What does this research mean for the field?

Temperature and density significantly modulate the 129Xe NMR chemical shifts in carbon nanotubes, with shifts increasing by 5-13 ppm at low densities and by 20-30 ppm due to nanotube motion. Novelty: ClaimNovelty.NOVEL_FINDING. Consensus alignment: ConsensusAlignment.NEUTRAL.

What question did this study set out to answer?

This research aims to understand how temperature and density of xenon gas impact 129Xe NMR chemical shifts in carbon nanotubes.

February 26, 2026Open Access

Modeling 129Xe NMR chemical shift sensitivity in carbon nanotube systems

Key Points

This research aims to understand how temperature and density of xenon gas impact 129Xe NMR chemical shifts in carbon nanotubes.
Conducted multiscale computational simulations using Canonical Monte Carlo and molecular dynamics/DFT calculations.
Examined the statistical behavior of xenon atoms in pristine carbon nanotubes and bundles.
Analyzed the effects of temperature and gas density on chemical shifts.
At low xenon densities, the chemical shift increases by 5–13 ppm compared to static equilibrium positions.
Chemical shifts inside narrow CNTs increase linearly with temperature, while wider tubes show nonlinear shifts at high temperatures.
Xenon interactions increase density dependence, resulting in shifts around 200 ppm external to CNTs.
Including nanotube motion raises the chemical shift inside by 20–30 ppm.

Abstract

Understanding xenon nuclear magnetic resonance (NMR) in confined environments is essential for characterizing porous materials at the nanoscale. Here, we investigate how temperature and density of the xenon gas affect the 129 Xe NMR chemical shift in pristine carbon nanotubes (CNTs) and CNT bundles using a multiscale computational approach. Canonical Monte Carlo (MC) simulations on static potential energy (PES) and chemical shift surfaces (CSS) are applied to capture the statistical behavior of Xe atoms, while molecular dynamics/DFT calculations provide insight into the role of CNT dynamics. At low Xe densities, the chemical shift is 5 − 13 ppm higher than at the static equilibrium position. Inside narrow CNTs, the chemical shift increases nearly linearly with temperature, whereas inside wider tubes and on the outer surface of a CNT, it exhibits nonlinear and decreasing trends at high temperatures. Interactions with other xenon atoms induce a strong positive density dependence of Xe shift that modifies the temperature behaviour, producing a systematic increase in the chemical shift but also suppressing the simple linear temperature dependence observed at low densities inside CNTs. Molecular dynamics simulation reveals that inclusion of CNT motion increases chemical shifts inside a nanotube by 20–30 ppm. At high densities, the adsorption on the groove site results in a rise of chemical shift distribution around the 200 ppm range. These simulations provide microscopic insight into how structural, thermal, and interaction-driven effects govern xenon NMR responses in carbon nanotube environments, and therefore provide guidance for interpreting experimental observations across a range of temperatures and densities. • Temperature and density modulate 129 Xe NMR shifts in CNTs; at low density, thermal effects add 5–13 ppm, and temperature dependence is linear inside CNTs. • Inside CNTs, the 129 Xe chemical shift is small, even negative inside diamagnetic environment of chiral tubes, and increases with density. • Outside the CNT bundles, adsorption to the groove site yields high, ∼ 200 ppm, 129 Xe chemical shifts. • For Xe inside the CNT, nanotube motion raises 129 Xe chemical shift by 20–30 ppm.

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Cite This Study

Jacklin et al. (Sun,) studied this question.

synapsesocial.com/papers/699fe37b95ddcd3a253e757c https://doi.org/https://doi.org/10.1016/j.micromeso.2026.114092

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