2.1. Relationship between Stress and Microhardness

The following equation reveals that a substrate with a tensile stress develops a larger apparent contact area than the virgin material, when indented to the same load [14]:$$\begin{array}{}\text{(1)}& \frac{A_{\sigma }}{A_{\text{b}}}={\left(1-\frac{{\sigma }_{\text{h}}}{p_{\text{ave}}}\right)}^{-1}={\left(1-\frac{{\sigma }_{y,0}}{p_{\text{ave}}}\right)}^{-1},\end{array}$$where $A_{\sigma }$ is the apparent contact area for the substrate with a tensile stress, $A_{\text{b}}$ is the apparent contact area for the virgin material without any stress, ${\sigma }_{\text{h}}$ is the apparent tensile hydrostatic stress, which is equivalent to the equibiaxial tensile stress at the indented surface, σ_h = σ_x,0 = σ_y,0, and $p_{\text{ave}}$ refers to the average contact pressure, p_ave = P/A_b, P is the experimental load.

In the process of indentation experiment, $\mathrm{HV}=P/\left(g_{\text{n}}·A\right)$, that is, with the same load, the hardness ratio of any two indentation points is inversely proportional to the ratio of the indentation area. Therefore, the hardness ratio is also a measure of the apparent area ratio, i.e., the ratio of the apparent area of contact for the substrate with a stress to that for the virgin substrate at a fixed indentation load:$$\begin{array}{}\text{(2)}& \frac{{\text{HV}}_{\text{b}}}{{\text{HV}}_{\sigma }}=\frac{A_{\sigma }}{A_{\text{b}}}={\left\{1-\frac{{\sigma }_{y,\text{0}}}{p_{\text{ave}}}\right\}}^{-1}={\left\{1-\frac{{\sigma }_{y,0}}{P}\cdot A_{\text{b}}\right\}}^{-1}={\left\{1-\frac{{\sigma }_{y,\text{0}}}{g_{\text{n}}\cdot {\text{HV}}_{\text{b}}}\right\}}^{-1}.\end{array}$$

The stress field then can simply be written as$$\begin{array}{}\text{(3)}& {\sigma }_{y,\text{0}}=\left(\frac{{\text{HV}}_{\sigma }}{{\text{HV}}_{\text{b}}}-1\right)\cdot \frac{P}{A_{\text{b}}}=\left(\frac{{\text{HV}}_{\sigma }}{{\text{HV}}_{\text{b}}}-1\right)\cdot g_{\text{n}}\cdot {\text{HV}}_{\text{b}}=\Delta {\text{HV}}_{\sigma }\cdot g_{\text{n}},\text{(4)}& \Delta {\text{HV}}_{\sigma }={\sigma }_{y,\text{0}}/g_{\text{n}},\end{array}$$where $g_{\text{n}}$ is the normal acceleration of gravity, $g_{\text{n}}$ = 9.8 m/s², HV_b is the original hardness of stress-free area, HV_σ is the micro-hardness of stress area at any point, and ΔHV_σ is the micro-hardness increment of stress area at any point.

2.2. Theoretical Model of Hydrogen Concentration Distribution in the Stress Environment

In this study, the diffused hydrogen atoms tend to accumulate around the high-stress field, interfaces, and grain boundaries, leading to the main hydrogen damage that can be obtained by means of stress-induced diffusion, which is given by Dean [35]:$$\begin{array}{}\text{(5)}& c_{\sigma }=c_0\exp \left(\frac{\overline{V_{\text{H}}}\cdot {\sigma }_{\text{h}}}{R\cdot T}\right),\end{array}$$where c_σ is the hydrogen concentration when σ_h = σ, c₀ is the hydrogen concentration when σ_h = 0, $\overline{V_{\text{H}}}$ is the partial molar volume of hydrogen, σ_h is the hydrostatic stress, R is the gas constant, and T is the thermodynamic temperature of the test environment.

Since the increase in hydrogen concentration is proportional to the increase in hardness, the relative hydrogen concentration of σ_h = σ is$$\begin{array}{}\text{(6)}& \Delta {\text{HV}}_{{\text{c}}_{\sigma }}=\frac{c_{\sigma }}{c_0}\cdot \Delta {\text{HV}}_{{\text{c}}_{\text{0}}}=\Delta {\text{HV}}_{{\text{c}}_{\text{0}}}\exp \left(\frac{\overline{V_{\text{H}}}\cdot {\sigma }_{\text{h}}}{R\cdot T}\right),\end{array}$$where $\Delta {\text{HV}}_{{\text{c}}_{\sigma }}$ is the hydrogen-induced microhardness increment when σ_h = σ and $\Delta {\text{HV}}_{{\text{c}}_{\text{0}}}$ is the hydrogen-induced microhardness increment when σ_h = 0.

