| Nome |
# |
|
Nuclear astrophysics experiments with trojan horse method, file dfe4d22b-b322-bb0a-e053-d805fe0a78d9
|
83
|
|
A hitchhiker's guide to the Trojan Horse Method, file dfe4d22d-6685-bb0a-e053-d805fe0a78d9
|
24
|
|
The AGB star nucleosynthesis in the light of the recent O-17(p,alpha)N-14 and O-18(p,alpha)N-15 reaction rate determinations, file dfe4d22c-4e7b-bb0a-e053-d805fe0a78d9
|
23
|
|
The 10B(p, α)7Be S(E)-factor from 5 keV to 1.5 MeV using the Trojan Horse Method, file dfe4d22d-1ec0-bb0a-e053-d805fe0a78d9
|
23
|
|
10B(n, α)7Li and10B(n, α1γ)7Li cross section data up to 3 MeV incident neutron energy, file dfe4d22c-4a13-bb0a-e053-d805fe0a78d9
|
20
|
|
Beam-energy dependence and updated test of the Trojan-horse nucleus invariance via a measurement of the H 2 (d,p) H 3 reaction at low energies, file dfe4d22c-4e37-bb0a-e053-d805fe0a78d9
|
20
|
|
A new high-precision upper limit of direct α-decays from the
Hoyle state in 12C, file dfe4d22c-9477-bb0a-e053-d805fe0a78d9
|
20
|
|
Calibration of detectors for studying the 19 F(p,α) 16 O reaction at astrophysical energies via the Trojan Horse Method, file dfe4d22b-b4b1-bb0a-e053-d805fe0a78d9
|
19
|
|
ASTROPHYSICAL IMPACT OF THE UPDATED Be-9(p,alpha)Li-6 AND B-10(p,alpha)Be-7 REACTION RATES AS DEDUCED BY THM, file dfe4d22c-3e90-bb0a-e053-d805fe0a78d9
|
18
|
|
First evidences for 19F(α, p)22Ne at astrophysical energies, file dfe4d22c-47cd-bb0a-e053-d805fe0a78d9
|
17
|
|
Erratum to: An increase in the 12C + 12C fusion rate from resonances at astrophysical energies (Nature, (2018), 557, 7707, (687-690), 10.1038/s41586-018-0149-4), file dfe4d22d-1a84-bb0a-e053-d805fe0a78d9
|
17
|
|
Neutron-induced reactions investigated via the Trojan Horse Method, file dfe4d22b-01fd-bb0a-e053-d805fe0a78d9
|
16
|
|
Measurement of the 10B( p,α0)7Be cross section from 5 keV to 1.5 MeV in a
single experiment using the Trojan horse method, file dfe4d22b-dcc8-bb0a-e053-d805fe0a78d9
|
16
|
|
26Mg target for nuclear astrophysics measurements, file dfe4d22c-32e6-bb0a-e053-d805fe0a78d9
|
16
|
|
Assessing the near threshold cross section of the O 17 (n,α) C 14 reaction by means of the Trojan horse method, file dfe4d22c-3e8f-bb0a-e053-d805fe0a78d9
|
16
|
|
Trojan horse method with neutrons induced reactions: The 17O(n, α)14C reaction, file dfe4d22c-595d-bb0a-e053-d805fe0a78d9
|
16
|
|
Recent results on the 10B(p,α)7Be reaction studied via THM at low energies, file dfe4d22b-d96c-bb0a-e053-d805fe0a78d9
|
15
|
|
The Trojan Horse Method as a tool for investigating astrophysically relevant fusion reactions, file dfe4d22c-601b-bb0a-e053-d805fe0a78d9
|
15
|
|
ANC experiments for nuclear astrophysics in NPI CAS, file dfe4d22d-206c-bb0a-e053-d805fe0a78d9
|
15
|
|
A new measurement of the direct alpha-decay width of the Hoyle state in 12C, file dfe4d22d-2ba2-bb0a-e053-d805fe0a78d9
|
15
|
|
Cross-section Measurement of the Cosmologically Relevant 7Be(n, α)4He Reaction over a Broad Energy Range in a Single Experiment, file dfe4d22b-d973-bb0a-e053-d805fe0a78d9
|
14
|
|
Probing the Early Universe through nuclear physics, file dfe4d22c-2eba-bb0a-e053-d805fe0a78d9
|
14
|
|
The Trojan Horse Method application on the 10B(p, α 0)7Be reaction cross section measurements, file dfe4d22c-2f6b-bb0a-e053-d805fe0a78d9
|
14
|
|
The 12C(12C,α)20Ne and 12C(12C,p)23Na reactions at the Gamow peak via the Trojan Horse Method, file dfe4d22c-3554-bb0a-e053-d805fe0a78d9
|
14
|
|
The Trojan Horse Method in Nuclear Astrophysics, file dfe4d22c-36e8-bb0a-e053-d805fe0a78d9
