Corrosion Behavior Of Steel Bars Research Articles

Corrosion behavior of steel bar in magnesium oxysulfide cement-based materials: The role of chloride and nitrite

Magnesium oxysulfide (MOS) cement has emerged as a promising cementitious material due to the high strength and excellent durability, but research on its rust inhibition remains limited. In this study, the chloride and nitrite were introduced in the MOS cement composites, aiming to investigate the corrosion properties and reveal the rust inhibition mechanism of steel bar under different W/C ratio. Experimental results show that the corrosion area ratios reach the largest value of approximately 98% and the lowest value of approximately 3%, respectively, as the chloride and nitrite contents increase to 2%. Compared with chloride, the effect of W/C ratio on the mass loss of steel bar is gradually weakened when the nitrite content is larger than 0.5%. Based on the natural potential, the change of corrosion degree mainly occurs after 28d. In addition, the corrosion potential of steel bar decreases and corrosion rate increases with the increase of chloride content in MOS cement composites. Conversely, the presence of Mg(NO2)2 from nitrite engenders an opposite effect. Besides, the increase of W/C ratio results in higher electrochemical parameters. At this time, the rust inhibition mechanism is revealed based on the micro-structure analysis.

Evaluation of combined addition of nitrite and chloride on the corrosion behavior of steel bars in modified magnesium oxysulfate cement paste

Magnesium oxysulfate (MOS) cement, a new breed of eco-friendly and carbon-efficient material, boasts exceptional corrosion resistance, especially in harsh environments such as high salt and high humidity. Understanding how it affects the corrosion of steel bars is crucial for its widespread application in coastal concrete engineering. Nitrite-based inhibitors are known for their rust-preventing qualities in cementitious materials. However, more research is needed to determine if nitrite remains effective in MOS cement mixed with chloride salts. This study focuses on the combined effect of chloride and nitrite salts on the corrosion of steel bars in MOS cement. Methods like corrosion area rate, weight loss rate, natural potential, and electrochemical station are employed to study the corrosion behavior of steel in MOS cement. Microscopic techniques help unravel the influence mechanism of phase composition and microstructure on these materials. Furthermore, the study examines how chloride and nitrite contents affect the concentration of free nitrite and chloride ions in MOS cement paste. The analysis model is also established to compare simple linear adsorption, Langmuir adsorption, and Freundlich adsorption. The results indicate that chloride accelerates steel corrosion, while nitrite slows it down in the environment of mixed chloride and nitrite. In low-chloride environments, nitrite content has minimal impact on steel corrosion, but its effect becomes more pronounced in high-chloride settings. The MOS cement mixed with chloride and nitrite primarily consists of Mg(OH)2, MgCl2, MgCO3, MgO, and the 5Mg(OH)2·MgSO4·7 H2O (517 phase). The phase content of passive film on the surface of steel bar is composed primarily of Fe2O3, FeO, Fe, and FeOOH in descending order. As nitrite content increases, the absorption and concentration of free nitrite ions in the MOS cement paste gradually rise, exhibiting a linear trend. Based on the fitting calculations for three distinct adsorption relationships, notably, due to the limited adsorption capacity of MOS cement for nitrite, there's a considerable difference between the simple linear adsorption relationship and the two nonlinear adsorption models in high nitrite environments. However, in low nitrite concentrations, the difference among these three fitting adsorption relationships is little. This research can provide theoretical basis for enhancing the corrosion resistance and durability of coastal concrete engineering with high chloride exposure.

Inhibition resistance and mechanism of migrating corrosion inhibitor on reinforced concrete under coupled carbonation and chloride attack

