Kinetics of Water Transfer Between the LCST and UCST Thermoresponsive Blocks in Diblock Copolymer Thin Films Monitored by In Situ Neutron Reflectivity

Hu, Neng; Li, Lin; Metwalli, Ezzeldin; Bießmann, Lorenz; Philipp, Martine; Hildebrand, Viet; Laschewsky, André; Papadakis, Christine M.; Cubitt, R.; Zhong, Qi; Müller‐Buschbaum, Peter

doi:10.1002/admi.202201913

Cited by 4 publications

(1 citation statement)

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“…[21] The hydration of nanostructured biopolymers and polymers is accompanied by complicated changes both in their molecular structure and in their nanoscale architecture. [22][23][24] In the case of aerogels, the exact nature of these changes and the mechanism of the hydration of the backbone can be elucidated in fine details only by the combination of state-of-the-art characterization techniques that provide information on the molecular level structural changes, as well as the alteration of the nanoscale architecture. [25][26][27][28][29] Another complication is, that water is known to be a Janus-type small molecular additive in polymer science; capable of both the plasticization and the anti-plasticization of the same polymer in a concentration dependent manner.…”

Section: Introductionmentioning

confidence: 99%

Mechanism of Hydration Induced Stiffening and Subsequent Plasticization of Polyamide Aerogel

Moldován

Forgács

Paul

et al. 2023

Adv Materials Inter

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The mesoporous polyamide (PA) aerogel similar in chemical structure to DuPont's Kevlar is an advanced thermal insulation material tested in airspace applications. Unfortunately, the monolithic aerogel readily absorbs humidity (from moist air), which dramatically alters its mechanical properties. The compressive strength of the PA aerogel first increases when its water content increases, but subsequently decreases following additional hydration. To provide a coherent explanation for this non-monotonic change, the aerogel is hydrated stepwise and its hydration mechanism is elucidated by multiscale experimental characterization. The molecular structure is investigated by solid-state and liquid-state nuclear magnetic resonance (NMR) spectroscopy, and the morphology by small angle neutron scattering (SANS) at each equilibrium hydration state. The physico-chemical changes in the molecular level and in the nanoscale architecture are reconstructed. The first water molecules bind into the vacancies of the intermolecular H-bonding network of the PA macromolecules, which strengthens this network and causes concerted morphological changes, leading to the macroscopic stiffening of the monolith. Additional water disrupts the original H-bonding network of the macromolecules, which causes their increased segmental motion, marking the start of the partial dissolution of the nanosized fibers of the aerogel backbone. This eventually plasticizes the monolith.

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