Issue 15, 2024

Nanometrology based control: taming radical grafting reactions with attoliter precision

Abstract

Precisely controlled micropatterning with organic moieties is a promising route for designing smart surfaces, enabling the development of microsensors and actuators with optimal usage of reactants. Such applications require fine control over the surface modification process, which in turn demands detailed knowledge about the surface modification process. As complex surface kinetics often emerge as a result of even slight modifications of the grafting entity, non-invasive, sensitive and precise closed loop control strategies are highly desirable. In this paper we demonstrate that a nanometrology approach based on quantitative phase imaging (QPI) fulfill all these requirements. We first use the technique to monitor surface photografting kinetics of aryl radicals, comprehensively analyzing the effect of substituents on surface addition reactions. We demonstrate that several aspects of the grafting process are affected in complex ways, rendering open-loop strategies impossible to implement precisely. Then, we show that the operando optical phase signal can be used as a direct feedback, guiding the grafting reaction process. Using relatively simple instrumentation, we demonstrate that general and precise control strategies can be designed and used to control the volume of the grafting material with attoliter precision, in spite of radically different surface modification kinetics spanning several orders of magnitude.

Graphical abstract: Nanometrology based control: taming radical grafting reactions with attoliter precision

Supplementary files

Article information

Article type
Paper
Submitted
11 Dec 2023
Accepted
11 Mar 2024
First published
12 Mar 2024
This article is Open Access
Creative Commons BY-NC license

Nanoscale, 2024,16, 7594-7602

Nanometrology based control: taming radical grafting reactions with attoliter precision

B. Maillot, J. Audibert, F. Miomandre and V. Brasiliense, Nanoscale, 2024, 16, 7594 DOI: 10.1039/D3NR06324K

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