Corrosion of steel bars in the marine environment is an important reason to reduce the service life of reinforced concrete structures. In this study, an amino alcohol migrating corrosion inhibitor (MCI) was coated on the concrete surface, which was then subjected to a simulated marine atmospheric environment by carbonation and salt spraying. The carbonation depth, chloride concentration of concrete, electrochemical performance of steel bars and mass loss rate of steel bar were determined to evaluate the corrosion inhibition performance of MCI. NELD-BS610 hardened concrete bubble spacing coefficient analyzer and scanning electron microscopy (SEM) were applied to analyze the pore structure parameters in concrete and the corrosion behavior of steel bar, respectively. The test results showed that MCI could alleviate the deterioration of concrete induced by accelerated carbonation and chloride attack, and delay the carbonation effect. After 7 days of accelerated carbonation and 35 days of chloride attack, the carbonation depth and chloride concentration of concrete coated with MCI were 16.07% and 16.93% lower than those of concrete uncoated with MCI, respectively. MCI could migrate to the steel bar surface of steel bar to form a protective film, significantly improving the electrochemical performance of the steel bar, and the inhibition efficiency of MCI was about 66.07 ∼ 97.91%. Besides, MCI could also reduce the mass loss rate of steel bars and porosity of concrete induced by carbonation and chloride attack. For the specimens coated with MCI, the mass loss rates of steel bar decreased by 20.31 ∼ 39.78%, and pores with sizes of 1.0 ∼ 0.2 μm in concrete reduced by 59.10 ∼ 76.38%. The results of this research are purposeful for alleviating the corrosion damage problems of reinforced concrete in marine areas.

Compressive strength and corrosion behavior of steel bars embedded in concrete produced with ferronickel slag aggregate and fly ash: an experimental study

Compressive strength and corrosion behavior of steel bars embedded in concrete produced with ferronickel slag aggregate and fly ash: an experimental study

The Constituent Phases and Micromechanical Properties of Steel Corrosion Layers Generated by Hyperbaric-Oxygen Accelerated Corrosion Test.

Hyperbaric oxygen-accelerated corrosion testing (HOACT) is a newly developed method to study in the labor the corrosion behavior of steel bars in concrete. This work aimed to intensively investigate the mechanical properties and microstructures of HOACT-generated corrosion products by means of nano-indentation tests, Raman micro-spectrometry, and scanning electron microscopy. The local elastic modulus and nanohardness varied over wide ranges of 6.8-75.2 GPa and 0.38-4.44 GPa, respectively. Goethite, lepidocrocite, maghemite, magnetite, and akageneite phases were identified in the corrosion products. Most regions of the rust layer were composed of a complex and heterogeneous mix of different phases, while some regions were composed of maghemite or akageneite only. The relationship between the micromechanical properties and typical microstructural features is finally discussed at the micro-scale level. It was found that the porosity of corrosion products can significantly influence their micromechanical properties.

EIS Investigation of the Corrosion Behavior of Steel Bars Embedded into Modified Concretes with Eggshell Contents

This investigation is focused on evaluation of the corrosion behavior of embedded steel bars (SB) into concretes. Conventional and modified concretes with eggshell are prepared. Although the effect of calcium carbonate on mechanical behavior is recognized and reported, their effects as eggshell (ES) particles replacing portions of sand and cement contents are reasonably scarce. Corrosion behavior is evaluated by electrochemical impedance spectroscopy (EIS) and the potentiodynamic polarization technique. Equivalent circuit and porous electrode behavior are also considered. The novelty concerns a promising use of concrete with ES content to maintain corrosion resistance concatenated with reasonable structural properties. For this purpose, three distinct concrete mixtures are proposed, i.e., a reference and two modified concretes. One replaces 10 wt.% with cement and another 10 wt.% with sand content. It is found that porous electrode behavior helps to predict the corrosion mechanism. Finer ES particles in concrete mixture provides a rapidly passivation on rebar. This reflects positively in corrosion current density after long-term immersion. Additionally, an environmentally friendly aspect associated with economical factor constitutes a promise use of the concrete.

Electrochemical and microscopic analysis on corrosion behavior of steel bars in slag/fly ash-cement paste subjected to seawater attack

A series of corrosion experiments of cement paste-steel bar specimens with different contents of slag and fly ash were performed to investigate the influence of slag/fly ash on the corrosion behavior of steel bars in concrete under seawater. In this investigation, the corrosion behavior of specimen was electrochemically monitored by open-circuit potential (OCP), Tafel polarization (TP) and electro chemical impedance spectra (EIS). Meanwhile, SEM/EDS and XRD were applied to microscopically analyze the microstructure deterioration of materials. Results showed that, replacing cement with slag/fly ash caused a decrease in Ca(OH)2 as well as an increase in C-S-H gel and Friedel's salt in concrete, which can improve the chloride-solidification ability and slow down the chloride diffusion in concrete by both physical adsorption and chemical binding, and thereafter promoting the corrosion resistance of steel bars in concrete in marine environment. Compared to slag, the equal replacing content of fly ash can contribute to a better improving effect on the corrosion resistance of reinforced concrete in marine environment. In this study, a replacement of cement by 20% slag+20% fly ash led to an optimum improving effect on its corrosion resistance. In addition, the results also indicate that the corrosion of reinforced concrete caused by seawater attack does not occur at a uniform rate, but it can firstly maintain a long-term uncorroded state, and then develops rapidly after pitting corrosion occurs.