|
14
|
|
Clusterization of light nuclei and the Trojan Horse Method, file dfe4d22c-422c-bb0a-e053-d805fe0a78d9
|
14
|
|
Improved information on astrophysical S-factor for the10B(p, α0)7Be reaction using the Trojan Horse method, file dfe4d22c-422a-bb0a-e053-d805fe0a78d9
|
13
|
|
New direct measurement of the 10B(p, α)7Be reaction with the activation technique, file dfe4d22c-47b2-bb0a-e053-d805fe0a78d9
|
13
|
|
Nuclear Astrophysics with the Trojan Horse Method, file dfe4d22b-0e84-bb0a-e053-d805fe0a78d9
|
12
|
|
Indirect study of the 16O+16O fusion
reaction toward stellar energies by the
Trojan Horse Method, file dfe4d22c-3132-bb0a-e053-d805fe0a78d9
|
12
|
|
Trojan Horse cross section measurements and their impact on primordial nucleosynthesis, file dfe4d22c-4cda-bb0a-e053-d805fe0a78d9
|
12
|
|
AGB nucleosynthesis: The 19F(α, p)22Ne reaction at astrophysical energies, file dfe4d22c-5956-bb0a-e053-d805fe0a78d9
|
12
|
|
Study of the neutron-induced reaction O-17(n, alpha)C-14 at astrophysical energies via the Trojan Horse Method, file dfe4d22d-7012-bb0a-e053-d805fe0a78d9
|
12
|
|
Improved results on extraction of 11B(p,α0) 8Be and 10B(p,α)7Be S(E)-factor through the Trojan Horse Method, file dfe4d227-abb4-bb0a-e053-d805fe0a78d9
|
11
|
|
The 19F(α,p)22Ne and 23Na(p,α)20Ne Reactions at Energies of Astrophysical Interest via the Trojan Horse Method, file dfe4d22b-ebf4-bb0a-e053-d805fe0a78d9
|
11
|
|
Experimental study to explore the Be-8-induced nuclear reaction via the Trojan horse method (vol 93, 035803, 2016), file dfe4d22c-3070-bb0a-e053-d805fe0a78d9
|
11
|
|
The 19F(α, p)22Ne and 23Na(p, α)20Ne reaction in AGB nucleosynthesis via THM, file dfe4d22c-3c69-bb0a-e053-d805fe0a78d9
|
11
|
|
On the Determination of the 7Be(n, α)4He Reaction Cross Section at BBN Energies, file dfe4d22d-2220-bb0a-e053-d805fe0a78d9
|
11
|
|
The α-decay of the Hoyle state in 12C: A new high-precision investigation, file dfe4d22d-437d-bb0a-e053-d805fe0a78d9
|
11
|
|
Indirect study of (p, alpha) and (n, alpha) reactions induced on boron isotopes, file dfe4d227-35c1-bb0a-e053-d805fe0a78d9
|
10
|
|
The Treiman-Yang Criterion: Validating the Trojan Horse Method by experimentally probing the reaction mechanism, file dfe4d22b-dcbe-bb0a-e053-d805fe0a78d9
|
10
|
|
Primordial nucleosynthesis revisited via Trojan Horse Results, file dfe4d22c-3da3-bb0a-e053-d805fe0a78d9
|
10
|
|
Trojan Horse Method experiments with radioactive ion beams, file dfe4d22c-4236-bb0a-e053-d805fe0a78d9
|
10
|
|
Light elements burning reaction rates at stellar temperatures as deduced by the Trojan Horse measurements, file dfe4d22c-5c0c-bb0a-e053-d805fe0a78d9
|
10
|
|
Investigation of the Hoyle state in12C with a new hodoscope detector, file dfe4d22c-7ff8-bb0a-e053-d805fe0a78d9
|
10
|
|
Neutron-Driven Nucleosynthesis in Stellar Plasma, file 41a2d247-1138-46f3-b0cb-14f7482057ae
|
9
|
|
Validity test of the Trojan Horse Method applied to the (7)Li + p -> alpha plus alpha reaction via the (3)He break-up, file dfe4d227-8a70-bb0a-e053-d805fe0a78d9
|
9
|
|
Indirect measurement of the (15)N(p,alpha)(12)C reaction cross section through the Trojan-Horse Method, file dfe4d227-a9f1-bb0a-e053-d805fe0a78d9
|
9
|
|
Study of nuclear reactions in laser plasmas at future ELI-NP facility, file dfe4d229-66a1-bb0a-e053-d805fe0a78d9
|
9
|
|
THM applied to the investigation of explosive astrophysical scenarios, file dfe4d22b-01fe-bb0a-e053-d805fe0a78d9
|
9
|
|
Observation of N 15 +α resonant structures in F 19 using the thick target in inverse kinematics scattering method, file dfe4d22b-cdb6-bb0a-e053-d805fe0a78d9
