science:phd-notes:2025-03-03-lee
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| science:phd-notes:2025-03-03-lee [2025/03/07 06:58] – Extend text on OBTD analysis jon-dokuwiki | science:phd-notes:2025-03-03-lee [2025/03/07 15:13] (current) – Extend info on orbitals and obtds jon-dokuwiki | ||
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| - | The $pf$ shell is by far the most dominant for neutrons, while for protons there are also some strong contributions from the $sd$ shell. This makes sense as the fermi level for neutrons is higher than the fermi level for protons. Recall | + | The $pf$ shell is by far the most dominant for neutrons, while for protons there are also some strong contributions from the $sd$ shell. This makes sense as the fermi level for neutrons is higher than the fermi level for protons |
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| + | It might at first seem strange that there are transitions from and to the same orbital, like for example $0f7/2 \rightarrow 0f7/2$. $0f7/2$ does of course have 8 sub-states for the different z-projections of the total angular momentum vector, but they are degenerate, meaning that they have the same energy. This is however true only in the pure single-particle picture. When there are several particles in say $0f7/2$ there are nucleon-nucleon interactions which give rise to configurations which are more energetically favourable than others, for example pairing forces which favours pairing up nucleons with opposite $j_z$ (eg. 1/2 and -1/2). The energy differences – and hence gamma energies – which arise from these kinds of nucleon-nucleon interactions are of comparatively low energy, and consequently, | ||
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| + | Spin-flip transitions are those where, big surprise, the spin of the nucleon is flipped. That means for example $0f7/2 \rightarrow 0f5/2$, and more generally, orbital partners with the same $l$ value but different $j$. The energy of such a transition should be decided by the energy splitting imposed by the spin-orbit splitting (the $\bm{l} \cdot \bm{s}$ term in the potential). The energy from the spin-orbit splitting is typically much larger than the energy from the aforementioned nucleon-nucleon interactions. | ||
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| + | Let's start by removing $0f7/2 \rightarrow 0f7/2$! On the left side you see the GSF with the modified $M1$ strength function in green. On the right side I'm showing the OBTD grid (this time protons and neutrons are summed) so that we can visualise the orbitals which have been removed. | ||
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| + | We can see the absence of $0f7/2 \rightarrow 0f7/2$ in the OBTD grid to the right, and we can see that it has a huge impact on the strength function to the left. The impact is largest in the low-energy region, less so as the gamma energy increases, and then at approx. 7 MeV it reaches the same amplitude as the non-modified $M1$ strength function in red. This shows that $0f7/2 \rightarrow 0f7/2$ transitions are strong at the lower gamma energies. | ||
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| + | In the following, I have removed all the diagonal elements, aka. the transitions within the same orbital. | ||
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| + | As you can see, the low-energy part of the GSF decreases even more, and maybe more interesting, | ||
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| + | Looks good! The low-energy strength is back while the high-energy strength is significantly reduced. Now what if we allow only $0f7/2 \rightarrow 0f7/2$ on the diagonal? Let's see! | ||
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| + | This one is also pretty interesting. Keeping only $0f7/2 \rightarrow 0f7/2$ on the diagonal almost retains the original $M1$ strength function. As we saw earlier, $0f7/2 \rightarrow 0f7/2$ carries almost no high energy strength meaning that the high energy strength is retained by the non-diagonals, | ||
science/phd-notes/2025-03-03-lee.1741327122.txt.gz · Last modified: 2025/03/07 06:58 by jon-dokuwiki