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シュウモン固体における拡散原書2版(電子書籍版)

出版社：	丸善出版
著者：	P.シュウモン(著) 藤川辰一郎(訳)
発行日：	2021-02-26
分野：	その他 > 一般
ISBN：	9784621305409
電子書籍版：	2021-02-26 （電子書籍版）

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固体の拡散現象を基礎から説いた名著の第2版の邦訳。翻訳版では訳者により付表が追加され、代表的な金属(Al, Mg, Ti, Fe, Cu, Ni)中における最新の研究を含む詳細な拡散データが掲載されている。また、訳注にて、原書刊行以降の成果が多数紹介されている。重要な概念の解説と豊富な例題がコンパクトにまとまった教科書としてはもちろん、同分野の最新の情報を得ることができる専門書としても有用な書籍である。

表紙
目次
原著者序文
第1章拡散方程式
1.1 拡散流束方程式
1.2 拡散方程式
1.3 拡散方程式の解 ( Dが一定の場合 )
1.4 析出の速度論
1.5 応力の影響下での拡散
1.6 可変なDに対する解
1.7 二相の二元系
1.8 非立方晶の格子中の拡散
第2章拡散の原子論
2.1 ランダムな移動と拡散係数
2.2 拡散機構
2.3 ランダムウォークの問題
2.4 Dの計算
2.5 第一原理からのHおよびSの計算
2.6 Hv, HmおよびSvの実験的決定
2.7 拡散に及ぼす静水圧の影響
2.8 QおよびDOを得るための経験則
2.9 複空孔の形成
2.10 自己拡散の異常性
第3章希薄合金中の拡散
3.1 格子間原子と擬弾性
3.2 純金属中の不純物拡散
3.3 相関効果
3.4 置換型合金中の格子間拡散
3.5 トラップのある拡散
第4章濃度勾配下での拡散
4.1 カーケンドール効果
4.2 ダーケンの解析
4.3 現象論的拡散方程式
4.4 固有拡散係数D1とトレーサー拡散係数D1 * の間の関係
4.5 ダーケンの仮定の検証
4.6 三元合金
4.7 二元系相図を横断してのD ~ の評価
第5章非金属中の拡散
5.1 イオン性固体中の欠陥
5.2 拡散とイオン伝導
5.3 σとDTの間の関係の実験的評価
5.4 DTおよびσに及ぼす不純物の影響
5.5 電気伝導率に及ぼす不純物の影響 ( フレンケル欠陥 )
5.6 AgBr中のDTに対するσの関係 ( フレンケル欠陥 )
5.7 酸化物半導体
5.8 元素半導体
5.9 規則合金と金属間化合物相
第6章高速拡散路
6.1 粒界拡散の解析
6.2 粒界拡散についての実験的観察
6.3 転位および粒径効果
6.4 移動する粒界に沿っての拡散
6.5 表面拡散と形状変化
6.6 表面拡散データおよび表面拡散機構
第7章固体中のサーモトランスポートおよびエレクトロトランスポート
7.1 エレクトロトランスポート
7.2 サーモトランスポート - 格子間原子合金
7.3 サーモトランスポート - 空孔拡散
付表代表的な金属中の各種元素の拡散データ
表1 アルミニウム中の自己拡散および不純物拡散
表2 マグネシウム中の自己拡散および不純物拡散
表3 α - Ti中の自己拡散および不純物拡散
表4 α - およびγ - 鉄中の自己拡散および不純物拡散
表5 銅中の自己拡散および不純物拡散
表6 ニッケル中の自己拡散および不純物拡散
訳者あとがき
索引
奥付

この書籍の参考文献

参考文献のリンクは、リンク先の都合等により正しく表示されない場合がありますので、あらかじめご了承下さい。

本参考文献は電子書籍掲載内容を元にしております。

第1章拡散方程式

P.2 掲載の参考文献

1) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「フィックの拡散方程式とその解」, 丸善出版, 2012, pp. 5-16.

2) T. Okino, "Theoretical evidence for revision of Fickian first law and new understanding of diffusion problems", J. Mod. Phys., 3 (2012) 1388-93.

H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「拡散の連続体理論」, 「拡散方程式の解」, 丸善出版, 2012, pp. 31-57.

P.3 掲載の参考文献

3) R. P. Smith, Acta Met., 1 (1953) 578.

P.7 掲載の参考文献

7) Crank, Mathematics of Diffusion, 2nd ed., Oxford Univ. Press, 1975.

8) H. S. Carslaw, J. C. Jaeger, Conduction of Heat in Solids, Oxford Univ. Press, 1959.

9) O. D. Kellog, Foundations of Potential Theory, Springer-Verlag, New York, 1967.

P.8 掲載の参考文献

10) H. S. Carslaw, J. C. Jaeger, Conduction of Heat in Solids, Oxford Univ. Press, 1959.

11) O. D. Kellog, Foundations of Potential Theory, Springer-Verlag, New York, 1967.

13) W. A. Johnson, Trans. AIME, 147 (1942) 331.

P.11 掲載の参考文献

藤川辰一郎, 「固体における拡散研究におけるイオンビームスパッタリングの応用」, 日本金属学会会報, 25 (1986) 608.

藤川辰一郎, 「拡散研究を活性化させるマイクロセクショニング技術」, 金属, 56 (1986) 52.

19) 藤川辰一郎, 「イオンビーム・マイクロエッチングと放射性トレーサーを利用しての小さな拡散係数の測定」, 固体物理, 20 (1983) 923.

20) S. J. Rothman, Measurement of Tracer Diffusion Coefficients in Solids, Diffusion in Crystalline Solids, ed. G. E. Murch, A. S. Nowick, Academic Press, 1984, pp. 1-61.

P.19 掲載の参考文献

26) M. Hill, E. Johnson, Acta Met., 3 (1955) 566.

P.20 掲載の参考文献

A. J. Ardell, "A1-L12 interfacial free energies from data on coarsening in five binary Ni alloys", J. Mater. Sci., 46 (2011) 4832.

27) M. E. Glicksman, "Spherical bodies" and "Population dynamics", Diffusion in solids : theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 9, Chap. 22, pp.135-159, pp.377-390.

28) 藤川辰一郎, 及木義則, 平野賢一, 「電気抵抗測定によるアルミニウム中のけい素の固溶度およびAl-Si合金におけるSi 析出物粒子のオストワルド成長の研究」, 軽金属, 29 (1979) 331.

29) F. S. Ham, J. Phys. Chem. Solids, 6 (1958) 335-51.

P.24 掲載の参考文献

31) H. H. Jo, S.-I. Fujikawa, "Kinetics of precipitation in Al-Sc alloy and low temperature solid solubility of Sc in aluminum studied by electrical reisistivity measurement", Mat. Sci. Eng. A, A171 (1993) 277.

33) Brown 粒子の運動理論-材料科学における拡散理論の新知見, 沖野隆久, エヌ・ティー・エス, 2017, p. 121.

P.26 掲載の参考文献

34) 理化学英和辞典 (小田稔ら編集, 研究社, 1998 年, p. 242).

P.27 掲載の参考文献

35) F. S. Ham, J. Appl. Phys., 30 (1959) 915.

P.28 掲載の参考文献

36) A. Cocarddt, G. Schoeck, H. Wiedersich, Acta Met., 3 (1955) 533.

37) J. Crank, The Mathematics of Diffusion, Oxford University Press, 1967.

P.29 掲載の参考文献

小岩昌宏, 「俣野仲次郎の拡散研究」, マテリア, 38 (1999) 798.

小岩昌宏, W. Sprengel,「材料科学のパイオニアたち, 拡散研究の始まりとボルツマン-俣野の方法」, マテリア, 46 (2007) 682.

39) C. Matano, Japan Phys., 8 (1933) 109.

40) 小岩昌宏, 「俣野仲次郎-相互拡散の "Matano Interface" に不朽の名を残す研究者の軌跡」, まてりあ, 38 (1999) 511.

P.31 掲載の参考文献

"MATANO-A Computer Code for the Analysis of Interdiffusion and Intrinsic Diffusion Information in Binary Systems," P. T. Carlson, ORNL-5045, June 1975, NTIS, 5285 Port Royal Rd., Springfield VA, 22161.

41) H. C. Akuezue, D. P. Whittle, Metal Science, 17 (1983) 27.

42) 沖野隆久, Brown粒子の運動理論-材料科学における拡散理論の新知見, エヌ・ティー・エス, 2017, p. 68.

P.36 掲載の参考文献

49) W. Jost, Diffusion in Solids, Liquids, Gases, Academic Press, 1952, pp. 69-75.

50) G. V. Kidson, J. Nucl. Mat., 3 (1961) 21.

51) S. R. Shatynski, J. P. Hirth, R. A. Rapp, Acta Met., 24 (1975) 1071.

