The Effects of Ocean Salinity Variance due to Climate Change on Australian Seaport Infrastructure

Andrew Hunting; Sujeeva Setunge; Daniel Kong

doi:10.4028/www.scientific.net/AMM.438-439.157

Paper Titles

Experimental Study on Shrinkage of Concrete with Recycle Crushed Brick Coarse Aggregate
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Influence on Permeability and Mechanical Properties of Pervious Concrete by Aggregate Gradation
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A Simple Method of Coarse Aggregate Generation Based on PFC2d
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The Influence by the Method of Aggregate Enveloped with Cement of Multi-Step Mixing to Durability of High Performance Concrete
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The Effects of Ocean Salinity Variance due to Climate Change on Australian Seaport Infrastructure
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Evaluation on Compressive Strength and Workability of Green High-Performance Concrete by Grey Relational Grade
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Modelling Concrete Strength Using Support Vector Machines
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Study on Effect of Different Fine Aggregates on Properties of Dam Concrete
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Experimental Research on the Influence of Pebble Aggregate Gradation on Concrete Strength
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 438-439The Effects of Ocean Salinity Variance due to...

The Effects of Ocean Salinity Variance due to Climate Change on Australian Seaport Infrastructure

Abstract:

As the effects of climatic change become more evident and extreme, there is significant pressure being mounted onto port authorities and infrastructure stakeholders to ensure that their assets are resilient to the effects of a more aggressive and corrosive climate. Typically, the reinforcing steel within concrete which provides its flexural strength is protected from corrosion by both the alkalinity of the cement and the distance of cover from the chloride laden environment. However, studies are suggesting that as the hydrological cycle around the equator begins to accelerate, the salinity of the oceans at these lower latitudes (namely from 25°S to 25°N) will increase. As demonstrated through Ficks 2^nd Law of diffusion, there will then be an effect on the build-up of surface chlorides and thus, chloride ingress through the cement matrix to initiate corrosion. Through an extensive literature review of climatic forecasts, and both laboratory and in-field trials, this paper will numerically demonstrate the relationship between salinity concentration and surface chloride levels at varying temperatures. The results illustrate a strong positive relationship between the two parameters suggesting faster corrosion initiation, and more frequent operational downtime for stakeholders into the future. To fill this gap in knowledge, the surface chloride equations presented should be considered when design, maintenance, and retrofitting options are being considered for stakeholders within the affected locations.

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Periodical:

Applied Mechanics and Materials (Volumes 438-439)

Pages:

157-165

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.438-439.157

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Online since:

October 2013

Authors:

Andrew Hunting, Sujeeva Setunge, Daniel Kong

Keywords:

Chloride Ingress, Climate Change, Concrete, Hydrological Cycle, Salinity

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References

[1] J. Prascal, D. Jain, A. Ahuja, Factors influencing the sulphate resistance of cement, concrete, and motar, Asian Journal of Civil Engineering (Building and Housing), 3 (2006) 259-268.