Experimental study on multi-component corrosion inhibitor for steel bar in chloride environment

This paper investigates one type of multi-component corrosion inhibitor for steel bars in chloride environment. Triethanolamine (TEA), tri-isopropanolamine (TIPA), sodium monofluorophos-phate (MFP) and sodium molybdate (T-4) were proportioned to prepare this multi-component corrosion inhibitor. Corrosion behavior of steel bar was evaluated using the polarization curve, electrochemical impedance spectroscopy (EIS) and scanning electron microscopy (SEM). The polarization curves were fitted using the adsorption isotherm models. Experimental results indicated that the steel bar corrosion in chloride solution can be reduced by the addition of either organic or inorganic corrosion inhibitors. This is attributed to the fact that organic corrosion inhibitor can form an adsorption film on the steel bar surface and inorganic corrosion inhibitor abates electrochemical reaction of steel bars. Compared to single component corrosion inhibitors, the corrosion rate of steel bars in simulated pore solution was significantly restrained by the multi-component corrosion inhibitor. The adsorption of multi-component corrosion inhibitor on the surface of steel bar can significantly reinforce the passive film by means of physical (organic) or chemical (inorganic) process. For all the investigated corrosion inhibitors, the adsorption isotherms were in good agreement with experimental results. The EIS result and equivalent electrochemical circuit confirmed the chemical reaction and physical adsorption process of the multi-component corrosion inhibitor. Therefore, the chloride induced corrosion of steel bars can be effectively controlled by the multi-component corrosion inhibitor.

Corrosion behavior of steel bar embedded in high-ductility cementitious composites under the coupled action of dry–wet cycles and chloride attack

Purpose High-ductility cementitious composites (HDCC) have an excellent crack controlled capacity and corrosion resistance capacity, which has a promising application in structure engineering under harsh environment. The purpose of this study is to explore the corrosion mechanism of steel bar in HDCC. Design/methodology/approach Intact and the pre-cracked HDCC specimens under the coupled action of different dry–wet cycles and chloride attack were designed, and intact normal concrete (NC) was also considered for comparison. Corrosion behavior of a steel bar embedded in HDCC was analyzed by an electrochemical method, a chloride permeability test and X-ray computed tomography. Findings Steel corrosion probability is related to the chloride permeability of the HDCC cover, and the chloride permeability resistance of HDCC is better than that of NC. Besides, crack is the key factor affecting the corrosion of steel bars, and the HDCC with narrower cracks have a lower corrosion rate. Slight pitting occurs at the crack tips. In addition, the self-healing products and corrosion products fill up the cracks in HDCC, preventing the external aggressive ions from entering and thereby decreasing the steel corrosion rate. Originality/value HDCC has a superior corrosion resistance than that of NC, effects of variable crack width on corrosion behavior of steel bar in HDCC under the coupled actions of different dry–wet cycles and chloride attack are investigated, which can provide the guide for the design application of HDCC material in structure engineering exposed to marine environment.

Investigation on the Corrosion Behavior of Steel Embedded in Basic Magnesium Sulfate Cement Concrete: An Attempt and Challenges.

Basic magnesium sulfate cement is a type of green high-performance cementitious material. In order to exert its performance advantages and expand its application field, it is urgent to study the problem of steel corrosion in basic magnesium sulfate cement concrete (BMSCC). In this paper, linear polarization resistance (LPR) and electrochemical impedance spectroscopy (EIS) were used to study the corrosion behavior of steel bars in different strength grades of BMSCC in seawater. Based on the relationship between the corrosion current density and the immersion time, the corresponding time-varying model was obtained. The LPR and EIS results show that the corrosion potential and polarization resistance of steel bars in BMSCC decreased with the immersion time in the seawater environment. The fitting analysis indicated concordance between the corrosion rates with the logarithmic function time-varying model. Furthermore, the cracking time of the protective layer of BMSCC was analyzed based on the cracking time prediction model of Portland cement concrete and the mechanical properties of BMSCC.

