Issue 89, 2017

Light harvesting in silicon(111) surfaces using covalently attached protoporphyrin IX dyes

Abstract

We report the photosensitization of crystalline silicon via energy transfer using covalently attached protoporphyrin IX (PpIX) derivative molecules at different distances via changing the diol linker to the surface. The diol linker molecule chain length was varied from 2 carbon to 10 carbon lengths in order to change the distance of PpIX to the Si(111) surface between 6 Å and 18 Å. Fluorescence quenching as a function of the PpIX–Si surface distance showed a decrease in the fluorescence lifetime by almost two orders of magnitude at the closest separation. The experimental fluorescence lifetimes are explained theoretically by a classical Chance–Prock–Silbey model. At a separation below 2 nm, we observe for the first time, a Förster-like dipole–dipole energy transfer with a characteristic distance of R0 = 2.7 nm.

Graphical abstract: Light harvesting in silicon(111) surfaces using covalently attached protoporphyrin IX dyes

Supplementary files

Article information

Article type
Communication
Submitted
19 Jun 2017
Accepted
18 Oct 2017
First published
19 Oct 2017

Chem. Commun., 2017,53, 12120-12123

Light harvesting in silicon(111) surfaces using covalently attached protoporphyrin IX dyes

N. Alderman, L. Danos, L. Fang, M. C. Grossel and T. Markvart, Chem. Commun., 2017, 53, 12120 DOI: 10.1039/C7CC04767C

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