For a modified WOL specimen, the plane strain fields σ_e along the crack propagation direction in front of the crack tip can be obtained by the following equation:$$\begin{array}{}\text{(7)}& {\sigma }_{\text{e}}=\left\{\begin{array}{cc}{\sigma }_{\text{s}},& r\le r_0,\\ \frac{K_{\text{I}}}{Y\cdot \sqrt{2r}},& r>r_0,\end{array}\right.\end{array}$$where ${\sigma }_{\text{s}}$ is the yield stress of the metal and $K_{\text{I}}$ is the stress intensity factor, and the relationship between stress intensity factor $K_{\text{I}}$ and the crack length a for the WOL specimen can be calculated by$$\begin{array}{}\text{(8)}& K_{\text{I}}=\frac{Y\cdot P}{B\cdot \sqrt{a}},\end{array}$$where $Y$ is the stress intensity factor coefficient, which is derived from stress analysis for a sample of a particular geometric shape, $P$ is the loading force, and $B$ is the thickness of the specimen.

In Equation (7), r is the distance from the crack tip to the measurement point, and r₀ is the boundary of the plastic region in the front of crack tip. For a fixed K_I,$$\begin{array}{}\text{(9)}& r_0=\frac{1}{2}{\left(\frac{Y\cdot {\sigma }_{\text{s}}}{K_I}\right)}^2.\end{array}$$

In a stress-induced hydrogen corrosion environment, it is assumed that the microhardness increment along the crack propagation direction of the specimen can be generally divided into two parts: plane strain theoretical stress-induced microhardness increment and the hydrogen-induced microhardness increment. The relationship can be given by the following equation:$$\begin{array}{}\text{(10)}& \Delta \text{HV}=\Delta {\text{HV}}_{\sigma }+\Delta {\text{HV}}_{{\text{c}}_{\sigma }}={\sigma }_{y,\text{0}}/g_{\text{n}}+\Delta {\text{HV}}_{{\text{c}}_{\sigma }}\cdot \exp \left(\frac{\overline{V_{\text{H}}}\cdot {\sigma }_{\text{h}}}{R\cdot T}\right).\end{array}$$

4.1. Microhardness Increment of Stress-Free Area after Corrosion

The mean and standard deviation of the microhardness increment values of stress-free area with different corrosion periods are shown in Figure 2. Subtracting the measured hardness value before corrosion from the measured hardness value after corrosion, the microhardness increment value under different corrosion periods can be obtained. The change in the hardness value of stress-free area after corrosion is the result of individual effect of hydrogen corrosion. Student’s t-test for quantitative variables and chi-squared test for qualitative variables were used for statistical analysis. It can be seen from the results that there is no significant difference ($P>0.05$) in microhardness increment with different corrosion periods.

[figure omitted; refer to PDF]

4.2. Microhardness Increment along the Crack Propagation Direction of Specimens before and after Corrosion

The microhardness increment distribution was calculated along the crack propagation direction of multiple groups of specimens after soaking for 0 h, 24 h, 48 h, and 72 h in saturated hydrogen sulfide solution, respectively, as shown in Figure 3. The vertical axis represents the microhardness value of the material, and the horizontal axis represents the distance from the crack tip. The microhardness increment is obtained by calculating the difference between the measured hardness and the hardness under stress-free and no corrosion conditions.

[figures omitted; refer to PDF]

In Figure 3, the black square line represents the microhardness increment distribution curve along the crack propagation direction of each specimen under the no corrosion condition. The red circular line represents the microhardness increment distribution curve along the crack propagation direction of each specimen after soaking for 24 hours in saturated hydrogen sulfide solution. The blue triangular line represents the microhardness increment distribution curve along the crack propagation direction of each specimen after soaking in saturated hydrogen sulfide solution for 48 hours. The green triangle line represents the microhardness increment distribution curve along the crack propagation direction of each specimen after soaking in saturated hydrogen sulfide solution for 72 hours.

5.1. Relationship between Applied Stress and Microhardness Increment

The blue line in Figure 4 shows that the average measured microhardness increment distribution curve along the crack propagation direction, which is calculated by averaging the microhardness increment distributions of the no corrosion condition. In Figure 4, the blue vertical axis represents the microhardness value of the material, the black horizontal axis represents the distance from the crack tip, the blue horizontal solid line is the average hardness values, the horizontal dotted line is the standard deviations of the hardness value, the blue vertical solid line is the mean distance from the crack tip, and the vertical dotted line is the standard deviation of the distance from the crack tip.

[figure omitted; refer to PDF]

The red line in Figure 4 shows that the theoretical stress (σ_y = σ_e) distribution curve along the crack propagation direction of specimens. The red vertical axis represents the stress value, and the black horizontal axis represents the distance from the crack tip.

In Figure 4, the microhardness increment distribution is consistent with the applied stress distribution. The result shows that the stress-induced microhardness increment is due to the presence of stress. To reveal the influence of the applied stress Δσ on the microhardness, the relationship between the applied stress Δσ and the stress-induced microhardness increment ΔHV_σ was investigated, as shown in Figure 5.

