Abstract

Soft matter that undergoes programmed macroscopic responses to molecular analytes has potential utility in a range of health and safety-related contexts. In this study, we report the design of a nematic liquid crystal (LC) composition that forms through dimerization of carboxylic acids and responds to the presence of vapors of organoamines by undergoing a visually distinct phase transition to an isotropic phase. Specifically, we screened mixtures of two carboxylic acids, 4-butylbenzoic acid and trans-4-pentylcyclohexanecarboxylic acid, and found select compositions that exhibited a nematic phase from 30.6 to 111.7 °C during heating and 110.6 to 3.1 °C during cooling. The metastable nematic phase formed at ambient temperatures was found to be long-lived (>5 days), thus enabling the use of the LC as a chemoresponsive optical material. By comparing experimental infrared (IR) spectra of the LC phase with vibrational frequencies calculated using density functional theory (DFT), we show that it is possible to distinguish between the presence of monomers, homodimers and heterodimers in the mixture, leading us to conclude that a one-to-one heterodimer is the dominant species within this LC composition. Further support for this conclusion is obtained by using differential scanning calorimetry. Exposure of the LC to 12 ppm triethylamine (TEA) triggers a phase transition to an isotropic phase, which we show by IR spectroscopy to be driven by an acid-base reaction, leading to the formation of ammonium carboxylate salts. We characterized the dynamics of the phase transition and found that it proceeds via a characteristic spatiotemporal pathway involving the nucleation, growth, and coalescence of isotropic domains, thus amplifying the atomic-scale acid-base reaction into an information-rich optical output. In contrast to TEA, we determined via both experiment and computation that neither hydrogen bonding donor or acceptor molecules, such as water, dimethyl methylphosphonate, ethylene oxide or formaldehyde, disrupt the heterodimers formed in the LC, hinting that the phase transition (including spatial-temporal characteristics of the pathway) induced in this class of hydrogen bonded LC may offer the basis of a facile and chemically selective way of reporting the presence of volatile amines. This proposal is supported by exploratory experiments in which we show that it is possible to trigger a phase transition in the LC by exposure to volatile amines emitted from rotting fish. Overall, these results provide new principles for the design of chemoresponsive soft matter based on hydrogen bonded LCs that may find use as the basis of low-cost visual indicators of chemical environments.

Highlights

  • Responsive soft materials change their structure and properties upon interaction with their environment

  • We show that an acid-based reaction between the liquid crystal (LC) and volatile amines triggers a phase transition from a nematic to an isotropic phase that is accompanied by a distinct optical response

  • Motivated by the proposal that mixtures of mesogen can lead to a lowering of phase transition temperatures [30], we investigated mixtures of trans-4-pentylcyclohexanecarboxylic acid (C5CA) [29] and 4-butylbenzoic acid (C4BA) [28], which are two known hydrogen bonding LCs

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Summary

Introduction

Responsive soft materials change their structure and properties (e.g., mechanical [1,2], chemical [3] and optical [4]) upon interaction with their environment. This class of soft materials is being widely explored as the basis of a range of emerging technologies, including for drug delivery [5], chemical sensors [3,6], and actuators [1,2]. Micrometer-thick films of nematic LCs have been oriented on the surfaces of tailored solids via hydrogen bonding [14], metal cation-ligand coordination interactions [15,16] and bonding to metals (dissociative adsorption) [17]

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