Kinetic Control and Trapping in the Supramolecular Polymerization of m-Terphenyl Bis-Urea Macrocycles

Gamage Isuri P. Wijesekera; Isabella G. Rushton; Vaibhavi A. Samant; Fahidat A. Gbadamosi; Md Faizul Islam; Mark D. Smith; Shehani T. Wetthasinghe; Sophya Garashchuk; Linda S. Shimizu

doi:10.1002/chem.202404552

Kinetic Control and Trapping in the Supramolecular Polymerization of m-Terphenyl Bis-Urea Macrocycles

Gamage Isuri P. Wijesekera
, Isabella G. Rushton
, Vaibhavi A. Samant
, Fahidat A. Gbadamosi
, Md Faizul Islam
, Mark D. Smith
, Shehani T. Wetthasinghe
, Sophya Garashchuk
, Linda S. Shimizu

Research output: Contribution to journal › Article › peer-review

2 Scopus citations

Abstract

Herein, we examine pathway complexity in the supramolecular polymerization of a novel m-terphenyl bis-urea macrocycle. Designed to induce kinetically metastable states, the macrocycle‘s concentration-dependent aggregation was studied via ¹H NMR and IR spectroscopy in THF and CHCl₃. Temperature-dependent UV-Vis spectroscopy in water/THF revealed a cooperative nucleation-growth mechanism, indicated by a shift in λmax to longer wavelengths upon cooling. Morphological studies using DLS, AFM, and SEM demonstrated fibrous aggregate formation. Thermal hysteresis observed in assembly-disassembly cycles indicated kinetically trapped species, with cooling governed by kinetic control and heating by thermodynamic processes. Deviations in ΔH values during cooling, compared to van′t Hoff analysis and alignment of heating ΔH values with thermodynamic predictions, reinforced this distinction. Spontaneous nucleation retardation, resulting from monomer trapping, led to lag times of up to 50 minutes under specific conditions. Computational studies revealed the parallel urea conformation as the more stable monomer configuration, whereas the antiparallel conformation is more stable in dimers. By probing pathway complexity of the macrocycle, we demonstrate a distinct ability to control and stabilize kinetically trapped states, broadening the scope for designing macrocyclic supramolecular polymers with tailored properties. This work deepens our understanding of supramolecular dynamics, exploring ON-pathway mechanisms and advancing tunable supramolecular materials.

Original language	English
Article number	e202404552
Journal	Chemistry - A European Journal
Volume	31
Issue number	19
DOIs	https://doi.org/10.1002/chem.202404552
State	Published - Apr 1 2025
Externally published	Yes

Funding

This work was supported in part by the National Science Foundation (NSF) CHE‐2203830 and CHE‐2308922. Any opinions, findings, and conclusions, or recommendations expressed in this material are those of the authors and do not necessarily reflect those of the NSF. We thank Dr. Iftikhar Ahmad and his group for their support in acquiring the AFM images, and Prof. Vitaly Rassolov for many helpful discussions.

Keywords

hydrogen bonding
kinetic trapping, hydrogen bonding
m-terphenyl
self-assembly
supramolecular polymerization
thermal hysteresis

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10.1002/chem.202404552

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title = "Kinetic Control and Trapping in the Supramolecular Polymerization of m-Terphenyl Bis-Urea Macrocycles",

abstract = "Herein, we examine pathway complexity in the supramolecular polymerization of a novel m-terphenyl bis-urea macrocycle. Designed to induce kinetically metastable states, the macrocycle{\textquoteleft}s concentration-dependent aggregation was studied via 1H NMR and IR spectroscopy in THF and CHCl₃. Temperature-dependent UV-Vis spectroscopy in water/THF revealed a cooperative nucleation-growth mechanism, indicated by a shift in λmax to longer wavelengths upon cooling. Morphological studies using DLS, AFM, and SEM demonstrated fibrous aggregate formation. Thermal hysteresis observed in assembly-disassembly cycles indicated kinetically trapped species, with cooling governed by kinetic control and heating by thermodynamic processes. Deviations in ΔH values during cooling, compared to van′t Hoff analysis and alignment of heating ΔH values with thermodynamic predictions, reinforced this distinction. Spontaneous nucleation retardation, resulting from monomer trapping, led to lag times of up to 50 minutes under specific conditions. Computational studies revealed the parallel urea conformation as the more stable monomer configuration, whereas the antiparallel conformation is more stable in dimers. By probing pathway complexity of the macrocycle, we demonstrate a distinct ability to control and stabilize kinetically trapped states, broadening the scope for designing macrocyclic supramolecular polymers with tailored properties. This work deepens our understanding of supramolecular dynamics, exploring ON-pathway mechanisms and advancing tunable supramolecular materials.",