P.37 掲載の参考文献

J. Nye ("The ground work of crystal physics", Physical properties of crystals : their representation by tensors and matrices, Clarendon Press, 1957, 1985, Chap. I, pp. 3-22).

52) W. Wooster, "The application of tensor notation to crystal physics", A text book on crystal physics, Cambridge Univ. Press, 1938, 2016, Chap I, pp. 1-14.

P.46 掲載の参考文献

56) ホイマン著, 藤川辰一郎訳, 「金属における拡散-純金属および合金における拡散の基礎, 理論, 現象」, 丸善出版, 2012, pp. 24-26.

第2章拡散の原子論

P.49 掲載の参考文献

1) 米沢登美子, ブラウン運動, 共立出版, 1986.

沖野隆久, Brown粒子の運動理論-材料科学における拡散理論の新知見, エヌ・ティー・エス, 2017, p. 1, p. 27.

T. Okino, "Brownian motion in parabolic space", J. Mod. Phys., 3 (2012) 255-9.

P.50 掲載の参考文献

3) A. Einstein, Investigation on the Theory of Brownian Movement, Dover Publications, New York, 1956.

6) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「ランダムウォーク理論と原子ジャンプ過程」, 丸善出版, 2012, pp. 59-71.

N. Wax (ed.), Selected Papers on Noise and Stochstic Processes, Dover Publications, New York, 1954.

P.53 掲載の参考文献

11) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「拡散機構」, 丸善出版, 2012, pp. 99-109.

P.56 掲載の参考文献

15) L. A. ジルファルコ著, 北田正弘訳, 入門結晶中の原子の拡散, 共立出版, 1980, p. 62.

P.59 掲載の参考文献

18) M. E. Glicksman, "Random walks and diffusion", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 12, pp. 191-212.

19) G. Gamov, One, Two, Three...Infinity, Viking Press (1947), Chap. 8.

20) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「ランダムウォーク理論と原子ジャンプ過程」, 丸善出版, 2012, pp. 59-71.

J. Manning, Diffusion Kinetics for Atoms in Crystals, Van Norstrand, 1968.

小岩昌宏, 中嶋英雄, 材料における拡散-格子上のランダム・ウォーク, 内田老鶴圃, 2009, pp. 25-35, pp. 127-45.

P.64 掲載の参考文献

24) B. S. Chandrsekhar, Revs. Modern Phys., 15 (1943).

26) M. N. Barber, B. W. Ninham, "Diffusion and Brownian motion", Random and restricted walks : theory and applications, Gordon & Breach, 1970, Chap. 6, pp. 75-80.

N. Wax (ed.), Selected Papers on Noise and Stochstic Processes, Dover Publications, New York, 1954.

P.71 掲載の参考文献

32) C. P. Flynn, Point Defects and Diffusion, Clarendon-Oxford Press, (1972) "The dynamics of atomic migration".

33) C. Zener : W. Schockley (ed.), Imperfections in Nearly Perfect Crystals, John Wiley & Sons, Inc., New York, 1952, p. 289.

C. P. Flynn, Point Defects and Diffusion, Clarendon-Oxford Press, (1972), pp. 335-7.

P.73 掲載の参考文献

34) C. Wert, C. Zener, Phys. Rev., 76 (1949) 1169.

P.74 掲載の参考文献

2) M. Mantina et al., "3d transition metal impurities in aluminum : A first-principles study", Phys. Rev. B, 80 (2009) 184111.

35) 1) S.-Li. Shng et al., A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients, Acta Mater., 109 (2016) 128-41.

36) R. A. Johnson, "Comparison of calculated and measured values of ΔHf and ΔHm for vacancies in pure metals", Diffusion, ASM, Metals Park, OH, 1973, Chap. 2, pp. 25-46.

M. Manjeera, "A first-principles methodology for diffusion coefficient in metals and dilute alloys", Pennsylvania State University 2008, Ph. D, thesis, 全252頁.

P.75 掲載の参考文献

38) F. Fumi, Phil. Mag., 46 (1955) 1007.

P.77 掲載の参考文献

39) H. Huntington, G. Shirn, E. Wajda, Phys. Rev., 99 (1955) 1085.

P.78 掲載の参考文献

40) A. Kuper, H. Letaw, L. Silfkin, C. Tomizuka, Phys. Rev., 98 (1955) 1870.

P.79 掲載の参考文献

2) K. M. Carling, et al., "Vacancy concentration in Al from combined first-principles and model potential calculations", Phys. Rev. B, 67 (2003) 054101.

44) R. Simmons, R. Balluffi, Phys. Rev., 119 (1960) 600.

46) 1. M. Mantina, et al., "First-principles calculation of self-diffusion coefficients", Phys. Rev. Lett., 100 (2008) 215901.

P.82 掲載の参考文献

49) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 丸善出版, 2012, pp. 81-83.

白井泰治, 「陽電子消滅法による金属中の空孔およびその集合体の研究」, 日本金属学会会報, 27 (1988), 869-77.

白井泰治, 「金属間化合物中の構造欠陥」, まてりあ, 35 (1996), 117-21.

長谷川雅幸, 「陽電子消滅法の原理と格子欠陥研究」, まてりあ, 35 (1996), 93-102.

P.83 掲載の参考文献

52) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「拡散の温度および圧力依存性」, 丸善出版, 2012, pp. 133-55.

P.84 掲載の参考文献

54) G. Rummel, T. Zumkley, M. Eggermann, K. Freitag, H. Mehrer, "Diffusion of implanted 3d-transition elements in aluminum. Part II. Pressure dependece", Z. Metallkd., 86 (1995) 131.

55) H. Mehrer, N. Stolica, "Mass and pressure dependence of diffusion in solid metals and alloys", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 574-629.

S. Fujikawa, M. Werner, H. Mehrer, A. Seeger, "Effect of hydrostaic pressure on the diffusion of gold in copper in the low-temperature regime", Defect Diffusion Forum., 66-69 (1989) 421.

P.85 掲載の参考文献

56) R. Emrick, Phys. Rev., 122 (1961) 1720.

P.86 掲載の参考文献

58) a) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「拡散と材料のバルクの性質の間の相関」, 「金属中の侵入型溶質原子の拡散」, 丸善出版, 2012, pp. 148-155, pp. 321-34.

59) H. Bakker, Diffusion in Crystalline Solids, eds., G. E. Murch, A. S. Nowick, Academic Press, 1984, pp. 189-258.

b) G. P. Tiwari, R. Mehrotra, Y. Iijima, "Solid state diffusion and bulk properties", Diffusion processes in advanced technological materials, ed., D. Gupta, Springer, 2005, Chap. 2, pp. 69-111.

P.88 掲載の参考文献

60) G. V. Kidson, "The diffusion of H, D, and T in solid metals", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, Springer-Verlag, ed. H. Mehrer, 1990, pp. 504-573.

61) H. Mehrer, N. Stolica, N. A. Stolwijik, "Self-diffusion in solid metallic elements", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, pp. 32-84.

A. D. Le Claire, "Diffusion of C, N, and O in metals", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, Springer-Verlag, ed. H. Mehrer, 1990, pp. 471-503.

G. Neumann, C. Tuijn, Self-diffusion and impurity diffusion in pure metals : Handbook of experimenta data, Elsevier, 2009.

P.90 掲載の参考文献

63) L. Darken, R. Curry, Physical Chemistry of Metals, Chap. 9, McGraw-Hill Book Company, New York, 1953.

P.91 掲載の参考文献

66) H. メーラー著, 藤川辰一郎訳, 固体中の拡散, 丸善出版, 2012年.

H. Mehrer, N. Stolica, N. A. Stolwijk, "Self-diffusion in solid metallic elements", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 32-84.

G. Neumann, C. Tuijn, Self-diffusion and impurity diffusion in pure metals : Handbook of experimental data, Elsevier, 2009.

P.94 掲載の参考文献

2) D. G. Sangiovanni et al., "Superioniclike diffusion in an elemental crystal : bcc titanium", Phys. Rev. Lett., 123 (2019) 105501.

68) J. N. Mundy, Phys. Rev. B, 3 (1971) 2431.

69) 1) D. Smirnova et al., "Atomistic description of self-diffusion in molybdenum : A comparative theoretical study of non-Arrhenius behavior", Phys. Rev. Materials, 4 (2020) 013605.

70) J. Federer, T. S. Lundy, Trans. AIME, 227 (1963) 592.

N. L. Peterson, J. Nucl. Mater., 69&70 (1978) 3-37.

P.95 掲載の参考文献

1) L. Messina, et al., "Systematic electroic-structure investigation of substitutional impurity diffusion and flux coupling in bcc iron", Phys. Rev. B, 93 (2016) 184302.