|
9
|
|
An increase in the 12C + 12C fusion rate from resonances at astrophysical energies, file dfe4d22b-f413-bb0a-e053-d805fe0a78d9
|
9
|
|
Resonance Strength Measurement at Astrophysical Energies: The 17O(p,α)14N Reaction Studied via THM, file dfe4d22c-636c-bb0a-e053-d805fe0a78d9
|
9
|
|
Studying astrophysical reactions with low-energy RI beams at CRIB, file dfe4d22d-6681-bb0a-e053-d805fe0a78d9
|
9
|
|
The 10B(n, α)7Li cross sections at ultra-low energy through the Trojan Horse Method applied to the 2H(10B, α7 Li)1H, file dfe4d22b-4d9c-bb0a-e053-d805fe0a78d9
|
8
|
|
The astrophysical S-factor of the direct 18O(p, γ)19F capture by the ANC method, file dfe4d22c-3702-bb0a-e053-d805fe0a78d9
|
8
|
|
New measurement of the 10B(p,α0)7Be reaction cross section at low energies and the structure of 11C, file dfe4d22c-3a69-bb0a-e053-d805fe0a78d9
|
8
|
|
Erratum: Beam-energy dependence and updated test of the Trojan-horse nucleus invariance via a measurement of the H 2 (d,p) H 3 reaction at low energies (Physical Review C (2017) 95 (035804) DOI: 10.1103/PhysRevC.95.035804), file dfe4d22c-4e34-bb0a-e053-d805fe0a78d9
|
8
|
|
Preface [EPJ Web of Conferences], file dfe4d22c-4d58-bb0a-e053-d805fe0a78d9
|
7
|
|
The effect of the recent O-17(p,alpha) 14N and O-18(p, alpha)N-15 fusion cross section measurements in the nucleosynthesis of AGB stars, file 40589faa-29f6-4db2-b5fb-6a3954d9169e
|
6
|
|
Spectator invariance test in the study of the Li-6,Li-7 fusion reactions via the Trojan Horse Method, file 6ef038b7-49f4-431c-b5c2-1d9d48235f72
|
6
|
|
Bare nucleus S(E) factor of the H-2(d,p)H-3 and H-2(d,n)He-3 reactions via the Trojan Horse Method, file dfe4d227-381e-bb0a-e053-d805fe0a78d9
|
6
|
|
Measurement of the 20 and 90 keV Resonances in the O-18(p,alpha)N-15 Reaction via the Trojan Horse Method, file dfe4d227-4a23-bb0a-e053-d805fe0a78d9
|
6
|
|
Indirect Measurement of 15N(p,alpha)12C and 18O(p,alpha)15N. Applications to the AGB Star Nucleosynthesis, file dfe4d227-6fa3-bb0a-e053-d805fe0a78d9
|
6
|
|
Study of the 10B(p,α) 7Be reaction through the Trojan
Horse Method, file dfe4d227-7594-bb0a-e053-d805fe0a78d9
|
6
|
|
Recent astrophysical applications of the trojan horse method to nuclear astrophysics, file dfe4d227-8056-bb0a-e053-d805fe0a78d9
|
6
|
|
The role of overshooting treatment in the s-process weak component efficiency, file dfe4d227-98cb-bb0a-e053-d805fe0a78d9
|
6
|
|
New High-Precision Measurement of the Reaction Rate of the O-18(p, alpha)N-15 Reaction via THM, file dfe4d227-aeb7-bb0a-e053-d805fe0a78d9
|
6
|
|
RECENT STUDIES ON TROJAN HORSE METHOD, file dfe4d227-b100-bb0a-e053-d805fe0a78d9
|
6
|
|
Nuclear astrophysics and neutron induced reactions: Quasi-free reactions and
RIBs, file dfe4d227-d0a6-bb0a-e053-d805fe0a78d9
|
6
|
|
Uncovering carbon burning in stars, file dfe4d22b-2ea2-bb0a-e053-d805fe0a78d9
|
6
|
|
Recent THM investigations of the Be-7(n,alpha)He-4 reaction in the BBN scenario, file dfe4d22b-3035-bb0a-e053-d805fe0a78d9
|
6
|
|
Trojan Horse measurement of the F-18(p, alpha)O-15 astrophysical S(E)-factor, file dfe4d22c-4232-bb0a-e053-d805fe0a78d9
|
6
|
|
Trojan Horse particle invariance in fusion reactions, file dfe4d22c-4a0c-bb0a-e053-d805fe0a78d9
|
6
|
|
Study of the neutron induced reaction 17O(n,α)14C at astrophysical energies via the Trojan Horse Method, file e2c7a8b0-41ea-4671-b732-d6f57f198717
|
6
|
|
Nuclear Physics in Stellar Lifestyles with the Trojan Horse Method, file 14bd8b0e-983f-43e6-b57f-c4c080935346
