1. IntroductionMinistry of water re

1. Introduction
Ministry of water resources and irrigation (MWRI) has many large concrete structures projects in the Nile River, irrigation network, and drainage network as new structures or replacement to old ones. Most of the concrete structures in these projects are water structures such as bridges, regulators, barrages, culvers, siphons and aqueducts. Some parts of the concrete of mentioned water structures are embedded in soil contaminated with chlorides and sulfates while, the other parts are exposed to irrigation water or drainage water (immersion in water) which is contaminated with salts.

The two most common causes of reinforcement corrosion are (i) localized breakdown of the passive film on the steel by chloride ions and (ii) general breakdown of passivity by neutralization of the concrete, predominantly by reaction with atmospheric carbon dioxide (Batis and Rakanta, 2005). Sound concrete is an ideal environment for steel, but the increased use of deicing salts and the increased concentration of carbon dioxide in modern environments principally due to industrial pollution, has resulted in corrosion of the rebar becoming the primary cause of failure of this material.

Chloride ions penetrate through the concrete by a solution diffusion process and are dissolved in pre-existing pore water which is relevant to reinforcing steel corrosion through the following effects: (a) slightly reduce the alkalinity of concrete, (b) increase the electrical conductivity of concrete, and (c) depassivate the steel surface even at high alkaline environment. Chloride ions may enter easily into fresh concrete from the mix components, such as cement, aggregate, mixing water and chemical admixtures, or from chloride contaminates. The chloride ions may penetrate into hardened concrete from external sources such as: curing water, deicing salts, salt spray and sea water. Chloride ions may be present in concrete in several states (Ravindrarajah and Moses, 1993): (a) strongly bound by tricalcium aluminate hydrates (and to a lesser extent by tetracalcium alumino-ferrite hydrates) mainly in the form of calcium chloroaluminate, (b) loosely bound (immobilized by calcium silicate hydrates), and (c) free in solution (water-soluble) in the pore space. Furthermore, migration of chloride ions occurs primarily through diffusion processes and the arbitrary limits of diffusion coefficient fall in range of the order of 10−7 and 10−8 cm2/s (Luca et al., 2007).

Silica fume is a powder by-product resulting from the manufacture of ferrosilicon and silicon metal. It has a high content of glassy of silicon dioxide (SiO2) and consists of very small spherical particles. Because of this, it has been a popular mineral admixture to use in high-strength concrete (Anwar et al., 2013). However, silica fume is expensive compared to Portland cement type I or fly ash. Fly ash is a by-product of coal-burning power plants. It is widely used as a cementitious material and a pozzolanic ingredient in concrete. The use of fly ash in concrete is constantly increasing because it improves the properties of concrete (Xianming et al., 2012).

In recent years, high-strength concrete has increasingly been used in civil engineering work because it has an advantage of reducing the sizes of beams and columns, which are essential in high-rise buildings. According to ACI 363 (ACI, 2000), concrete having a 28 day compressive strength higher than 41 MPa can be considered as high-strength concrete. Generally, high-strength concrete is achieved by using super plasticizer to reduce the water–binder ratio and by using supplementary cementing materials such as silica fume, natural pozzolan, or fly ash in order to create extra strength by pozzolanic reaction. Furthermore, Shannag (2000) used natural pozzolan and silica fume to produce high strength concrete, and it was found that the combination of the two can be used in producing high-strength concrete in the range of 69–85 MPa at 28 days, with medium workability.

Portland cement is the essential binding agent in concrete, which in turn is the most widely used construction material worldwide due to its many advantages, including lower cost (relative to steel, aluminum or polymers), durability and other properties. Materials of natural origin such as volcanic ash, or industrial by-products, like ground granulated blast furnace slag and pulverized fly ash, have been widely used as partial replacement of Portland cement in concrete constructions. The advantages include improved technological properties, low cost and a reduction in the environmental impact through reduction of waste accumulation. Furthermore, the simple replacement of 5% of cement by one of the aforementioned materials can provide a reduction of about 75 × 106 tons of CO2 (considering a world production of about 1500 × 106 tons/year with emission of an average 1 kg CO2/kg cement) (Escalante-Garcia and Sharp, 2004).

Silica fume concrete has a high compressive strength, low permeability and good resistance to freeze–thaw cycling (Malhotra and Mehta, 1996). Similar performance enhancements have also been achieved for high volume fly ash and blast furnace slag concretes (Bilodeau et al., 1994). However research on the long-term effects of these supplementary materials on chloride ion diffusivity and corrosion of the reinforcing steel in concrete is limited and needs further investigation. The use of these materials in concrete not only improves the mechanical properties and durability but also uses industry by-products and has, therefore, significant environmental and economic benefits (Qian et al., 2003). One of the main characteristics of green high-performance concrete is using different types of mineral admixtures (fly ash, slag or silica fume) to partially replace Portland cement. When these different reactive mineral admixtures are added into concrete at the same time, they develop their own characteristics with the development of time, so that the physical, mechanical and durability properties of concrete will not be reduced when a large amount of mineral admixtures are added into concrete. For example, in the case of addition of silica fume, slag and fly ash at the same time, silica fume provides main strength amongst these three types of mineral admixtures before 7 days due to its highly early pozzolanic reaction, then, slag begins develop its strong pozzolanic effect. After 28 days, fly ash also gradually exhibits its own properties and provides its contributions to the strength of concrete (Wei et al., 2004).

Keith and Tarunjit (2013) indicated the benefits of fly ash concrete. They carried out a longer-term chloride ion permeability tests on samples of concrete containing 0, 15, 30, and 50% fly ash replacing cement. These tests conducted at the Ohio State University, USA. The chloride ion permeability of the fly ash mixes was significantly lower than that of the no fly ash mix, as they concluded. The permeability reduced with increase in percent of fly ash. Increase in curing time from 6 months to 1 year led to about 4.75% reduction in the permeability of the no fly ash mix, while the permeability of the fly ash mixes reduced 30–40% over the same time period. Even at one year of curing, the no fly ash concrete sample had moderate chloride ion penetrability while all the fly ash concrete samples had very low penetrability values. In addition they reported that the high-volume fly ash mixes would be the most durable concrete mixes for preventing corrosion in reinforced concrete structures.

This paper aims to investigate the influence of using ternary cementitious systems containing ordinary Portland cement, silica fume and fly ash on the chloride ion permeability of concrete. As well as, to assess the effect of the replacement percentage of cement by fly ash and silica fume on the properties of concrete.