2) C. D. Versteylen, et al., "First-principles analysis of solute diffusion in dilute bcc-Fe-X alloys", Phys. Rev. B, 96 (2017) 094105.

3) S. Huang, et al., "Calculation of impurity diffusivities in α-Fe using first-principles methods", Acta Mater., 58 (2010), pp. 1982-93.

4) H. Ding, et al., "Self diffusion anomaly in ferromagnetic metals : A density-functional-theory investigation of magnetically ordered and disordered Fe and Co", Acta Mater., 70 (2014), pp. 130-6.

71) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「純金属における拡散, 遷移金属」, 丸善出版, 2012年, pp. 149-57.

72) M. Sanchez, D. de Fontaine, Acta Met., 26 (1978) 1083.

73) G. Hettich, H. Mehrer, K. Maier, Scripta Met., 11 (1977) 795.

74) Phys. Chem. Solids, 23 (1962) 1171.

J. Phys. Chem. Solids, 37 (1976) 649.

第3章希薄合金中の拡散

P.100 掲載の参考文献

1) A. S. Nowick, B. S. Berry, Anelastic Relaxation in Crystalline Solids, Academic Press, New York, 1972.

3) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「メカニカル・スペクトロスコピー」, 丸善出版, 2012, pp. 245-60.

小岩昌宏, 中嶋英雄著, 材料における拡散-格子上のランダム・ウオーク, 「拡散による擬弾性-侵入型原子の拡散」, 内田老鶴圃, 2009, pp. 85-112.

M. E. Glickdmsn, "Diffusional anelasticity", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 19, pp. 323-42.

P.103 掲載の参考文献

6) 藤川辰一郎分担執筆, 「内部摩擦の測定」, 実験材料科学内田老鶴圃, 112, 1996.

岩崎邦彦, 「マイコンによる低周波内部摩擦自動測定と即時データ処理」, 日本金属学会会報, 21 (1982) 715-9.

P.105 掲載の参考文献

10) T. Ke, Phys. Rev., 74 (1948) 9.

11) D. Beshers, "Diffusion of interstitial impurities", Diffusion, ASM, Metals Park, OH, 1973, Chap. 8, pp. 209-40.

P.106 掲載の参考文献

13) H. メーラー著, 藤川辰一郎訳, 固体中の拡散, 丸善出版, 2012.

A. D. Le Claire, "Diffusion of of C, N, and O in metals", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 471-503.

P.108 掲載の参考文献

14) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「希薄な置換型合金中の拡散」, 丸善出版, 2012, pp. 335-48.

A. D. Le Claire and G. Neumann, "Diffusion of impurities in solid metallic elements", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 85-212.

G. Neumann and C. Tuijn, Self-diffusion and impurity diffusion in pure metals : Handbook of experimental data, Elsevier, 2009.

P.110 掲載の参考文献

16) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「固体拡散中の相関」, 丸善出版, 2012, pp. 111-32.

小岩昌宏, 中嶋英雄著, 材料における拡散-格子上のランダム・ウォーク, 「相関における相関効果」, 「ランダム・ウオーク理論の基礎」, 内田老鶴圃, 2009, pp. 113-145.

P.112 掲載の参考文献

19) K. Compaan, Y. Haven, Trans. Faraday Soc., 52 (1956) 786.

P.119 掲載の参考文献

32) A. Lidiard, Phil. Mag., 46 (1955) 1218.

33) A. D. LeClaire, J. Nucl. Mater., 69-70 (1978) 70.

P.120 掲載の参考文献

35) A. D. LeClaire, J. Nucl. Mater., 69&70 (1978) 70-96.

36) E. T. Teatum, K. A. Gschneidner, Jr, J. T. Waber, "Compilation of calculated data useful in predicting metallurgical behavior of the elements in binary alloy systems", Los Alamos scientific laboratory of the University of California, Rep La-4003, 1968.

中嶋英雄, 小岩昌宏, 「チタンにおける拡散」, 日本金属学会会報, 30 (1991) 526-35.

P.121 掲載の参考文献

37) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「「隙間の広い」金属中の不純物拡散-解離機構」, 丸善出版, 2012, pp. 341-4.

小岩昌宏, 中嶋英雄, 材料における拡散-格子上のランダム・ウォーク, 「金属中での不純物高速拡散」, 内田老鶴圃, 2009, pp. 76-9.

中嶋英雄, 「鉛など2, 3の金属中での不純物の高速拡散」, 日本金属学会会報, 22 (1993), 480-7.

P.122 掲載の参考文献

38) W. K. Warburton, D. Turnbull, "Fast diffusion", Diffusion in solids : recent developments, ed. A. S. Nowick, J. J. Burton, Academic Press, 1975, Chap. 4, pp. 171-229.

P.123 掲載の参考文献

1) S. Kadkhodaei, A. Davariashtiyani, "Phonon-assisted diffusion in bcc phase of titanium and zirconium from first principles", Phys. Rev. Materials, 4 (2020) 043802.

2) L. Scotti, et al., "Non-classical interstitial sites and anomalous diffusion mechanism in hcp-titanium", Acta Mater., 177 (2019) 68-81.

3) L.-J. Zhang, et al., "On the abnormal fast diffusion of solute atoms in α-Ti : A first-principles investigation", J. Alloys compounds, 740 (2018) 156-66.

40) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「異常に高速な不純物拡散」, 2012, pp. 184-99.

41) H. Nakajima et al., "Diffusion in α-Ti and Zr", Mater. Trans. 44 (2003) 2-13.

42) A. D. LeClaire, J. Nucl. Mater., 69&70 (1978) 70-96.

P.124 掲載の参考文献

51) S. J. C. Rushbrook Williams, L. W. Barr, J. Nucl. Mater., 69&70 (1978) 556-8.

53) S. J. C. Rushbrook Williams, L. W. Barr, J. Nucl. Mater., 69&70 (1978) 556-8.

54) 小野正雄他5名, 「強い重力場におけるIn-Pb合金中の構成原子の沈降 : 実験およびシミュレーション」, 日本金属学会誌, 70 (2006) 511-516.

P.125 掲載の参考文献

56) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「拡散の同位体効果」, 丸善出版, 2012, pp. 157-66.

H. Mehrer, N. Stolica, "Mass and pressure dependence of diffusion in solid metals and alloys", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 574-629.

P.126 掲載の参考文献

62) N. L. Peterson, Diffusion in Solids, ed. A. Nowick, J. Burton, Academic Press, (1975), pp. 115-68.

P.127 掲載の参考文献

64) R. E. Howard, J. R. Manning, Phys. Rev., 154 (1967), 561.

66) F. C. Frank, D. Tunbull, Phys. Rev., 104 (1956), 617.

P.128 掲載の参考文献

2) Y. A. Du, et al., "Diffusion of hydrogen within idealized grains of bcc Fe : A kinetic Monte Carlo study", Phys. Rev. B, 86 (2012) 174110.

3) D. E. Jiang, E. A. Carter, "Diffusion of interstitial hydrogen into and through bcc Fe from first principles", Phys. Rev. B, 70 (2004) 064102.

4) J. Sanchez, et al., "Ab initio molecular dynamics simulation of hydrogen diffusion in α-iron", Phys. Rev. B, 81 (2010) 132102.

67) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「鉄における水素同位体の拡散」, 丸善出版, 2012, pp. 277-84.

68) 1) H. Kimizuka (君塚肇), et al., "Effect of temperature on fast hydrogen diffusion in iron : A path-integral quantum dynamics approach", Phys. Rev. B, 83 (2011) 094110.

69) J. P. Hirth, Met. Trans. A, 11A (1980) 861-869.

70) G. V. Kidson, "The diffusion of H, D, and T in solid metals", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 504-73.

H. H. Johnson, Met. Trans. A, 19A (1988) 2371.

P.130 掲載の参考文献

72) M. E. Glicksman, "Diffusion of H+ and D+ with trapping", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Sec. 16.3, pp. 273-79.

74) 山口正剛他3名, 「アルミニウムのポア内表面における水素解離吸着と表面エネルギー低下」, 軽金属, 68 (2018) 588-95.

P.131 掲載の参考文献

77) S. Taketomi (竹富紳也), et al., "Atomistic study of hydrogen distribution and diffusion around a {112} <111> edge dislocation in alpha iron", Acta Mater., 56 (2008) 3761-9.

P.132 掲載の参考文献

79) R. A. Oriani, "The diffusion and trapping of hydrogen in steel", Acta Met., 18 (1970) 147-157.

P.133 掲載の参考文献

80) L. S. Darken, R. P. Smith, Corrosion, 5 (1949) 1-16.

P.135 掲載の参考文献

2) W. A. Counts, et al., First-principles energies of hydrogen traps in α-Fe : Point defects, Acta Mater., 58 (2010) 4730-41.

83) P. Shewmon, Y. L. Shen, G. H. Shen, M. Meshii, Acta Met., 37 (1989) 1913.