|
5
|
|
Constraining the Primordial Lithium Abundance: New Cross Section Measurement of the 7Be + n Reactions Updates the Total 7Be Destruction Rate, file 2a62db80-d0cd-40fa-aec3-99ebc1c858d8
|
5
|
|
Indirect methods constraining nuclear capture - the Trojan Horse Method, file 53953130-adac-4431-b506-372f767e62ad
|
5
|
|
RIB induced reactions: Studying astrophysical reactions with low-energy RI beam at CRIB, file 5bf39f5b-802a-43ff-a822-f0fde7cd2eed
|
5
|
|
Experimental Study on the 7Be((n,p))7Li and the 7Be((n,alpha ))4He Reactions for Cosmological Lithium Problem, file 6a2c7b62-9d7a-4ae5-b3b6-785ed59acf20
|
5
|
|
Exploring the astrophysical energy range of the 27Al(p,α)24Mg reaction: A new recommended reaction rate, file 70b50735-5fa7-4aea-88a3-04a09ba25b97
|
5
|
|
Direct measurement of the F-19(p,a(0))O-16 reaction at E-cm=0.4-0.9 MeV using the LHASA detector array, file 8e4f2ed2-65e9-47ff-9f56-e9d46e0928c5
|
5
|
|
Experimental studies on astrophysical reactions at the low-energy RI beam separator CRIB, file a36e5491-72fc-468b-9578-a581854191af
|
5
|
|
Study of the Li-6(n, alpha)H-3 reaction via the H-2 quasi-free break-up, file dfe4d227-06c9-bb0a-e053-d805fe0a78d9
|
5
|
|
Effects of Distortion on the Intercluster Motion in Light Nuclei, file dfe4d227-0738-bb0a-e053-d805fe0a78d9
|
5
|
|
On the magnitude of the Li-8+He-4 -> B-11+n reaction cross section at the Big-Bang temperature, file dfe4d227-2888-bb0a-e053-d805fe0a78d9
|
5
|
|
Indirect study of B-11(p,alpha(0))Be-8 and B-10(p,alpha)Be-7 reactions at astrophysical energies by means of the Trojan Horse Method: recent results, file dfe4d227-2942-bb0a-e053-d805fe0a78d9
|
5
|
|
Erratum to “Low-energy d + d fusion reactions via the Trojan Horse Method”
[Phys. Lett. B 700 (2) (2011) 111], file dfe4d227-31a2-bb0a-e053-d805fe0a78d9
|
5
|
|
First application of the Trojan horse method with a radioactive ion beam:
Study of the 18F( p,α)15O reaction at astrophysical energies, file dfe4d227-7006-bb0a-e053-d805fe0a78d9
|
5
|
|
Spectroscopic study of 26Si for application to nova
gamma-ray emission, file dfe4d227-7592-bb0a-e053-d805fe0a78d9
|
5
|
|
New results on the Trojan Horse Method applied to the 10,11B+p reactions, file dfe4d227-7a69-bb0a-e053-d805fe0a78d9
|
5
|
|
Erratum: Molecular structures in T = 1 states of B-10 (vol 84, 054615, 2011), file dfe4d227-a95e-bb0a-e053-d805fe0a78d9
|
5
|
|
High-Precision Probe of the Fully Sequential Decay Width of the Hoyle State in C 12, file dfe4d22c-7f75-bb0a-e053-d805fe0a78d9
|
5
|
|
Coulomb-free 1 S 0 p − p scattering length from the quasi-free p + d → p + p + n reaction and its relation to universality, file f722a6df-b8c7-4ad9-bbb4-57e5f67f0563
|
5
|
|
Electron screening effects in (p,alpha) reactions induced on boron isotopes studied via the Trojan Horse Method, file 18dd2e63-5d66-44ea-b37e-a13fe3ac0f64
|
4
|
|
Application of the Trojan Horse Method to study neutron induced reactions: the O-17(n, alpha)C-14 reaction, file 1de37816-7b98-4407-adc4-b2ff5c690486
|
4
|
|
Trojan Horse particle invariance for H-2(d,p)H-3 reaction: a detailed study, file 2dcd08b3-f940-4301-87d8-054bb04b76c2
|
4
|
|
Study of the 12C + 16O fusion via the Trojan Horse Method, file 666b6740-5e07-44c7-a216-53a978f4be7a
|
4
|
|
Low-energy d plus d fusion via the Trojan Horse Method, file 7f458540-be95-4273-b97b-db61013e6578
|
4
|
|
Trojan Horse Method: recent applications in nuclear astrophysics, file dfe4d227-0732-bb0a-e053-d805fe0a78d9
|
4
|
| Totale |
1.055 |