Influence of SAP on the chloride penetration and corrosion behavior of steel bar in concrete

The steel corrosion induced by chloride penetration is a great threaten to concrete structures, in particular exposed to marine environments. Super absorbent polymer (SAP), as a water reservoir, is probably conducive to reinforced concrete suffered from steel corrosion in marine environments. Therefore, the influence of SAP on the chloride penetration and corrosion behavior of steel in concrete were investigated using concrete mixed with 0∼2 kg/m3 SAP. The results indicate that the permeability and chloride diffusion coefficient consistently rise up with increasing with SAP dosage. Furthermore, the higher SAP dosage results in an ascending free chloride content when subjected to tidal zone. However, when exposed to atmosphere zone, the effect of SAP can be neglected. Moreover, the corrosion current of the sample with SAP are larger than that without SAP, while more corrosion products can be observed in the sample with SAP. Since the stress and strain applied on concrete and internal steel bar of specimens with SAP are apparently smaller, the propagation of crack caused by steel corrosion is probably postponed. Thus, it can be roughly concluded that for concrete subjected to marine environment, adding SAP to concrete can delay the failure process of reinforced concrete to some extent and an optimized dosage of SAP is suggested to be 1 kg/m3.

Electrochemical investigation on the influence of sulfates on chloride-induced corrosion of steel bar in cement-based materials

The combined action of chloride and sulfate attacks is an important durability problem for RC structures long-termly dwelled in marine environment. This paper experimentally investigates the influence of sulfates on chloride-induced corrosion of steel bar in cement-based materials by accelerated corrosion experiment, in which some steel bar-mortar (SM) specimens were immersed in chloride-only (15% NaCl) and combined chloride-sulfate solutions (15% NaCl + 5% Na2SO4, 15% NaCl + 10% Na2SO4). Electrochemical measurements, like OCP, TP and EIS, were used to analyze the corrosion behavior of SM specimens immersed in the solutions. Results showed that sulfates play a significant role in accelerating the time at which the initial corrosion of steel bar in concrete begins. In 15% NaCl solutions containing 0%, 5% and 10% Na2SO4, the initial corrosion of steel bar occurred after 360, 240 and 160 days of immersion, respectively. Electrochemical results from OPC, TP and EIS were in good agreement regarding the corrosion behavior of steel bar, and either of them can be used in determining the onset of corrosion of steel bar in concrete.

Effects of Transverse Crack on Chloride Ions Diffusion and Steel Bars Corrosion Behavior in Concrete under Electric Acceleration.

Cracks greatly impact the durability of concrete structures due to their influence on the migration of chloride ions and the corrosion process of steel bars. This study investigates the effects of transverse cracks on chloride diffusion and the corrosion behavior of two types of steel bars (low carbon steel and corrosion resistant steel) in fly ash concrete with 1 kg/m3 solution-polymerized super absorbent polymer. Electrochemical impedance spectroscopy was used to monitor the chloride-induced corrosion behavior of steel bars in concrete. The chloride profile around cracks was tested via chemical titration. The corrosion products diffusion area was photographed and measured to evaluate the influences of cracks on the corrosion degree of steel bars. Transverse cracks greatly influence the chloride ion transport. When their width is less than 0.15 mm, cracks exert little influence on both chloride diffusion and steel corrosion. When the crack width exceeds 0.15 mm, the chloride ion transmission coefficient is significantly improved and steel corrosion is accelerated. However, when the crack width exceeds 0.20 mm, this effect is gradually weakened. Based on the experimental data, a quantitative relationship between the crack width and the chloride ion transmission coefficient in electric acceleration was established.

Carbonation treatment of recycled concrete aggregate: Effect on transport properties and steel corrosion of recycled aggregate concrete

Old cement mortars attached on recycled concrete aggregates (RCA) seriously affects the durability of the recycled aggregate concrete (RAC). Revealing the variation of the transport properties of cement mortar after subjecting to accelerated carbonation treatment is crucial with respect to understanding the effects of carbonated RCA on the durability of RAC. In this paper, cement mortars were used to study the transport properties after they were treated by accelerated carbonation. The corrosion behavior of steel bars in the concrete incorporating the carbonated RCA was also evaluated. The experimental results indicated that the water absorption and sorptivity, resistance to chloride ion penetration, as well as the bulk electrical conductivity of the cement mortar was decreased after subjecting the accelerated carbonation treatment. Extending the treatment from 1 day to 7 days only resulted in a marginal improvement of the transport properties. A significant decrease in the local porosity at the edge of cement mortar determined by Scanning electron microscopy-backscattered image was observed, agreeing well with the concentrated calcium carbonate (CC) contents detected in the surface layer by TGA. The determination of the spatial gradients of the porosity and carbonates/portlandite contents illustrated that even only with the external layer (0–10 mm) carbonated, a considerable improvement of transport properties of the cement mortar could still be achieved. The corrosion test in the new concrete prepared with the carbonated RCA also confirmed that the corrosion resistance of steel bars in the RAC was improved.