84) H. G. Lee, J. Y. Lee, Acta Met., 32 (1984) 131-6.

85) 鈴木啓史, 「水素トラップ挙動」, 軽金属, 68 (2018), 581-7.

86) 1) S. K. Desai, et al., Atomistic mechanism of hydrogen trapping in bcc Fe-Y solid solution : A first principle study, Acta Mater., 58 (2010) 5363-9.

87) N. Birks, G. H. Meier, Introduction to high temperature oxidation of metals, E.Arnold, 1983, p. 95.

Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 丸善出版, 2012, p. 272-6.

海老原健一ら他3名, 「数値シミュレーションによるアルミニウムの水素昇温脱離曲線の解釈」, 軽金属, 68 (2018) 596-602.

藤原比呂ら他4名, 「Al-8%Zn-1%Mg合金における水素脱離挙動」, 軽金属, 69 (2019) 186-93.

E. J. Song, D.-W. Suh, H. K. D. H. Bhadeshia, "Theory for hydrogen desorption in ferritic steel", Computational Mat. Sci., 79 (2013) 36-44.

P.136 掲載の参考文献

88) R. Kirchheim, F. Sommer, G. Schluckebier, Acta Met., 30 (1982) 1059-68.

第4章濃度勾配下での拡散

P.139 掲載の参考文献

3) T. Okino, "New mathematical solution for analyzing interdiffusion problems", Mater. Trans., 52 (2011) 2220-7.

P.140 掲載の参考文献

4) Smithells Metals Ref. Book, 6th Ed., Burtterworth (1983).

5) A. Smigelskas and E. Kirkendall, Trans. AIME, 171 (1947) 130.

6) 中嶋英雄, 「Kirkendall効果の発見にまつわるエピソード」, マテリア, 34 (1995) 461.

中嶋英雄, 「研究の喜びと悲しみと-金属学者カーケンドルの3つの論文」, 科学朝日, (1996) 94.

H. Nakajima, "The discovery and acceptance of the Kirkendall effect : The result of a short research career", JOM, 49 (1997) 15-9.

P.141 掲載の参考文献

9) M. E. Glicksman, "Kirkendall effect", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 17, pp. 283-308.

10) L. C. Correa da Silva とR. Mehlの研究 (Trans. AIME, 191 (1951) 155).

11) L. Darken, Trans. AIME, 175 (1948) 184.

Seitz, Turnbull (eds.), Solid State Physics, vol. 10, Academic Press, New York, (1960), p. 71中のD. Lazarus.

P.142 掲載の参考文献

12) Brown粒子の運動理論-材料科学における拡散理論の新知見, 沖野隆久, エヌ・ティー・エス, 2017, p. 94, p. 96, p. 114.

T. Okino, "Ending of Darken equation and intrinsic diffusion concept", J. Mod. Phys., 4 (2013) 1350-3.

P.145 掲載の参考文献

15) G. T. Horne, R. F. Mehl, Trans. AIME, 203 (1955) 88-99.

16) R. W. Balluffi, Acta Met., 8 (1960) 871.

P.146 掲載の参考文献

17) S. Sridhar, "A commentary on "Diffusion, mobility and their interrelation through free energy in binary metallic systems," L. S. Darken : Trans. AIME, 1948, vol. 175, p. 184, Met. Mater. Trans. A, 41A (2010), 543-62.

19) C. P. Flynn, "The theory of diffusion fluxes", Point defects and diffusion, Clarendon, Oxford, 1972, Chap. 8, pp. 375-410.

P.147 掲載の参考文献

20) R. E. Howard, A. B. Lidard, Rep. Prog. Phys., 27 (1964) 162.

P.149 掲載の参考文献

23) L. Darken, R. Gurry, Physical Chemistry of Metals, McGraw-Hill, 1953, p. 240 or p. 331.

24) M. E. Glicksman, "Influence of solution ideality", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 18, pp. 309-22.

P.153 掲載の参考文献

28) N. Cabrera, F. Frank, Phil. Trans. Roy. Soc. London, 243 A (1951) 299.

29) J. Bardeen, C. Herring, Atom Movements, ASM, Metals, Park, OH, 1951.

P.154 掲載の参考文献

32) T. R. Anthony, "Atom currents generated by vacancy winds", Diffusion in solids : recent developments, ed. A. Nowick, J. Burton, Academic Press, 1975, Chap. 7, pp. 353-79.

33) J. R. Manning, "Diffusion when diffusion coefficient depending on position", Diffusion kinetics for atoms in crystals, D. Van Nostrand, 1968, Chap. 5, pp. 170-211.

C. P. Flynn, "The theory of diffusion fluxes", Point defects and diffusion, Clarendon Press, Oxford, 1972, Chap. 8, pp. 375-410.

C. P. Flynn, "Diffusion couples ; the Kirkendall effect", Point defects and diffusion, Clarendon Press, Oxford, 1972, Sec. 8. 3. 2, pp. 398-402.

P.155 掲載の参考文献

34) R. O. Meyer, Phys. Rev., 18 (1969) 1086.

35) D. J. Schmatz, H. Domian, H. I. Aaronson, J. Appl. Phys., 37 (1966) 1741-3.

36) N. R. Iorio, M. A. Dayananda, R. E. Grace, Met. Trans., 4 (1973) 1339-46.

37) T. Shimozaki, K. Ito and M. Onishi, Interdiffusivity and ratio of intrinsic diffusivities in Ag-Cd alloys, Trans. Japan Inst. Met., 28 (1987) 157.

38) G. E. Murch, C. M. Bruff, "Chemical diffusion in homogeneous binary alloys", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, p. 279.

39) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「合金における拡散多元系での拡散」, 丸善出版, 2012, pp. 246-59.

40) M. A. Dayananda, "Diffusion in ternary alloys", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 372-436.

41) M. E. Glicksman, "Multicomponent diffusion" and "Multicomponent diffusion : profiler program", Diffusion in solids : field theory, solid-state principles, and applications, John Wiley & Sons, 2000, Chap. 23 and Chap. 24, pp. 391-404 and pp. 405-418.

P.156 掲載の参考文献

43) L. Darken, Trans. AIME, 180 (1949) 430.

P.157 掲載の参考文献

44) L. S. Darken, "Diffusion in metal accompanied by phase change, Trans. A.I.M.E, 150 (1942), 157-70.

P.159 掲載の参考文献

47) C. E. Birchenall, Atom Movements, ASM, Metals Park, OH, (1951), p. 122.

48) R. P. Smith, Acta Met., 1 (1953) 578-87.

49) C. E. Birchenall, R. Mehl, Trans. AIME, 188 (1950) 144.

C. Wert, Phys. Rev., 79 (1950) 601.

P.160 掲載の参考文献

50) 西田恵三, 山本強, 永田卓雄, 「Fe中へのAl蒸気拡散に関する研究」, 日本金属学会誌, 34 (1970) 591-596.

T. Yamamoto, T. Takashima, K. Nishida, "Interdiffusion in the ζ-solid solution of a Ni-Al system", Trans. Japan Inst. Metals, 21 (1980) 601-608.

第5章非金属中の拡散

P.164 掲載の参考文献

7) H. メーラー著, 藤川辰一郎訳, 固体中の拡散, 丸善出版, 2012, p. 461.

P.169 掲載の参考文献

17) Handbuch der Physik, vol. 20, p. 246, Springer-Verlag, Berlin, (1957) 中のA. B. Lidiard.

18) A. S. Nowick, in Diffusion in Crystalline Solids, eds., G. E. Murch, A. S. Nowick, Academic Press (1984) p. 143-88.

20) Mapother, Crooks and Maurer, J. Phys., 18 (1950) 1231.

P.171 掲載の参考文献

21) V. C. Nelson, R. J. Friauf, J. Phys. Chem. Solids, 31 (1970) 825-43.

P.174 掲載の参考文献

26) L. W. Barr, A. B. Lidiard, "Defects in ionic crystals", Physical Chemistry : an advanced treatise, ed. W. Jost, Academic Press, 1970, Vol. 10, Solid State, p. 151.

27) M. Tosi, F. Fumi, L. W. Barr, A. B. Lidiard, "Defects in ionic crystals", Physical Chemistry : an advanced treatise, ed. W. Jost, Academic Press, 1970, Vol. 10, Solid State, p. 151. Lidiard.

P.175 掲載の参考文献

28) R. W. Dreyfus, A. S. Nowick, "Ionic conductivity of doped NaCl crystals", Phys. Rev., 126 (1962) 1367.

P.176 掲載の参考文献

30) A. S. Nowick "Atom transport in oxide of fluoride structure", Diffusion in crystalline solids, eds. G. E. Murch, A. S. Nowick, Academic Press, 1984, Chap. 3, pp. 143-188.

