doctoral thesis
Isabela Tišma (Author), Matej Lipoglavšek (Mentor), Miha Mihovilovič (Co-mentor)

Abstract

The theoretical predictions of primordial abundances of the light stable isotopes ${}^{2}$H, ${}^{3}$He, ${}^{4}$He, and ${}^{7}$Li are largely constrained by the experimental uncertainties in the rates of nuclear reactions that occurred during BBN. The observed primordial deuterium abundance has reached a one percent precision, and the same level of precision should be achieved on the BBN-predicted result. The aim of this work was to improve our knowledge of the astrophysical S-factor for the ${}^{2}$H(p,$\gamma$)${}^{3}$He reaction, as it affects significantly the reaction rate and primordial deuterium abundance. The ${}^{2}$H(p,$\gamma$)${}^{3}$He reaction was studied in the energy range of interest for BBN. Its differential cross section at $135^{\circ}$, and $\gamma$-ray angular distributions at $90^{\circ}$ and $135^{\circ}$ were measured in a series of experiments using two deuterated titanium targets, and two HPGe detectors. The compositions of the targets were determined with the NRA and RBS techniques. The S-factor was obtained in the center-of-mass energy range $E$ = 97--210 keV. The achieved systematic uncertainty (10%) of the present measurements did not allow an evaluation of different theoretical S-factor calculations. Thus, more accurate data are needed at BBN energies. To check the lithium abundance problem, the effect of electron screening on the rates of nuclear reactions relevant for BBN was investigated. It was found that the electron screening effect is too small to have a notable impact on reaction rates in BBN temperature range, and hence also on the primordial abundances of light element isotopes. Additionally, the $E$ = 259 keV resonance in the ${}^{14}$N(p,$\gamma$)${}^{15}$O reaction was measured in normal and inverse kinematics, in order to confirm large electron screening in inverse kinematics reactions, as some previous studies suggest. The results obtained indicate smaller resonance strength values in inverse kinematics. The reason for this behaviour is currently unknown, and will be provided by the next generation of experiments.

Keywords

nuclear physics;nuclear reactions;astrophysics;Big-Bang;nucleosynthesis;radiative capture;elemental abundances;electron screening;

Data

Language: English
Year of publishing:
Typology: 2.08 - Doctoral Dissertation
Organization: UL FMF - Faculty of Mathematics and Physics
Publisher: [I. Tišma]
UDC: 539.17(043.3)
COBISS: 75686915 Link will open in a new window
Views: 254
Downloads: 30
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Other data

Secondary language: Slovenian
Secondary title: Jedrske reakcije pri nukleosintezi po velikem poku
Secondary abstract: Teoretične napovedi primarnih vsebnosti izotopov lahkih elementov ${}^{2}$H, ${}^{3}$He, ${}^{4}$He in ${}^{7}$Li so v veliki meri omejene z eksperimentalnimi negotovostmi hitrosti jedrskih reakcij, ki so se dogajale med sintezo elementov po velikem poku. Primarna vsebnost devterija določena iz astronomskih opazovanj je dosegla natančnost enega procenta in podobno natančnost bi pričakovali tudi od teoretičnih napovedi nukleosinteze po velikem poku. Namen tega dela je bil izboljšati naše poznavanje astrofizikalnega S-faktorja za jedrsko reakcijo ${}^{2}$H(p,$\gamma$)${}^{3}$He, ki pomembno vpliva na hitrost reakcije in primarno vsebnost devterija. Dano reakcijo smo študirali v energijskem območju pomembnem za nukleosintezo po velikem poku. Diferencialni reakcijski presek in kotno odvisnost žarkov $\gamma$ pri kotih $90^{\circ}$ in $135^{\circ}$ smo izmerili v nizu eksperimentov z uporabo dveh devteriranih titanovih tarč in dveh germanijevih detektorjev. Sestavo tarč smo določili s tehnikama NRA in RBS. Astrofizikalni S-faktor smo določili za težiščne energije med $E$ = 97--210 keV in ga primerjali z dostopnimi teoretičnimi izračuni. Z dano sistematsko negotovostjo (10%) nismo mogli določiti, kateri teoretični model bolje opiše nove izmerjene podatke. Tako potrebujemo bolj natančne podatke v energijskem območju velikega poka. Za preveritev problema vsebnosti litija v vesolju, smo raziskali vpliv efekta elektronskega senčenja na hitrosti jedrskih reakcij pomembnih za nukleosintezo po velikem poku. Pokazali smo, da je efekt elektronskega senčenja premajhen, da bi imel zaznaven vpliv na hitrosti jedrskih reakcij v temperaturnem območju velikega poka in s tem na primarne vsebnosti izotopov lahkih elementov. Poleg tega smo izmerili jakost resonance pri $E$ = 259 keV v reakciji ${}^{14}$N(p,$\gamma$)${}^{15}$O tako v normalni kot tudi v inverzni kinematiki. S tem smo želeli potrditi velik efekt elektronskega senčenja v inverzni reakcijski kinematiki, kot so napovedale prejšnje študije. Naši rezultati kažejo nižje jakosti resonanc v inverzni kinematiki kot v normalni kinematiki. Takega obnašanja še ne razumemo in ga bomo poskusili razložiti z naslednjo generacijo eksperimentov.
Secondary keywords: jedrska fizika;jedrske reakcije;astrofizika;veliki pok;nukleosinteza;sevalno zajetje;vsebnosti elementov;elektronsko senčenje;Jedrske reakcije;Disertacije;Astrofizika;
Type (COBISS): Doctoral dissertation
Study programme: 0
Thesis comment: Univ. v Ljubljani, Fak. za matematiko in fiziko, Oddelek za fiziko
Pages: XX, 85 str.
ID: 13352795