Understanding water behaviour on 2D material interfaces through single-molecule motion on h-BN and graphene
Understanding water behaviour on 2D material interfaces through single-molecule motion on h-BN and graphene
Understanding water behaviour on 2D materials is crucial for applications in sensing, microfluidics, and tribology. While graphene-water interactions are well studied, water on hexagonal boron nitride (h-BN) remains largely unexplored. Despite its structural similarity to graphene, h-BN possesses polar B-N bonds that give rise to distinct electronic and chemical properties. Most previous studies have also focused on multilayer water, leaving single-molecule dynamics poorly understood. Here we show how individual water molecules diffuse on h-BN compared to graphene using helium spin-echo spectroscopy and ab initio calculations. On h-BN/Ni, water exhibits coupled rotational-translational motion, in contrast to the discrete hopping observed on graphene. Water molecules rotate freely around their centre of mass, and although binding energies are similar on both materials, the activation energy for water dynamics on h-BN is 2.5 times lower than on graphene. These dynamics, which classical models fail to capture, highlight the fundamentally different nature of water transport on polar 2D surfaces. We further demonstrate that the supporting substrate strongly influences water friction, with h-BN/Ni showing markedly lower friction than graphene/Ni, opposite to the behaviour of free-standing layers. These findings challenge assumptions and offer insights for designing microfluidic devices requiring precise control of water mobility.
Seiler, Phillip
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Payne, Anthony J.R.
e5d2f7ff-2710-4c72-98f2-1fe570830979
Xavier, Neubi F.
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Slocombe, Louie
82bb3cea-f6d9-4f6c-8ea3-7730ef93de28
Sacchi, Marco
224e05e2-e57c-42bc-8bbe-a56dd745e2bd
Tamtögl, Anton
37946809-d7df-4274-8f0a-8adf4891c6b9
25 November 2025
Seiler, Phillip
bb7f9ac9-8a9b-4efb-8de9-1824c8b7964a
Payne, Anthony J.R.
e5d2f7ff-2710-4c72-98f2-1fe570830979
Xavier, Neubi F.
3111b8b0-fc09-4742-a951-fd1939b70aef
Slocombe, Louie
82bb3cea-f6d9-4f6c-8ea3-7730ef93de28
Sacchi, Marco
224e05e2-e57c-42bc-8bbe-a56dd745e2bd
Tamtögl, Anton
37946809-d7df-4274-8f0a-8adf4891c6b9
Seiler, Phillip, Payne, Anthony J.R., Xavier, Neubi F., Slocombe, Louie, Sacchi, Marco and Tamtögl, Anton
(2025)
Understanding water behaviour on 2D material interfaces through single-molecule motion on h-BN and graphene.
Nature Communications, 16 (1), [10465].
(doi:10.1038/s41467-025-65452-1).
Abstract
Understanding water behaviour on 2D materials is crucial for applications in sensing, microfluidics, and tribology. While graphene-water interactions are well studied, water on hexagonal boron nitride (h-BN) remains largely unexplored. Despite its structural similarity to graphene, h-BN possesses polar B-N bonds that give rise to distinct electronic and chemical properties. Most previous studies have also focused on multilayer water, leaving single-molecule dynamics poorly understood. Here we show how individual water molecules diffuse on h-BN compared to graphene using helium spin-echo spectroscopy and ab initio calculations. On h-BN/Ni, water exhibits coupled rotational-translational motion, in contrast to the discrete hopping observed on graphene. Water molecules rotate freely around their centre of mass, and although binding energies are similar on both materials, the activation energy for water dynamics on h-BN is 2.5 times lower than on graphene. These dynamics, which classical models fail to capture, highlight the fundamentally different nature of water transport on polar 2D surfaces. We further demonstrate that the supporting substrate strongly influences water friction, with h-BN/Ni showing markedly lower friction than graphene/Ni, opposite to the behaviour of free-standing layers. These findings challenge assumptions and offer insights for designing microfluidic devices requiring precise control of water mobility.
Text
s41467-025-65452-1
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Accepted/In Press date: 14 October 2025
e-pub ahead of print date: 25 November 2025
Published date: 25 November 2025
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Local EPrints ID: 508272
URI: http://eprints.soton.ac.uk/id/eprint/508272
ISSN: 2041-1723
PURE UUID: c60b76fc-f1e6-4497-a6ba-8cbc6ed9fa98
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Date deposited: 15 Jan 2026 18:07
Last modified: 16 Jan 2026 03:11
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Author:
Phillip Seiler
Author:
Anthony J.R. Payne
Author:
Neubi F. Xavier
Author:
Louie Slocombe
Author:
Marco Sacchi
Author:
Anton Tamtögl
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