P.177 掲載の参考文献

32) J. Teltow, Ann. Physik, 5 (1949) 63.

33) J. Teltov, Ann. Physik. Leipzig, 5 (1949) 63.

P.178 掲載の参考文献

34) R. Friauf, Phys. Rev., 105 (1957) 843.

M. D. Weber, R. J. Friauf, J. Phys. Chem. Solids, 30 (1969) 407-19.

P.182 掲載の参考文献

39) R. J. Friauf, Phys. Rev., 105 (1957) 843.

P.184 掲載の参考文献

41) R. Freer, J. Mat. Sci., 15 (1980) 803-24.

42) 丸山俊夫, 「金属酸化物における拡散」, 金属学会セミナー・テキスト先端材料における拡散-基礎と応用, 金属学会, 2002, pp. 71-8.

P.186 掲載の参考文献

43) R. Dieckmann, Z. Physik. Chem. NF, 107 (1977) 189.

P.187 掲載の参考文献

47) R. Dieckmann, H. Schmalzried, Ber. Bunsenges. Phys. Chem., 81 (1977) (I) 344-7.

R. Dieckmann, H. Schmalzried, Ber. Bunsenges. Phys. Chem., 81 (1977) (II) 414-19.

P.188 掲載の参考文献

49) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「IV部半導体中の拡散, 第22章半導体についての解説, 第23章元素半導体中の自己拡散, 第24章シリコンおよびゲルマニウム中の不純物拡散, 第25章格子間サイト-格子サイト交換機構」, 丸善出版, 2012, pp. 393-458.

50) W. Frank, U.Gosele, H. Mehrer, A. Seeger, "Diffusion in silicon and germanium", Diffusion in crystalline solids, eds. G. E. Murch, A. S. Nowick, Academic Press, 1984, Chap. 2, pp. 63-142.

51) T. Sudkamp, H. Bracht, "Self-diffusion in crystalline silicon : A single diffusion activation enthalpy down to 755℃", Phys. Rev. B, 94 (2016) 125208.

T. Y. Tan, U. Gosele, "Diffusion in semiconducors", P. Heitjans, J. Karger, Diffusion in Condensed Matter-Methods, Materials, Models, Springer, 2005, pp. 165-208.

S. Mu. Hu, "Diffusion in silicon and germanium", Atomic diffusion in semiconductors, ed. D. Shaw, Plenum, 1973, Chap. 5, pp. 217-350.

P.189 掲載の参考文献

53) H. Bracht, E. E. Haller, R. Clark-Phelps, "Silicon self-diffusion in isotope heterostructures", Phys. Rev. Lett., 81 (1998) 393-6.

54) N. A. Stolwijk, H. Bracht, "Diffusion in silicon, germanium and their alloys", in : Diffusion in Semicoductors and Non-Metallic Solids, D. L. Beke (vol. Ed.), Landolt-Bornstein, New Series, Group III, Vol. 33, Subvolume A, Springer, Berlin, 1998.

Y. Shimizu, M. Uematsu, K. M. Itoh, "Experimental evidence of the vacancy-mediated silicon self-diffusion in single-crystalline silicon", Phys. Lev. Lett., 98 (2007) 095901 1-4.

D. J. Fisher, ed., Diffusion in silicon, 10 years of research, Sci. Pub., 1989, 全560頁.

E. N. Sgouurou, et al., "Diffusion and dopant activation in germanium : Insights from recent experimental and theoretical results", Appl. Sci., 9 (2019), 254, 全14頁.

P.192 掲載の参考文献

57) D. A. Antoniadis, I. Moskowitz, "Diffusion of substitutional impurities in silicon at short oxidation times : An insight into point defect kinetics", J. Appl. Phys., 53 (1982) 6788-96.

P.193 掲載の参考文献

59) U. Gosele, W. Frank, A. Seeger, Appl. Phys. A, 23 (1980) 361.

P.197 掲載の参考文献

69) 植松真司, 「半導体おける拡散」, 金属学会セミナー・テキスト先端材料における拡散-基礎と応用, 日本金属学会, 2002, pp. 41-9.

K. Tsutsui, Y. Morikawa, "Analyses of three-dimensional atomic arrangements of impurities doped in Si relating to electrical activity by spectro-photoelectron holography", Jpn. J. Appl. Phys., 59 (2020) 010503.

P.198 掲載の参考文献

70) H Bakker, Diffusion in Crystalline Solids, ed. G. E. Murch, A. S. Nowick, Academic Press, 1984, pp. 189-258.

71) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「二元金属間化合物中の拡散」, 丸善出版, 2012, pp. 349-78.

73) J. P. Neumann, Acta Met., 28 (1980) 1165-70.

Th. ホイマン著, H メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 「合金における拡散, 金属間化合物相」, 丸善出版, 2012, pp. 239-46.

沼倉宏, 「金属化合物における拡散」, 金属学会セミナー・テキスト先端材料における拡散-基礎と応用, 日本金属学会, 2002, 59-70.

H. Bakker, "Self-diffusion in homogeneous binary alloys and intermediate phases", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, pp. 213-278.

H. Bakker, et al, in Atomic transport in alloys : recent development, eds. G. E. Murch, M. A. Dayananda, TMS/AIME, 1985, pp. 39-66.

P.199 掲載の参考文献

77) H. Hahn, G. Frohberg, H. Wever, Phys. Stat. Sol. (a), 79 (1983) 559-65.

P.201 掲載の参考文献

80) A. Kuper, D. Lazarus, J. R. Manning, C. T. Tomizuka, Phys. Rev., 104 (1956) 1536.

P.202 掲載の参考文献

82) N. Prinz, H. Werner, Phys. Stat. Solidi A, 61 (1980) 505. Bakker.

P.205 掲載の参考文献

84) K. Becker, H. Schmalzried, V. Wurmb, Solid State Ionics, 11 (1983) 213-9.

85) 早藤貴範, 「Si中の不純物の挙動とゲッタリング」, 応用物理 60 (1991) 782-9.

第6章高速拡散路

P.207 掲載の参考文献

1) D. Turnbull, in Atom Movements, ASM, Cleveland, 1951, p. 129.

P.209 掲載の参考文献

6) J. Fisher, J. Appl. Phys., 22 (1951) 74.

7) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「粒界拡散」, 丸善出版, 2012, pp. 569-98.

Th. ホイマン著, H. メーラー協力, 藤川辰一郎, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 粒界拡散, 転位拡散, 表面拡散」, 2012, pp. 299-346.

chr. Herzig, Y. Mishin, "Grain Boundary Diffusion in Metals", Diffusion in condensed matter : methods, materials, models, ed. P. Heitjans, J. Karger, Springer, 2005, p. 337.

I. Kaur, Y. Mishin, W. Gust, Fundametals of Grain and Interphase Boundary Diffusion, Wiley, Chichester WestSussex, 1995.

P.211 掲載の参考文献

11) R. T. Sibbatov, "Anomalous grain boundary diffusion : Fractional calculus approach", Advances in Mathematical Physics, (2019) Article ID 8017363, p. 9.

P.212 掲載の参考文献

13) R. T. Whipple, Phil. Mag., 45 (1954) 1225.

14) H. Levine, C. MacCallum, J. Appl. Phys., 31 (1960) 595.

15) N. L. Peterson, in Grain boundary Structure and Kinetics, ASM, Metals Park, OH (1980), pp. 209-37.

17) R. T. Whipple, Phil. Mag., 45 (1954) 1225.

P.214 掲載の参考文献

22) T. Suzuoka, J. Phys. Soc. Japan, 19 (1964) 839.

23) D. Gupta, J. Appl. Phys., 44 (1973) 4455.

P.215 掲載の参考文献

24) R. W. Balluffi, in Diffusion in Crystalline Solids, ed. G. E. Murch, A. S. Nowick, Academic Press, 1984, p. 320-78.

25) 石田洋一, 「結晶粒界の構造と粒界の移動特性」, 鉄と鋼, 70 (1984) 1819-27.

石田洋一, 「結晶粒界の微細構造」, 日本金属学会会報, 9 (1974) 156-68.

P.216 掲載の参考文献

26) N. L. Peterson, in Grain Boundary Structure and Kinetics, ASM Metals Park, OH, 1980, pp. 209-37.

29) D. Turnbull, R. Hoffman, Acta Met., 2 (1954) 419.

30) R. Hoffman, Acta Met., 4 (1956) 98.

G. Martin, B. Perraillon, in Grain Boundary Structure and Kinetics, ASM Metals Park, OH, 1980, pp. 239-95.

P.218 掲載の参考文献

31) I. Herbeuval, M. Biscondi, C. Goux, Mem. Sci. Rev. Met., 70 (1973) 39.

33) I. Kauer, W. Gust, "Grain and interphase boundary diffusion", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 630-716.