keywords = "hydrogen bonding, kinetic trapping, hydrogen bonding, m-terphenyl, self-assembly, supramolecular polymerization, thermal hysteresis",

author = "Wijesekera, \{Gamage Isuri P.\} and Rushton, \{Isabella G.\} and Samant, \{Vaibhavi A.\} and Gbadamosi, \{Fahidat A.\} and Islam, \{Md Faizul\} and Smith, \{Mark D.\} and Wetthasinghe, \{Shehani T.\} and Sophya Garashchuk and Shimizu, \{Linda S.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Chemistry - A European Journal published by Wiley-VCH GmbH.",

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T1 - Kinetic Control and Trapping in the Supramolecular Polymerization of m-Terphenyl Bis-Urea Macrocycles

AU - Wijesekera, Gamage Isuri P.

AU - Rushton, Isabella G.

AU - Samant, Vaibhavi A.

AU - Gbadamosi, Fahidat A.

AU - Islam, Md Faizul

AU - Smith, Mark D.

AU - Wetthasinghe, Shehani T.

AU - Garashchuk, Sophya

AU - Shimizu, Linda S.

PY - 2025/4/1

Y1 - 2025/4/1

N2 - Herein, we examine pathway complexity in the supramolecular polymerization of a novel m-terphenyl bis-urea macrocycle. Designed to induce kinetically metastable states, the macrocycle‘s concentration-dependent aggregation was studied via 1H NMR and IR spectroscopy in THF and CHCl₃. Temperature-dependent UV-Vis spectroscopy in water/THF revealed a cooperative nucleation-growth mechanism, indicated by a shift in λmax to longer wavelengths upon cooling. Morphological studies using DLS, AFM, and SEM demonstrated fibrous aggregate formation. Thermal hysteresis observed in assembly-disassembly cycles indicated kinetically trapped species, with cooling governed by kinetic control and heating by thermodynamic processes. Deviations in ΔH values during cooling, compared to van′t Hoff analysis and alignment of heating ΔH values with thermodynamic predictions, reinforced this distinction. Spontaneous nucleation retardation, resulting from monomer trapping, led to lag times of up to 50 minutes under specific conditions. Computational studies revealed the parallel urea conformation as the more stable monomer configuration, whereas the antiparallel conformation is more stable in dimers. By probing pathway complexity of the macrocycle, we demonstrate a distinct ability to control and stabilize kinetically trapped states, broadening the scope for designing macrocyclic supramolecular polymers with tailored properties. This work deepens our understanding of supramolecular dynamics, exploring ON-pathway mechanisms and advancing tunable supramolecular materials.

AB - Herein, we examine pathway complexity in the supramolecular polymerization of a novel m-terphenyl bis-urea macrocycle. Designed to induce kinetically metastable states, the macrocycle‘s concentration-dependent aggregation was studied via 1H NMR and IR spectroscopy in THF and CHCl₃. Temperature-dependent UV-Vis spectroscopy in water/THF revealed a cooperative nucleation-growth mechanism, indicated by a shift in λmax to longer wavelengths upon cooling. Morphological studies using DLS, AFM, and SEM demonstrated fibrous aggregate formation. Thermal hysteresis observed in assembly-disassembly cycles indicated kinetically trapped species, with cooling governed by kinetic control and heating by thermodynamic processes. Deviations in ΔH values during cooling, compared to van′t Hoff analysis and alignment of heating ΔH values with thermodynamic predictions, reinforced this distinction. Spontaneous nucleation retardation, resulting from monomer trapping, led to lag times of up to 50 minutes under specific conditions. Computational studies revealed the parallel urea conformation as the more stable monomer configuration, whereas the antiparallel conformation is more stable in dimers. By probing pathway complexity of the macrocycle, we demonstrate a distinct ability to control and stabilize kinetically trapped states, broadening the scope for designing macrocyclic supramolecular polymers with tailored properties. This work deepens our understanding of supramolecular dynamics, exploring ON-pathway mechanisms and advancing tunable supramolecular materials.

KW - hydrogen bonding

KW - kinetic trapping, hydrogen bonding

KW - m-terphenyl

KW - self-assembly

KW - supramolecular polymerization

KW - thermal hysteresis

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SN - 0947-6539

VL - 31

JO - Chemistry - A European Journal

JF - Chemistry - A European Journal

IS - 19

M1 - e202404552

ER -

Kinetic Control and Trapping in the Supramolecular Polymerization of m-Terphenyl Bis-Urea Macrocycles

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Keywords

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