AI Article Synopsis
- Charge transfer in organic fluorophores can enhance or hinder fluorescence, depending on the process involved, with -alkylation of amine chromophores proving to be an effective method to control these properties.
- Using quinine as a model, -alkylation effects on emission resemble those of pH changes, but allow for the creation of stable species not accessible through traditional acid methods, leading to new insights into quinine's excited states.
- This novel -alkylation technique not only uncovers charge-transfer excited states and related loss pathways in quinine but also facilitates the development of a new salt with improved performance as a quantum yield standard, indicating its potential for broader applications in discovering new emissive materials
Article Abstract
Charge transfer in organic fluorophores is a fundamental photophysical process that can be either beneficial, , facilitating thermally activated delayed fluorescence, or detrimental, , mediating emission quenching. -Alkylation is shown to provide straightforward synthetic control of the charge transfer, emission energy and quantum yield of amine chromophores. We demonstrate this concept using quinine as a model. -Alkylation causes changes in its emission that mirror those caused by changes in pH (, protonation). Unlike protonation, however, alkylation of quinine's two N sites is performed in a stepwise manner to give kinetically stable species. This kinetic stability allows us to isolate and characterize an -alkylated analogue of an 'unnatural' protonation state that is quaternized selectively at the less basic site, which is inaccessible using acid. These materials expose (i) the through-space charge-transfer excited state of quinine and (ii) the associated loss pathway, while (iii) developing a simple salt that outperforms quinine sulfate as a quantum yield standard. This -alkylation approach can be applied broadly in the discovery of emissive materials by tuning charge-transfer states.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8159361 | PMC |
| http://dx.doi.org/10.1039/d0sc02460k | DOI Listing |
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