P.219 掲載の参考文献

34) N. Gjostein, "Short circuit diffusion", Diffusion, ASM, Metals Park, OH, 1973, Chap. 9, pp. 241-74.

P.220 掲載の参考文献

35) R. W. Balluffi, "Grain boundary diffusion mechanism in metals", Diffusion in crystalline solids, eds. G. E. Murch, A. S. Nowick, Academic Press, 1984, Chap. 6, pp. 318-377.

36) S. Starikov, et al., "Study of grain boundary self-diffusion in iron wihth different atomistic models", Acta Mater., 188 (2020) 560-9.

37) G. Martin, D. A. Blackburn, Y. Adda, Phys. Status Solidi, 23 (1967) 223.

P.222 掲載の参考文献

38) A. Restrepo, et al., "Carbon diffusion paths and segregation at high-angle tilt grain boudaries in α-Fe studied by using a kinetic activation-relation technique", Phys. Rev. B, 97 (2018) 054309.

39) H. メーラー著, 藤川辰一郎訳, 固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程, 「転位パイプ拡散」, 丸善出版, 2012, pp. 599-607.

40) A. D. Le Claire, "Diffusion in dislocations", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 626-9.

41) A. D. Le Claire, A. Rabinovitch, in Diffusion in Crystalline Solids, ed. G. Murch, A. Nowick, Academic Press, 1984, pp. 259-319.

42) D. Gupta, D. R. Campbell, P. S. Ho, in Thin Films-Interdiffusion and Reactions, eds. Poate, Tu & Mayer, J. Wiley & Sons, 1978, pp. 161-242.

43) A. D. Le Claire, A. Rabinovitch, "A mathematical analysis of diffusion in dislocations. I. Application to concentration tails", J. Phys. C14 Solid State Physics (1981) 3863.

A. D. Le Claire, A. Rabinovitch, "A mathematical analysis of diffusion in dislocations. II. Influence at low densities on measured diffusion coefficients, J. Phys. C15 Solid State Physics (1982) 5727.

A. D. Le Claire, A. Rabinovitch, "A mathematical analysis of diffusion in dislocations. III. Diffusion in a dislocation array with diffusion zone overlap", J. Phys. C16 Solid State Physics (1983) 2087.

A. D. Le Claire, A. Rabinovitch, "A mathematical analysis of diffusion in dislocations. IV. Diffusion-controlled absorption or desorption for solid containing dislocations", J. Phys. C17 Solid State Physics (1984) 991.

A. D. Le Claire, A. Rabinovitch, "A mathematical analysis of diffusion in dislocations. A. D. Le Claire, A. Rabinovitch, "The mathematical analysis of diffusion in dislocations", Diffusion in crystalline solids, eds. G. E. Murch, A. S. Nowick, Academic Press, 1984, Chap. 5, pp. 257-318.

P.223 掲載の参考文献

45) L. J. Wirth, et al., "Density functional study of self-diffusion along an isolated screw dislocation in fcc Ni", Phys. Rev. Mater., 3 (2019) 033605.

P.224 掲載の参考文献

50) E. Hart, Acta Met., 5 (1957) 597.

P.226 掲載の参考文献

53) Y. K. Ho, Thesis, Imperial College, London, 1982.

P.227 掲載の参考文献

55) P. Shewmon, "Diffusion induced grain-boundary migration-DIGM, Defect and Diffusion Forum, 66-69 (1989) 727-34.

56) E. Sebastian M, K. Michael, G. Andrij, S. Guido, "On the mechanism of diffusion-induced recrystallizaion : Comparison between experiment and molecular dynamics simulations", Acta Mater., 60 (2012) 3469-79.

57) I. Kaur, Y. Mishin, W. Gust, "Diffusion along migrating grain boudaris", Fundamentals of grain and interphase boundary diffusion, John Wiley & Sons, 1995, pp. 303-377.

J. Sommer, Y. M. Chiang, R. W. Balluffi, "Diffusion induced grain boudary migration at low temperatures and its effect on measuring chemical grain boundary diffusivities", Scripta Meta. Mater., 33 (1995) 7-12.

P.228 掲載の参考文献

58) M. Hillert, G. Purdy, Acta. Met., 26 (1978) 333.

59) P. G. Shewmon, G. Meyrick, in Interface Migration & Control of Microstructure, ASM, 1985, pp. 7-17.

P.229 掲載の参考文献

60) D. L. Beke, et al., "Interdiffusion along grain boundaries-Diffusion induced grain boundary migration, low temperature homogenization and reactions in nanostructured thin films", Progress in Materials Science, Vol. 98, pp. 625-74, 2018.

61) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散, 理論, 現象, 「粒界拡散, 転位拡散及び表面拡散, 9.3 表面拡散」, 丸善出版, 2012, pp. 338-46.

R. B. Ananya, et al., "Phase-field model for diffusion-induced grain boundary migration : An application to battery electrodes", Phys. Rev. Mater., 3 (2019) 065404.

L. Volpe, "Understanding the role of diffusion induced grain boundary migration on the prefential inter granular oxidation behaviour of alloy 600 via advanced microstructural characterization, Acta Mater., 179 (2019) 238-49.

P.230 掲載の参考文献

63) W. W. Mullins, "Solid Surface Morphologies Governed by Capillarity," Metal Surfaces, ASM, Metals Park OH, 1963, pp. 17-66.

P.232 掲載の参考文献

67) N. A. Gjostein, Techniques of Metals Research, ed. R. Bunshah, Interscience Publ., 1970, vol. IV part 2, pp. 405-57.

P.233 掲載の参考文献

73) Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 金属における拡散-純金属および合金における拡散の基礎, 理論, 現象, 丸善出版, 2012, p. 56.

M. D. Geenberg, J. N. Pryor, L. Elban, "On the formulation of the zero creep method for small diameter wires", Mat. Sci. Eng., 33 (1978) 63-67.

P.234 掲載の参考文献

75) W. Nix, Metals Forum, 4 (1981) 38-43.

P.235 掲載の参考文献

76) C. Herring, J. Appl. Phys., 21 (1950) 301.

77) G. Antczak and G. Ehrlich, Surface Diffusion-Metals, Metal Atoms, and Clusters, Cambridge University Press, 2010.

P.236 掲載の参考文献

82) F. A. Nichols, W. W. Mullins, J. Appl. Phys., 36 (l965) 1826.

P.237 掲載の参考文献

83) H. P. Bonzel, "Surface diffusion on metals", Landolt-Bornstein, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, pp. 717-47.

P.239 掲載の参考文献

86) Vu Thien Binh, P. Melinon, Surf. Sci., 161 (1985) 234-44.

87) A. P. Voter, J. D. Doll, J. Chem. Phys., 82 (1985) 80-92.

P.241 掲載の参考文献

89) G. Ehrlich, K. Stolt, Ann. Rev. Phys. Chem., 31 (1980) 603-37.

P.242 掲載の参考文献

91) F. Delamare, G. E. Rhead, Surf. Sci., 28 (1971) 267.

第7章固体中のサーモトランスポートおよびエレクトロトランスポート

P.247 掲載の参考文献

4) H. B. Huntington, "Electromigration in metals", Diffusion in solids : recent developments, eds. A. S. Nowick, J. J. Burton, Academic Press, 1975, Chap. 6, pp. 303-52.

5) Hans Wever, Elektrou. Thermotransport in Metallen, J. A. Barth, Leipzig (1973) (ドイツ語)

P.248 掲載の参考文献

7) J. Philibert, "Electromigration in substitutional binary alloy", Atom movements : diffusion and mass transport in solids, Les Editions de Physique, 1991, Sec. III4, pp. 320-25.

P.249 掲載の参考文献

10) H. Weber in Electro-transport in Metals and Alloy, ed. R. E. Hummel, H. B. Huntington, AIME, New York, 1977, pp. 37-52.

P.250 掲載の参考文献

13) D. T. Carlson, in Electro- and Thermo-transport in Metals and Alloys, ed. R. E. Hummel, H. B. Huntington, AIME, New York, 1977, pp. 54-67.

P.251 掲載の参考文献

14) R. A. Oriani, O. D. Gonzales, Met. Trans., 1 (1967) 1041.

17) H. B. Huntigton, "Electro-and thermomigration in metals", Diffusion, ed., H. I. Aaronson, Ameican Society for Metals, 1973, Chap. 6, pp. 155-184.

P.252 掲載の参考文献

18) H. B. Huntington, "Electromigration in metals", Diffusion in solids : recent developments, eds. A. S. Nowick, J. J. Burton, Adademic Press, 1975, Chap. 6, pp. 303-52.

P.254 掲載の参考文献

21) Choong-Un Kim, Electromigration in thin films and electronic devices : materials and realiability, Woodhead Publising, 2011, 全352頁.

