Suitable boron-doped graphene substrate for glucose Raman signal enhancement
Suitable boron-doped graphene substrate for glucose Raman signal enhancement
Surface-enhanced Raman spectroscopy (SERS) is a highly sensitive and selective technique. It greatly enhances the signal of an analyte compared to classical Raman spectroscopy, due to analyte–substrate interactions. A promising substrate for SERS is boron-doped graphene (B-graphene). At low boron concentrations of ∼1.39 at.%, it has been shown to enhance the Raman signal of simple organic molecules such as pyridine. The potential use of high-concentration B-graphene materials for SERS remains unexplored. Therefore, in our study, we investigate the influence of dopant concentration and relative adsorbate/substrate geometry on the effectiveness of B-graphene as a SERS substrate, with glucose as the analyte. We perform Density Functional Theory simulations using the PBE functional and the DFT-D2 van der Waals correction. By combining analysis of interatomic force constants and phonon eigenvector composition, we conclude that higher doping concentrations provide a larger enhancement to the Raman signal of glucose, while the molecule’s orientation relative to the surface plays a fundamental role in the Raman response. We suggest that 12.5 at.% B-graphene represents a potential substrate for SERS-based detection of glucose. Additionally, the phonon-based analysis can be promptly applied in the search for promising substrate materials for enhanced Raman response.
Komeda, Jan
a369ffd1-3066-4b7c-8dae-4ecf78057700
Cammarata, Antonio
d9f02172-7364-4d80-a32b-03d2d7970257
Polcar, Tomas
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
16 October 2025
Komeda, Jan
a369ffd1-3066-4b7c-8dae-4ecf78057700
Cammarata, Antonio
d9f02172-7364-4d80-a32b-03d2d7970257
Polcar, Tomas
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Komeda, Jan, Cammarata, Antonio and Polcar, Tomas
(2025)
Suitable boron-doped graphene substrate for glucose Raman signal enhancement.
Applied Surface Science Advances, 30, [100875].
(doi:10.1016/j.apsadv.2025.100875).
Abstract
Surface-enhanced Raman spectroscopy (SERS) is a highly sensitive and selective technique. It greatly enhances the signal of an analyte compared to classical Raman spectroscopy, due to analyte–substrate interactions. A promising substrate for SERS is boron-doped graphene (B-graphene). At low boron concentrations of ∼1.39 at.%, it has been shown to enhance the Raman signal of simple organic molecules such as pyridine. The potential use of high-concentration B-graphene materials for SERS remains unexplored. Therefore, in our study, we investigate the influence of dopant concentration and relative adsorbate/substrate geometry on the effectiveness of B-graphene as a SERS substrate, with glucose as the analyte. We perform Density Functional Theory simulations using the PBE functional and the DFT-D2 van der Waals correction. By combining analysis of interatomic force constants and phonon eigenvector composition, we conclude that higher doping concentrations provide a larger enhancement to the Raman signal of glucose, while the molecule’s orientation relative to the surface plays a fundamental role in the Raman response. We suggest that 12.5 at.% B-graphene represents a potential substrate for SERS-based detection of glucose. Additionally, the phonon-based analysis can be promptly applied in the search for promising substrate materials for enhanced Raman response.
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Accepted/In Press date: 9 October 2025
e-pub ahead of print date: 16 October 2025
Published date: 16 October 2025
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Local EPrints ID: 511066
URI: http://eprints.soton.ac.uk/id/eprint/511066
PURE UUID: 7ff7994c-f292-4505-bfdd-979c6fbb2b26
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Date deposited: 30 Apr 2026 16:48
Last modified: 01 May 2026 01:49
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Author:
Jan Komeda
Author:
Antonio Cammarata
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