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Beilstein J. Nanotechnol. 2020, 11, 1663–1684, doi:10.3762/bjnano.11.149
Figure 1: (a) Schematic diagram of the radiative and non-radiative decay processes of an optical excitation o...
Figure 2: Overview spectra of 1.55 ML PTCDA on Cu(111) (red), of 0.50 ML PTCDA on hBN/Cu(111) (blue), and of ...
Figure 3: Zoom-in on the high-energy region (III) of the spectra. (a) 0.80 ML PTCDA/hBN/Cu(111) after deposit...
Figure 4: Fluorescence spectra of (a) 0.60 ML PTCDA and (b) 1.55 ML PTCDA on hBN/Cu(111) as deposited at 20 K...
Figure 5: (a) Fluorescence spectra of PTCDA on hBN/Cu(111) (left, blue spectra, prepared by deposition at 20 ...
Figure 6: Fluorescence spectra of 0.60 ML PTCDA/hBN/Cu(111) (blue, bottom) and 2.55 ML PTCDA/Cu(111) (red, to...
Figure 7: LEED pattern of (a) 1 ML PTCDA/Cu(111) and (b) 1.55 ML PTCDA/Cu(111) deposited at 300 K. On the lef...
Figure 8: LEED pattern of PTCDA layers on hBN/Cu(111). (a) LEED pattern of 2 ± 0.5 ML PTCDA/hBN/Cu(111). The ...
Figure 9: Raman modes of 0.90 ML PTCDA on hBN/Cu(111), measured with a dye laser with tunable wavelength (497...
Figure 10: FL spectra of 0.50 ML PTCDA on hBN/Cu(111), deposited at 20 K and subsequently annealed at 300 K (b...