Influence of Chloride Ions on Corrosion Behavior of Steel Bars in a Simulated Concrete Pore Solution

Influence of Chloride Ions on Corrosion Behavior of Steel Bars in a Simulated Concrete Pore Solution

Monitoring Steel Bar Corrosion in 3.5 Wt.% NaCl Solution Using a Fiber Optic Corrosion Sensor

In this study, a Fe-C coated LPFG corrosion sensor was employed to monitor corrosion of steel bar in 3.5 wt.% NaCl solution. This corrosion sensor was coated with an inner silver layer and an outer layer of Fe-C coating. The inner silver was sputter coated with a thickness of 800 nm, and the outer Fe-C layer was electroplated with a thickness of 20 µm. A steel bar was cut, prepared and tested in 3.5 wt.% NaCl solution, together with the fiber optic corrosion sensor. The corrosion evolution of both the outer layer of Fe-C coating and the steel bar were investigated with electrochemical impedance spectroscopy (EIS), and the change in the transmitted spectrum of the Fe-C coated LPFG was recorded with an optical sensing interrogator. EIS results showed that the corrosion behavior of steel bar remained stable throughout the whole test period, while the corrosion resistance of Fe-C layer gradually increased with time. Due to the limitation of interaction range between the coating layer and the light propagating in the fiber as well as the coating thickness, this fiber optic corrosion sensor can only monitor the corrosion of steel bar for 18 hours in 3.5 wt% NaCl solution.

Monitoring Steel Bar Corrosion in 3.5 Wt.% NaCl Solution Using a Fiber Optic Corrosion Sensor

Reinforcement steel in concrete structures is initially protected by a passive film formed due to the alkaline concrete pore solution, which contains hydroxyl ions released from cement hydration. This protective film may be destroyed due to neutralization of the concrete pore solution or penetration of aggressive chemicals such as chloride from de-icing salt or marine environments. Breakdown of passive film causes initiation of corrosion that is followed by corrosion propagation, and over time results in cracking of concrete cover, reduction of mechanical properties of steel bar, bond loss between steel and concrete, as well as reduction of carrying capacity of concrete structural members and systems. According to a NACE report released in 2002, the annual direct corrosion cost for replacement and maintenance of highway bridges in the U.S. was estimated $13.6 billion [1]. The indirect cost due to traffic delay or loss of productivity during the replacement or maintenance period is ten times higher than the direct cost. Moreover, steel corrosion in concrete structures is also a potential threat for human life if structures collapse when the key members are subjected to corrosion attack. A lot of methods or techniques have been proposed or developed to monitor corrosion of reinforcement steel in concrete structures, which can be broadly divided into two categories: electrochemical and non-electrochemical. Electrochemical methods include half-cell potential measurements, electrochemical noise, electrochemical impedance, linear polarization resistance and solid embeddable reference electrodes. Non-electrochemical methods use techniques such as acoustic emission, ultrasonic wave, piezoelectric transducer, ground penetration radar, and optical fiber. Use of optic fiber to monitor steel corrosion in concrete structures have many advantages compared with conventional methods, such as small size, immunity to electromagnetic interference, high precision and sensitivity, capability of multiplexing in large sensor networks. In our previous study, an optical fiber corrosion sensor was proposed based on the sensing principle of long period grating [2], and its mechanism and sensitivity was characterized in 3.5 wt.% NaCl solution [3]. However, the effectiveness of this corrosion sensor to monitor corrosion evolution of reinforcement steel has not been investigated yet. In this study, the corrosion sensor was employed to monitor corrosion behavior of steel bar in 3.5 wt.% NaCl solution, and its correlation with corrosion evolution of steel bar and its effective service life were studied experimentally. This fiber optic corrosion sensor was coated with an inner layer of silver and an outer layer of Fe-C coating. The inner silver was sputtered coated with a thickness of 800 nm, and the outer Fe-C coating was electroplated with a thickness of 20 um. A small piece of steel bar was cut, prepared and tested in 3.5 wt.% NaCl solution, together with the fiber optic corrosion sensor. The corrosion behavior of both the outer Fe-C layer and the steel bar was investigated with electrochemical impedance spectroscopy (EIS), and the change in the light spectrum was recorded with an optical sensing interrogator. EIS results showed that the corrosion behavior of steel bar remained stable throughout the whole test period, while the corrosion resistance of Fe-C layer gradually decreased with time. Due to the limitation of interaction range between the coating layer and the light propagating in the fiber as well as the coating thickness, this fiber optic corrosion sensor can only monitor the corrosion of steel bar for 18 hours in 3.5 wt.% NaCl solution. P.H. Koch, N.G. Brongers, Y.P. Thompson, “Corrosion Costs and Preventive Strategies in the United States”, NACE International Houston, TX, USA, 2002 Publication No. FHWA-RD-01–156.Chen, F. Tang, Y. Bao, Y. Tang, G. Chen, “A Fe-C Coated Long-Period Fiber Grating Sensor for Corrosion-Induced Mass Loss Measurement”, Optics Letters, Vol. 41, pp 2306-2309, 2016.Chen, F. Tang, Y. Tang, M. J. O’Keefe, G. Chen, “Mechanism and Sensitivity of Fe-C Coated Long Period Fiber Grating Sensors for Steel Corrosion Monitoring of RC Structures”, Corrosion Science, Vol. 127, pp 70-81, 2017.

