图 1  序参量η与ϕ_i的取值在相场模型中的表现

Fig. 1.  Representation of the values of order parameters η and ϕ_i in the phase-field model.

图 2  自由能密度随浓度(c_v, c_g)分布的变化, 曲线最低点的横坐标为平衡浓度, 随着c_g增加, $ c_{\text{v}}^{{\text{b, eq}}} $逐渐减小, f ^bubble,v的图像(蓝色虚线)将向左平移

Fig. 2.  Variation of free energy density with concentration (c_v, c_g) distribution, the abscissa of the lowest point of the curve is the equilibrium concentration. As c_g increases, $ c_{\text{v}}^{{\text{b, eq}}} $ gradually decreases, and the image of f ^bubble,v (blue dashed line) will shift to the left.

图 3  T = 1276 K条件下直径5 μm晶粒与气泡随时间演化分布　(a) τ = 0 s; (b) τ = 140 s; (c) τ = 160 s; (d) τ = 200 s; (e) τ = 300 s; (f) τ = 550 s

Fig. 3.  Distribution of grain with a diameter of 5 μm and bubble evolution over time at T = 1276 K: (a) τ = 0 s; (b) τ = 140 s; (c) τ = 160 s; (d) τ = 200 s; (e) τ = 300 s; (f) τ = 550 s.

图 4  空位(c_v, (a), (c))与裂变气体(c_g, (b), (d))在τ = 140 s与τ = 550 s的浓度分布(不同的颜色代表浓度的取值)　(a), (b) τ = 140 s; (c), (d) τ = 550 s

Fig. 4.  Concentration distribution of vacancies (c_v, (a) and (c)) and fission gases (c_g, (b) and (d)) at τ = 140 s and τ = 550 s, different color represent the value of concentration: (a), (b) τ = 140 s; (c), (d) τ = 550 s.

图 5  (a) 整个模拟区域内的平均自由能密度随时间的变化; (b) 总自由能密度在整个模拟区域分布, 颜色栏为取值范围; (c)某一气泡径向自由能密度分布

Fig. 5.  (a) Variation of average free energy density over time in simulation area; (b) distribution of the total free energy density in simulation area, the color bar represents the range of values; (c) radial free energy density distribution of a certain bubble.

图 9  相同温度不同晶粒尺寸, (a), (c), (e)孔隙度与(b), (d), (f)晶界气泡覆盖率随时间演化　(a), (b) T = 1276 K; (c), (d) T = 1476 K; (e), (f) T = 1676 K

Fig. 9.  Evolution of (a), (c), (e) porosity and (b), (d), (f) bubble coverage on GB over time for the same temperature but different grain sizes: (a), (b) T = 1276 K; (c), (d) T = 1476 K; (e), (f) T = 1676 K.

图 6  T = 1276, 1476, 1676 K条件下直径10 μm晶粒与气泡分布图　(a) T = 1276 K, τ = 180 s; (b) T = 1476 K, τ = 180 s; (c) T = 1676 K, τ = 180 s; (d) T = 1276 K, τ = 500 s; (e) T = 1476 K, τ = 500 s; (f) T = 1676 K, τ = 500 s

Fig. 6.  Distribution of grains with a diameter of 10 μm and bubbles under T = 1276, 1476, 1676 K: (a) T = 1276 K, τ = 180 s; (b) T = 1476 K, τ = 180 s; (c) T = 1676 K, τ = 180 s; (d) T = 1276 K, τ = 500 s; (e) T = 1476 K, τ = 500 s; (f) T = 1676 K, τ = 500 s.

图 7  直径10 μm晶粒3种温度条件下(a)孔隙度与(b)晶界气泡覆盖率随时间演化

Fig. 7.  Evolution of (a) porosity and (b) bubble coverage on grain boundaries over time under three temperature conditions for grains with a diameter of 10 μm.

图 8  T = 1476 K, τ = 250 s时晶粒与气泡分布　(a) 5 μm; (b) 10 μm; (c) 15 μm; (d) 20 μm

Fig. 8.  Distribution of grains and bubbles at τ = 250 s, T = 1476 K: (a) 5 μm; (b) 10 μm; (c) 15 μm; (d) 20 μm.

图 10  采用$ {D^{{\text{undoped}}}} $与$ {D^{{\text{doped}}}} $晶粒与气泡分布对比　(a) T = 1676 K, 15 μm, $ {D^{{\text{undoped}}}} $; (b) T = 1676 K, 15 μm, $ {D^{{\text{doped}}}} $; (c) T = 1476 K, 20 μm, $ {D^{{\text{undoped}}}} $; (d) T = 1476 K, 20 μm, $ {D^{{\text{doped}}}} $

Fig. 10.  Comparison of the distribution of grains and bubbles using $ {D^{{\text{undoped}}}} $ and $ {D^{{\text{doped}}}} $: (a) T = 1676 K, 15 μm, $ {D^{{\text{undoped}}}} $; (b) T = 1676 K, 15 μm, $ {D^{{\text{doped}}}} $; (c) T = 1476 K, 20 μm, $ {D^{{\text{undoped}}}} $; (d) T = 1476 K, 20 μm, $ {D^{{\text{doped}}}} $.

图 11  对于直径15 μm与20 μm晶粒, (a), (c) 孔隙度与(b), (d)晶界气泡覆盖率随时间演化　(a), (b) 直径15 μm; (c), (d) 直径20 μm

Fig. 11.  Evolution of (a), (c) porosity and (b), (d) bubble coverage on grain boundary with time for grains with a diameter of 15 μm and 20 μm: (a), (b) Diameter 15 μm; (c), (d) diameter 20 μm.