Abstract
The photochromic norbornadiene/quadricyclane (NBD/QC) couple has found interest as a molecular solar thermal energy (MOST) system for storage of solar energy. To increase the energy difference between the two isomers, we present here the synthesis of a selection of benzo-fused NBD derivatives that contain an aromatic unit, benzene, naphthalene or phenanthrene, fused to one of the NBD double bonds, while the carbon atoms of the other double bond are functionalized with donor and acceptor groups. The synthesis protocols involve functionalization of benzo-fused NBDs with bromo/chloro substituents followed by a subjection of these intermediates to a cyanation reaction (introducing a cyano acceptor group) followed by a Sonogashira coupling (introducing an arylethynyl donor group, -C≡CC6H4NMe2 or -C≡CC6H4OMe). While the derivatives have good absorption properties in the visible region (redshifted relative to parent system) in the context of MOST applications, they lack the ability to undergo NBD-to-QC photoisomerization, even in the presence of a photosensitizer. It seems that loss of aromaticity of the fused aromatics is too significant to allow photoisomerization to occur. The concept of destroying aromaticity of a neighboring moiety as a way to enhance the energy density of the NBD/QC couple thus needs further structural modifications, in the quest for optimum MOST systems.
Highlights
Functionalized norbornadiene/quadricyclane (NBD/QC) couples have been identified as promising candidates for molecular solar thermal energy storage (MOST) systems that can undergo a closed energy cycle of light absorption, energy storage and energy release [1,2,3]
We have in this work shown that the previously one-pot procedure for functionalization of norbornadiene at one double bond can conveniently be expanded to benzo, naphtho- and phenanthro-fused norbornadienes
This expansion has allowed the synthesis of a selection of derivatives with donor-acceptor substituent groups
Summary
Functionalized norbornadiene/quadricyclane (NBD/QC) couples have been identified as promising candidates for molecular solar thermal energy storage (MOST) systems that can undergo a closed energy cycle of light absorption, energy storage and energy release [1,2,3]. By introduction of donor-acceptor substituents on one or both double bonds of NBD, its absorption maximum can conveniently be redshifted from the UV to the visible region [4,5,6], thereby better matching the solar spectrum. This functionalization, decreases the energy density (from the optimum 1 MJ kg-1 of the parent system) on account of the increased molecular weight of the molecule. By using the same aryl group as a bridging substituent between two NBD units, this decrease in energy density can to some extent be counter-balanced [7].
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