P.255 掲載の参考文献

25) 岡林秀和, 「LSIにおけるエレクトロマイグレーション」, 金属学会セミナー・テキスト先端材料における拡散-基礎と応用, 金属学会, 2002, pp. 79-86.

P.256 掲載の参考文献

26) P. Shewmon, Acta Met., 8 (1960) 606.

P.258 掲載の参考文献

28) K. G. Denbigh, The Thermodynamics of the steady State, Methuen & Co., (1951).

P.259 掲載の参考文献

30) K. Wirtz, Phys. Z, 44 (1943) 221.

P.262 掲載の参考文献

32) A. Sawatzky, J. Nucl. Mater., 2 (1960) 450.

P.263 掲載の参考文献

33) P. G. Shewmon, Trans. AIME, 212 (1958) 642.

34) Mehmet Uz, D. K. Rehbein, O. N. Carson, Met. Trans. A, 17A (1986) 1955-66.

P.265 掲載の参考文献

2) A. B. Lidiard, "An essay on the heat of transport in solids and partial guide to the literature", Diffusion Foundations, vol. 4, 57-68, ed. I. V. Belova, et al.,

3) P. Schelling, et al., "Molecular-dynamics calculation of the vacancy heat of transport", J. Appl. Phys., 116 (2014) 023506.

4) R. R. Mohanty, et al., J. Appl. Phys., 106 (2009) 034912.

5) S.-I. Fujikawa, et al., "Thermomigration of zinc in aluminum and Al-Zn alloy", Defect Diff. Forum, 143-147 (1997) 1693.

35) 1) D. Jaffe, P. G. Shewmon, "Thermal diffusion of substitutional impurities in copper, gold and silver", Acta Metall., 12 (1964) 515-27.

付表代表的な金属中の各種元素の拡散データ

P.271 掲載の参考文献

1. Y. Minamino, S. Saji, K. Hirao, K. Ogawa, H. Araki, Y. Miyamoto, T. Yamane : Mater. Trans. JIM., 37 (1996) 130-7.

2. Z. T. Fujita, Z. Horita, T. G. Langdon, Mat. Sci. Eng. A, 371 (2004) 241-50.

3. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

4. Landolt-Bornstein, vol. 26, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Condensed Matter, vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, p. 60, p. 151.

5. Smithells metals reference book, seventh edition, Eds. E. A. Brandes, G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

6. 藤川辰一郎, 軽金属, 60 (2010), 314.

7. H. メーラー, 藤川辰一郎, 「固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程」, 丸善出版, 2012, p. 340, p. 640.

8. 藤川辰一郎, 新版アルミニウム技術便覧, 軽金属協会編, カロス出版, 1996, p. 1275.

9. G. Erdelyi, Philos. Mag. B, 38 (1978) 445-462.

10. S.-I. Fujikawa, Defect Diffus. Forum, 143-147 (1997) 115-20.

11. J. Chengzhou, N. Xiaguang, W. Anmin, Y. Jianjua, Surf. Coat. Tech., 66 (1994) 240-4.

12. M. Beyeler, Y. Adda, J. Physique, 29 (1968) 345.

13. S. Dais, R. Messer, A. Seeger, Mater. Sci. Forum, 15-18 (1987) 419.

14. N. L. Peterson, S. J. Rothman, Phys. Rev. B, 1 (1970) 3264.

15. W. B. Alexander, L. M. Slifkin, Phys. Rev. B, 1 (1970) 3274.

16. S. Fujikawa, K.-I. Hirano, Trans. JIM, 12 (1971), 434-41.

17. G. Rummel, Th. Zumkley, M. Eggersmann, K. Freitag, H. Mehrer, Z. Metallk., 86 (1995) 122.

18. Y. Minamino, T. Yamane, Sh. Nakagawa, H. Araki, K. Hirao, J. Japan Inst. Light Metals, 37 (1987) 72.

19. G. M. Hood, R. J. Schultz, J. Armstrong, Phil. Mag. A, 47 (1983) 775.

20. S. Fujikawa, K. Hirano, Defect and Diffusion Forum, 66-69 (1989) 447.

21. G. M. Hood, Phil. Mag., 21 (1970) 305.

22. Y. Minamino, T. Yasuda, H. Araki,d T. Yamane, Defect and Diffusion Forum, 66-69 (1989) 1251.

24. A. Thurer, G. Rummel, Th. Zumkley, K. Freitag, H. Mehrer, Phys. Stat. Sol., (a) 149 (1995) 535.

25. F. Sawayanagi, R. R. Hasiguti, J. Japan Inst. Metals, 42 (1978) 1155.

26. G. M. Hood, R. J. Schultz, Phys. Rev. B, 4 (1971) 2339.

27. Ch. Khoukaz, H. Mehrer, Z. Metallk., 91 (2000) 888.

28. C. Moreau, A. Alloche, J. Knystautas, J. Appl. Phys., 58 (1985) 4582.

29. Y. Minamino, T. Yamane, H. Araki, Metall Trans., 18A (1987) 1535.

30. S. J. Rothman, N. L. Peterson, L. J. Nowicki, L. C. Robinson, Phys. Stat. Sol., (b) 63 (1974) K29.

31. Y. Minamino, T. Yamane, A. Shimomura, M. Shimada, M. Koizumi, N. Ogawa, J. Takahashi, H. Kimura, J. Mat. Sci., 18 (1983) 2679.

32. S.-I. Fujikawa, Y. Takada, Defect Diffusion Forum, 143-147 (1997) 409.

33. S. Fujikawa, K. Hirano, Mater. Sci. Eng., 27 (1977) 25.

34. S. Fujikawa, K. Hirano, Mat. Sci. Forum, 13-14 (1987) 539.

35. N. van Chi, D. Bergner, in DIMETA-82 : Diffusion in Metals and Alloys, ed. by F. J. Kedves, D. L. Beke, Trans Tech Publicaitons, Switzerland, 1983, p. 334.

36. G. M. Hood, R. J. Schultz, Phil. Mag., 23 (1971) 1479.

37. S. Sudar, J. Csikai, M. Buczko, Z. Metallkd., 68 (1977) 740.

38. N. Scapellato. M. Uhrmacher, K. P. Lieb, J. Phys. F : Met. Phys., 18 (1988) 677.

39. Ch. Khoukaz, H. Mehrer, Z. Metallk., 91 (2000) 888.

40. S.-I. Fujikawa, K.-I. Hirano, Y. Fukushima, Met. Trans. A, 9A (1978) 1811.

41. S. Badrinarayanan, H. B. Mathur, Int. J. Appl. Radiat. Isot., 19 (1968) 353.

42. G. Erdelyi, K. Freitag, G. Rummel, H. Mehrer, "Volume and grain boundary diffusion of implanted 113Sn in aluminum", Appl. Phys. A, 53 (1991) 297-302.

43. J. J. Blechet, A. Van Craeynest, D. Calais, J. Nucl. Mater., 27 (1968) 112.

44. J. Chengzhou, N. Xiaoguang, W. Anmin, Y. Jianhua, Surface Coating Tech., 66 (1994), 240-4.

45. S. Fujikawa, K.-I. Hirano, Trans. JIM., 17 (1976) 809.

46. T. Marumo, S. Fujikawa, K. Hirano, J. Japan Inst. Light Metals, 23 (1973) 17.

47. K. Hirano, S. Fujikawa, J. Nucl. Mater., 69&70 (1978) 564.

48. G. A. Young, Jr., J. R. Scully. Acta Matter, 46 (1998) 6337.

49. N. van Chi, Neue Hutte, 23 (1978) 147.

50. G. Erdelyi, D. L Beke, F. J. Kedves, I. Godeny, Phil. Mag. B, 38 (1978) 445.

51. S.-I. Fujikawa, Defect Diffus. Forum, 143-147 (1997) 115-20.

52. W. Zhong, M. S. Hooshmand, M. Ghazisaeidi, W. Windl, J.-C. Zhao, "An inegrated experimental and computational study od diffusion and atomic mobility of the aluminum-magnesium sysem", Acta Mater., 189 (2020) 214-31.

53. R. Shi, Z. Zhu, A. A. Luo, "Assessing phase equilibria and atomic mobility of intermetallic compounds in aluminum-magnesium alloy system", J. Alloys and Compounds, 825 (2020),153962.

54. W. Zhong, M. S. Hooshmand, M. Ghazisaeidi, W. Windl, "An integrated and computational study of diffusion and atomic mobility of the aluminum-magnesium system", Acta Mater., 189 (2020), 214-31.

55. J. M. Pauls, C. E. Shuck, A. Gen, S. Rouvimov, A. S. Mukasyan, "In-situ transmission electron microscopy determination of solid-state diffusion in the aluminiumnickel system", J. Solid State Chemistry, 276 (2019) 114-21.

