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This paper introduces pyglotaran, a new Python framework for global and target analysis of time-resolved spectra, and the spiritual successor to (legacy) Glotaran.
The novel features are showcased through three case studies, for which Jupyter notebooks are available:
- The first study uses guidance spectra and a parametric description to detail "coherent artifact" (CA) in transient absorption, revealing the framework's capability to resolve vibrational wavepackets via damped oscillations.
- The second focuses on the light-absorbing efficiency of multichromophoric systems, especially when comprised of two chromophores.
- The final case study elucidates the energy transfer pathways in the time-resolved emission of whole photosynthetic cells, characterizing the contributions of numerous megacomplexes. These studies span systems ranging from singular chromophores to a megacomplex of approximately 500, with temporal resolutions between ≈10 fs to ≈10 ps.
The figure below visually summarizes the results from the first case-study. All plots are generate using pyglotaran and the plotting package pyglotaran-extras.
Figure 1 of 10.1007_s43630-023-00460-y (reproduced as is) showing axample of a
- time-resolved difference absorption Spectrum and fit thereof (row 1),
- with the help of a compartmental model (row 2),
- the damped oscillations (row 3),
- a “coherent artifact” (CA) (row 4)
- and the residual (row 5).
DOI: 10.1007/s43630-023-00460-y