Corrosion behavior of steel reinforcement bars embedded in concrete exposed to chlorides: Effect of surface finish

The corrosion behavior of steel bars with different surface finish (ordinary (CS), dual phase (TTS) and galvanized (GS)) was studied in the laboratory using prismatic concrete specimens with two water/cement (w/c) ratios: 0.45 and 0.65. The specimens were exposed to penetration of chlorides using wetting and drying cycles for 2.6years. The evolution with time of corrosion potential (Ecorr) and polarization resistance (Rp) was studied. Microhardness, microstructural, chloride content and visual inspections of steel bars were also assessed. It was found that the different steels bars exposed followed a same sequence in depassivation for both w/c ratios; i.e. in this order: CS, TTS and GS. During initiation stage, the corrosion current density for TTS was lower than CS, similar behavior was observed in propagation stage for steel bars in specimens with w/c ratio of 0.45. The zinc-based coating obtained by hot-dip galvanization increases the time to corrosion initiation for CS bar and the amount of chlorides needed for this to occur. For GS and TTS bars, localized damage was observed, which was more severe for the GS bar.

Corrosion behavior of steel bars immersed in simulated pore solutions of alkali-activated slag mortar

To study the corrosion behavior of steel bars in alkali-activated slag (AAS) system, simulated pore solutions of AAS mortar were first applied in this work. The effects of the three major species in AAS pore solutions, namely sulfur-containing species, aluminate, and silicate, were investigated. Electrochemical impedance spectroscopy and potentiodynamic polarization results showed that the simulated pore solution of AAS mortar had a stronger capacity to passivate and protect steel bars than the simulated pore solution of Portland cement (PC) mortar, mainly due to the higher concentration of silicate in the former, as confirmed by surface analysis of SEM-EDXS.

Corrosion Behavior of Steel Bar and Corrosive Cracking of Concrete Induced by Magnesium-Sulfate-Chloride Ions

The evolution of steel bar and corrosive-crack propagation of reinforced concrete in three different solutions including MgSO4, Mg2+-SO42--Cl-, and seawater were examined using electrochemical impedance spectroscopy. Results showed that seawater had the most serious corrosion effect on steel bar in concrete. MgSO4 combined with chloride ions could accelerate the damage process of passive film, whereas Mg(OH)(2) and gypsum particles could be produced and deposited on the steel-bar surface to block the diffusion of sulfate and chloride ions into the passive film. The crack propagation of concrete in single chloride environment increased with time linearly, but the existence of MgSO4 in chloride solution could change the crack-propagation behavior of reinforced concrete from linear to nonlinear. The existence of Ca(OH)(2) in MgSO4 and MgSO4-NaCl solutions could not delay the initial corrosion time but reduce the corrosion rate of steel bar by 60%-85%.