Briefing: Microscopic study into biodeterioration of joint sealant

Peter Hughes; Don Fairhurst; Ian Sherrington; Nathalie Renevier; Glyn Morton; Peter C. Robery; Lee Cunningham

doi:10.1680/coma.12.00032

Briefing: Microscopic study into biodeterioration of joint sealant

Peter Hughes, Don Fairhurst, Ian Sherrington, Nathalie Renevier, Glyn Morton, Peter C. Robery, Lee Cunningham

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

Abstract

This research presents an exploratory study into the biodeterioration of joint sealants used in concrete coastal structures. Monocular, inverted-light microscopy and scanning electron microscopy with an energy dispersive X-ray analyser were used to observe colonisation of site specimens, enabling the further understanding of this interaction. Algal filaments have been observed growing within the matrix of a polymer sealant. Growth has been observed tunnelling within and adhered to the surface of the sealant. This degradation mechanism will weaken the material bond as a direct result of the physical activity of an organism, resulting from its growth. Loss of material, either through biodeterioration or through other mechanical means, such as tidal action, is not the primary cause of degradation, but it should be considered with associated environmental conditions, to exacerbate the condition.

Original language	English
Pages (from-to)	265-268
Number of pages	3
Journal	Proceedings of Institution of Civil Engineers: Construction Materials
Volume	166
Issue number	5
DOIs	https://doi.org/10.1680/coma.12.00032
Publication status	Published - Oct 2013

Keywords

Maritime engineering
Sea defences
Site investigation

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10.1680/coma.12.00032

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title = "Briefing: Microscopic study into biodeterioration of joint sealant",

abstract = "This research presents an exploratory study into the biodeterioration of joint sealants used in concrete coastal structures. Monocular, inverted-light microscopy and scanning electron microscopy with an energy dispersive X-ray analyser were used to observe colonisation of site specimens, enabling the further understanding of this interaction. Algal filaments have been observed growing within the matrix of a polymer sealant. Growth has been observed tunnelling within and adhered to the surface of the sealant. This degradation mechanism will weaken the material bond as a direct result of the physical activity of an organism, resulting from its growth. Loss of material, either through biodeterioration or through other mechanical means, such as tidal action, is not the primary cause of degradation, but it should be considered with associated environmental conditions, to exacerbate the condition.",

keywords = "Maritime engineering, Sea defences, Site investigation",

author = "Peter Hughes and Don Fairhurst and Ian Sherrington and Nathalie Renevier and Glyn Morton and Robery, {Peter C.} and Lee Cunningham",

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doi = "10.1680/coma.12.00032",

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AU - Hughes, Peter

AU - Fairhurst, Don

AU - Sherrington, Ian

AU - Renevier, Nathalie

AU - Morton, Glyn

AU - Robery, Peter C.

AU - Cunningham, Lee

PY - 2013/10

Y1 - 2013/10

N2 - This research presents an exploratory study into the biodeterioration of joint sealants used in concrete coastal structures. Monocular, inverted-light microscopy and scanning electron microscopy with an energy dispersive X-ray analyser were used to observe colonisation of site specimens, enabling the further understanding of this interaction. Algal filaments have been observed growing within the matrix of a polymer sealant. Growth has been observed tunnelling within and adhered to the surface of the sealant. This degradation mechanism will weaken the material bond as a direct result of the physical activity of an organism, resulting from its growth. Loss of material, either through biodeterioration or through other mechanical means, such as tidal action, is not the primary cause of degradation, but it should be considered with associated environmental conditions, to exacerbate the condition.

AB - This research presents an exploratory study into the biodeterioration of joint sealants used in concrete coastal structures. Monocular, inverted-light microscopy and scanning electron microscopy with an energy dispersive X-ray analyser were used to observe colonisation of site specimens, enabling the further understanding of this interaction. Algal filaments have been observed growing within the matrix of a polymer sealant. Growth has been observed tunnelling within and adhered to the surface of the sealant. This degradation mechanism will weaken the material bond as a direct result of the physical activity of an organism, resulting from its growth. Loss of material, either through biodeterioration or through other mechanical means, such as tidal action, is not the primary cause of degradation, but it should be considered with associated environmental conditions, to exacerbate the condition.

KW - Maritime engineering

KW - Sea defences

KW - Site investigation

U2 - 10.1680/coma.12.00032

DO - 10.1680/coma.12.00032

M3 - Article

SN - 1747-6518

VL - 166

SP - 265

EP - 268

JO - Proceedings of Institution of Civil Engineers: Construction Materials

JF - Proceedings of Institution of Civil Engineers: Construction Materials

IS - 5

ER -

Briefing: Microscopic study into biodeterioration of joint sealant

Abstract

Keywords

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