T. Davinson; A. Di Leva; Z. Elekes; F. Ferraro; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; G. Imbriani; M. Junker; R. Menegazzo; V. Mossa; F. R. Pantaleo; D. Piatti; P. Prati; O. Straniero
α ion beams. In order to fully exploit these features, a high-purity, recirculating gas target system for isotopically enriched gases is coupled to a high-efficiency, six-fold optically segmented bismuth germanate (BGO)
Physical Review C | 2016
R. Depalo; F. Cavanna; M. Aliotta; M. Anders; D. Bemmerer; A. Best; A. Boeltzig; C. Broggini; C. G. Bruno; A. Caciolli; G. F. Ciani; P. Corvisiero; Thomas Davinson; A. Di Leva; Z. Elekes; F. Ferraro; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; G. Imbriani; M. Junker; R. Menegazzo; V. Mossa; F. R. Pantaleo; D. Piatti; P. Prati; O. Straniero
\gamma
Physical Review C | 2016
R. Depalo; F. Cavanna; M. Aliotta; M. Anders; D. Bemmerer; A. Best; A. Boeltzig; C. Broggini; C. G. Bruno; A. Caciolli; G. F. Ciani; P. Corvisiero; T. Davinson; A. Di Leva; Z. Elekes; F. Ferraro; A. Formicola; Zs. Fülöp; G. Gervino; A. Guglielmetti; C. Gustavino; Gy. Gyürky; G. Imbriani; M. Junker; R. Menegazzo; V. Mossa; F. R. Pantaleo; D. Piatti; P. Prati; O. Straniero
γ-ray detector. The beam intensity is measured with a beam calorimeter with constant temperature gradient. Pressure and temperature measurements have been carried out at several positions along the beam path, and the resultant gas density profile has been determined. Calibrated