[figure omitted; refer to PDF]

From Figure 5, in the no corrosion environment, the microhardness increment versus the applied stress fields have strong linear correlation with a correlation coefficient, R, of 0.98 and significance level of 0.04·10⁻¹⁴. Therefore, an equation describing the relationship between the applied stress and the microhardness increment can be given as follows:$$\begin{array}{}\text{(11)}& \Delta \sigma =k_{\text{const}}\cdot \Delta {\text{HV}}_{\sigma },\end{array}$$where Δσ = σ − σ_b, ΔHV_σ = HV_σ − HV_b, σ is the stress at any point along the direction of crack propagation, σ_b is the corrected stress value of the applied stress, HV is the Vickers hardness at any point along the direction of the crack propagation, HV_b is the Vickers hardness of stress-free area, and k_const is a constant of proportionality, equal to −10 in the present study.

This is in accord with the result of stress estimation by Suresh and Giannakopoulos [14] using the indentation theory, as is shown in Equation (4).

Therefore, in the no corrosion environment, the stress can be described using the stress-induced microhardness increment linearly as follows:$$\begin{array}{}\text{(12)}& \sigma -144=\Delta {\text{HV}}_{\sigma }\cdot \left(-10\right).\end{array}$$

Equation (12) reveals that the stress distribution in front of the crack tip can be evaluated precisely using the microhardness method. For a modified WOL specimen with a fixed stress factor K_I,$$\begin{array}{}\text{(13)}& \Delta {\text{HV}}_{\sigma }=\left\{\begin{array}{cc}\frac{-\left({\sigma }_{\text{s}}-144\right)}{10},& r\le r_0,\\ -\left(\frac{K_{\text{I}}}{Y\sqrt{2r}}-144\right)/10,& r>r_0.\end{array}\right.\end{array}$$

5.2. The Hydrogen Distribution in the Stress Environment

The blue line in Figure 6 shows that the experimental average microhardness increment distribution (experimental microhardness increment) along the crack propagation direction of all specimens under the combined effect of applied stress and hydrogen corrosion, which is calculated by averaging the microhardness increment distributions of the same corrosion period in Figure 3. In Figure 3, the curves under the same corrosion period have a strong consistency, indicating the stability of the corrosion soaking in saturated hydrogen sulfide solution.

[figures omitted; refer to PDF]

The red line in Figure 6 shows the plane strain theoretical stress-induced microhardness increment distribution (stress-induced microhardness increment) along the crack propagation direction of specimens without hydrogen corrosion, which was obtained from the relationship between stress and microhardness increment (Equation (12)).

Subtracting the red line (micro-hardness increment distribution curve under the no corrosion condition) from the blue line (microhardness increment distribution curve under the corrosion condition), a new micro-hardness increment distribution curve is obtained, shown as the green line in Figure 6.

The orange line in Figure 6 shows that the hydrogen-induced microhardness increment (theoretical hydrogen-induced microhardness increment) along the crack propagation direction of the WOL specimen, which can be calculated by Equation (6). The hydrostatic stress under plane stress state is σ_e = (σ₁ + σ₂ + σ₃)/3 = 2σ_e/3.

The obtained green line is the experimental curve of hydrogen-induced microhardness increment (experimental hydrogen-induced microhardness increment) distribution along the crack propagation direction of specimens because the green line and the orange line are in good agreement with each other. Therefore, the hydrogen distribution behavior in the stress environment can be successfully measured using the microhardness method. In the actual project, as long as the stress environment is a known equibiaxial stress environment, the microhardness method can be used to accurately obtain the hydrogen concentration distribution in the equipment.

This also reveals that, under the combined effect of applied stress and hydrogen corrosion, the measured microhardness increment can be generally divided into two parts: plane strain theoretical stress-induced microhardness increment and the hydrogen-induced microhardness increment. In this study, the relationship can be given by the following equation:$$\begin{array}{}\text{(14)}& \Delta \text{HV}=\Delta {\text{HV}}_{\sigma }+\Delta {\text{HV}}_{{\text{c}}_{\sigma }}=\left\{\begin{array}{cc}\frac{-\left({\sigma }_{\text{s}}-144\right)}{10}+\Delta {\text{HV}}_{{\text{c}}_{\text{0}}}\exp \left(\frac{\overline{V_{\text{H}}}\cdot {\sigma }_{\text{h}}}{R\cdot T}\right),& r\le r_0,\\ -\left(\frac{K_{\text{I}}}{Y\sqrt{2r}}-144\right)/10+\Delta {\text{HV}}_{{\text{c}}_{\text{0}}}\exp \left(\frac{\overline{V_{\text{H}}}\cdot {\sigma }_{\text{h}}}{R\cdot T}\right),& r\ge r_0.\end{array}\right..\end{array}$$