Acta Physica Sinica, Volume. 69, Issue 9, 096103-1(2020)
Figures & Tables(10)
Fig. 1. Positron lifetime of vacancies and potassium-containing vacancies in tungsten lattice.
Fig. 2. Distribution of positron annihilation region: (a) 9 × 9 × 9 BCC tungsten lattice supercell with a vacancy; (b) W-GB-1 supercell; (c) W-GB-1 supercell with a vacancy at the GBs; (d) W-GB-1 supercell with a potassium at the GBs.
Fig. 3.
Fig. 4.
Table 1.
Grain boundary (GB) and dislocation line (DL) model for positron annihilation lifetime calculation
正电子湮没寿命计算中建立的晶界和位错模型
View tableView in ArticleTable 1.
Grain boundary (GB) and dislocation line (DL) model for positron annihilation lifetime calculation
正电子湮没寿命计算中建立的晶界和位错模型
编号 Σ GB plane GB type Rotation axis Angle/(°) W-GB-1 5 $ \langle 210 \rangle $ twist z(001) 53.15 W-GB-2 13 $ \langle 510 \rangle $ twist z(001) 22.61 W-GB-3 5 $ \{0\bar1 5\} $ tilt x(100) 22.61 W-GB-4 13 $ \{0\bar15\} $ tilt x(100) 53.15 编号 Slip plane(z) Burgers vector[ b ]Dislocation line[y] Dislocation type b-y Angle/(°) W-DL-1 $ (\bar101) $ (111)/2 $ (\bar 12\bar 1) $ EDGE 90 W-DL-2 $ (\bar101) $ (111)/2 (111) SCREW 0 W-DL-3 $ (\bar101) $ (111)/2 (010) MIX 54.73
Table 2.
Positron annihilation lifetime of grain boundary and dislocation with vacancies or potassium atoms.
晶界和位错包含空位或钾原子时的正电子湮没寿命值
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Positron annihilation lifetime of grain boundary and dislocation with vacancies or potassium atoms.
晶界和位错包含空位或钾原子时的正电子湮没寿命值
编号 Intact/ps Vac.1/ps Vac.9/ps K1/ps K9/ps W-GB-1 116.6 198.2 297.4 110.6 108.4 W-GB-2 117.9 198.0 297.2 116.4 111.7 W-GB-3 135.2 204.8 304.4 142.3 144.1 W-GB-4 142.2 198.0 317.3 141.0 144.6 W-DL-1 133.9 160.3 309.7 133.9 134.2 W-DL-2 106.5 194.7 324.0 104.7 105.8 W-DL-3 123.4 158.0 315.4 123.4 123.4
Table 3.
Two-component positron lifetime of W-K samples with different potassium content.
不同钾含量的钨钾合金样品的双组分正电子寿命值
View tableView in ArticleTable 3.
Two-component positron lifetime of W-K samples with different potassium content.
不同钾含量的钨钾合金样品的双组分正电子寿命值
钾含量/ppm 编号 ${\tau _{{\rm{1, }}\exp }}$ ${I_{1, \exp }}$ ${\tau _{{\rm{2, }}\exp }}$ ${I_{2, \exp }}$ 平均寿命 ${\tau _{{\rm{av}}}}$ 捕获率 $\kappa $ 计算体寿命 $\tau _{\rm{1}}^{{\rm{cal}}}$ 46 A1 123.4 74.62 296.2 25.38 167.3 1.1999 97.2 82 B1 123.3 75.68 305.1 24.32 167.5 1.1752 97.4 122 C1 140.1 72.42 332.6 27.58 193.2 1.1395 97.7 144 D1 143.2 77.07 328.3 22.93 185.6 0.9028 100.1
Table 4.
Dislocation and vacancy clusters in W-K samples with potassium content.
不同钾含量的钨钾合金样品中位错和空位团簇
View tableView in ArticleTable 4.
Dislocation and vacancy clusters in W-K samples with potassium content.
不同钾含量的钨钾合金样品中位错和空位团簇
钾含量/ppm 编号 位错捕获率 ${\kappa _1}$ 空位团簇捕获率 ${\kappa _2}$ 位错密度 ${C_{{\rm{dis}}}}$ 空位团簇浓度 ${C_{{\rm{cl}}}}$ 46 A1 0.00912 0.00505 0.8289 1.515 82 B1 0.00895 0.00474 0.8136 1.424 122 C1 0.03359 0.01511 3.0534 4.538 144 D1 0.04400 0.01489 3.9991 4.470
Table 5.
Fitted values of S parameters of W-K samples with different potassium content.
不同钾含量的钨合金样品的S参数拟合
View tableView in ArticleTable 5.
Fitted values of S parameters of W-K samples with different potassium content.
不同钾含量的钨合金样品的S参数拟合
钾含量/ppm 编号 第一层厚度/nm 第一层S1 第二层S2 46 A2 10 0.4521 0.4424 82 B2 11 0.4520 0.4406 122 C2 13 0.4521 0.4455 0 PMW 10 0.4050 0.3880
Table 6.
Positron diffusion length in tungsten alloy samples with different potassium content.
不同钾含量的钨合金样品中正电子扩散长度
View tableView in ArticleTable 6.
Positron diffusion length in tungsten alloy samples with different potassium content.
不同钾含量的钨合金样品中正电子扩散长度
钾含量/ppm 编号 寿命谱 $L_{{\rm{ +, eff}}}^{{\rm{cal}}}$ 编号 第一层 $L_{ +, {\rm{eff}}}^1$ 第二层 $L_{ +, {\rm{eff}}}^2$ 46 A1 77.59 A2 2.73 ± 0.89 59.75 ± 9.96 82 B1 78.39 B2 4.98 ± 1.06 58.61 ± 7.86 122 C1 49.22 C2 1.65 ± 1.56 37.44 ± 7.72 0 PMW 6.50 ± 0.29 109.32 ± 5.46
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Pei-Yuan Zhang, Ai-Hong Deng, Xue-Fen Tian, Jun Tang.
Paper Information
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Received: Nov. 25, 2019
Accepted: --
Published Online: Nov. 26, 2020
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