56. J. M. Pauls, C. E. Shuk, A. Gen, c, S. Rouvimov, A. S. Mukasyan, "In-situ transmission electron microscopy determination of solid-state diffusion in the aluminum-nickel system", J. Solid State Chem., 276 (2019) 114-21.

57. D. Connetable, M. David, "Diffusion of interstitial species (H and O atoms) in fcc systems (Al, Cu, Co, Ni and Pd) : Contribution of first and second order transition states", J. Alloys and Compounds, 772 (2019) 280-7.

58. J. Wang, S. Shin, A. Y. Nobakht, A. Shyam, "Structural deformation and transformation of θ'-Al2Cu precipitate in Al matrix via iterfacial diffusion", Computational Mater. Sci., 156 (2019) 111-20.

59. I. V. Zoryab, D. V. Novoselova, M. D. Starostenkova, G. M. Poletaeva, Molecular dynamics simulation of hydrogen atom diffusion in crystal lattice of fcc metals, Int. J. Mater. Res., 108 (2017) 4.*

60. G. M. Poletaev, I. V. Zorya, D. V. Novoselva, M. D. Starostenkov, "Molecular dynamics simulation of hydrogen atom diffusion in crystal lattice of fcc metals", Int. J. Mater. Res. (formally Z. Metallkd.), 108 (2017) 785-90.

61. M. David, D. Connetable, "Diffusion of interstitials in metallic systems, illustration of a complex study case : aluminum", J. Phys. : Condens. Matter, 29 (2017), 455703.

62. Y. Tang, L. Zhang, Y. Du, "Diffusivities in liquid and fcc Al-Mg-Si alloys and their application to the simulation of solidification and dissolution processes", CALPHAD : Computer Coupling of Phase Diagrams and Thermochemistry, 49 (2015) 58-66. (計算結果を訳者による"Tracer diffusion of magnesium in pseudo-binary Al-Mg2Si alloy, Defect Diff. Forum, 143-147 (1997) 403-8" の実験結果と比較した).

63. A. J. Ross, H. Z. Fang, S. L. Shang, G. Lindwall, Z. K. Liu, "A curved pathway for oxygen interstial diffusion in aluminum", Computational Mater. Sci., 140 (2017) 47-54.

64. H. Wu, T. Mayaeshiba, D. Morgan, "High-throughput ab-initio dilute solute diffusion database", Sci. Data 3, Article number : 160054 (2016).

65. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang, Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.

66. J. V. Pearce, "Survey of key parameter of impurities in aluminum : Diffusion coefficients, solubility, and liquidus slopes", Int.J. Thermophysics, 37 (2016) Article number : 123.

67. M. A. Kerkove, T. D. Wood, P. G. Sanders, S. L. Kampe, D. Swenson, "The diffusion coefficient of scandium in dilute aluminum-scandium alloys", Metall. Mater. Trans. A, 45 (2014) 3800-05.

68. M. A. Kerkove, T. D. Wood, P. G. Sanders, S. L. Kampe, D. Swenson, "The diffusion coefficient of scandium in dilute aluminium-scandium alloys", Met. Mater. Trans. A, 45 (2014) 3800-5.

69. G. Stechauner, E. Kozeschnik, "Assessment of substitutional self-diffusion along short-circuit paths in Al, Fe and Ni", Calphad, 47 (2014) 92-9.

70. O. M. Lovvik, E. Sagvolden, Y. J. Li, "Prediction of solute diffusivity in Al assisted by first-principles molecular dynamics", J. Phys. : Condens. Matter, 26 (2014) 025403.

71. D. Liu, L. Zhang, Y. Du, S. Cui, W. Jie, Z. Jin, "Development of an atomic mobility database for disordered and ordered fcc phases in multicomponent Al alloys : focusing on binary systems", Int. J. Mater. Res., (formerly Z. Metallkd.) 104 (2013) 135-48.

72. K. N. Kulkarni, A. A. Luo, "Interdiffusion and phase growth kinetics in magnesiumaluminum binary system", JPDAV, 34 (2013) 104-15.

73. F. Kargl, H. Weiss, T. Unruh, A. Meyer, "Self-diffusion in liquid aluminum", J. Phy. : Conf. Ser., 340 (2012) 012077.

74. M. Mantina, Y. Wang, R. Arroyave, S. L. Shang, L. Q. Chen, Z. K. Liu, "A firstprinciples approach to transition states of diffusion", J. Phys. : Condens. Matter, 24 (2012) 305402.

75. C. E. Campbell, A. L. Rukhin, "Evaluation of self-diffusion data using weighted means statistics", Acata Mater., 59 (2011) 5194-201.

76. Y. Du, L. Zhang, S. Cui,D. D. Zhao, D.Liu, W. Zhang, W. Sun, W. Jie, "Atomic mobilities and diffusivities in Al alloys", Sci. China Tech. Sci., 55 (2012) 306-28.

77. W. Zhang, Y. Du, D. Zhao, L. Zhang, H. Xu, S. Liu, Y. Li, S. Liang, "Assessment of the atomic mobility in fcc Al-Cu-Mg alloys", Calphad, 34 (2010) 286-93.

78. M. Mantina, Y. Wang, L. Q. Chen, Z. K. Liu, C. M. Wolverton, "First principles impurity diffusion coefficients", Acta Mater., 57 (2009) 4102-8.

79. M. Mantina, S. L. Shang, Y. Wang, L. Q. Chen, Z. K. Liu, "3d transition metal impurities in aluminum : A first-principles study", Phys. Rev. B, 80 (2009) 184111.

80. M. E. v. Dalen, R. A. Karnesky, J. R. Cabotaje, D. C. Dunand, D. Seidman, "Erbium and ytterbium solubilities and diffusivities in aluminum as determined by nanoscale characterization of precipitates", Acta Mater., 57 (2009) 4081-9.

81. M. Mantina, Y. Wang, R. Arroyave, L. Q. Chen, Z. K. Liu, "First-principles calculation of self-diffusion coefficients", Phys. Rev. Lett., 100 (2008) 215901.

82. N. Sandberg, R. Holmestad, "First-principles calculations of impurty diffusion activation energies in Al", Phys. Rev. B, 73 (2006) 014108.

83. F. Dyment, S. Balart, C. Lugo, R. A. Perez, N. D. Lalla, M. J. Iribarren, "Ru selfdiffusion and Ru diffusion in Al", Defect and Diffusion Forum, 237-240 (2005) 402-7.

84. A. Van der Ven, G. Ceder, "First principles calculation of the interdiffusion coefficient in binary alloys", Phys. Rev. Lett., 94 (2005) 045901.

85. T. Fujita, Z. Horita, T. G. Langdon, "Using grain bundary engineering to evaluate the diffusion characteristics in ultrafine-grained Al-Mg and Al-Zn alloys", Mater. Sci. Eng. A, 371 (2004) 241-50.

8b. 藤川辰一郎, 軽金属, 46 (1996) 202-215, 254-265.

8c. 藤川辰一郎, 「アルミニウム中の拡散」, アルミニウムおよびその合金中の微量元素と諸性質, 軽金属学会研究部会報告書 No. 9 (1983) pp. 1-16.

P.279 掲載の参考文献

1. 藤川辰一郎, 「マグネシウム合金の熱処理」, マグネシウム技術便覧, 日本マグネシウム協会編, カロス出版, 2000, pp. 131-6.

2. 藤川辰一郎, 「マグネシウムにおける拡散」, 軽金属, 42 (1992), 823-5.

3. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

4. Landolt-Bornstein, vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, p. 38, p. 93.

5. Smithells Metals Reference Book, Seventh edition, Ed. E. A. Brandes & G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

6. P. G. Shewmon and F. N. Rhines, Trans. Metall Soc. AIME, 250 (1954) 1021.

7. P. G. Shewmon, Trans. Metall Soc. AIME, 206 (1956), 918.

8. V. F. Yerko et al., Fiz. Met. Metalloved., 22 (1966) 112.

9. K. Lal et al., C. R. Acad. Sci. (Paris), C262 (1966) 107.

10. L. V. Pavlinov et al., Fiz. Met. Metalloved., 26 (1968) 823.

10. K. Lal, L'etude de la Diffusion de Quelques Elementss dans le Magnesium. Thesis, Univ. Paris, 1967.

11. J. Smolinski, "Electrolytic deposition and diffusion of lithium into magnesium", J. Appl. Chem., 6 (1956) 180-6.

12. M. S. Hooshmand, W. Zhong, J. C. Zhao, W. Windl, M. Ghazisaeidi, "Data on the comprehensive first-principles diffusion study of the alumininum-magnesium system", Data in Brief, 30 (2020) 105381.

13. Z. Zhou, Y. Gu, G. Xy, Y. Guo, Y. Cui, "Diffusion rearcd in HCP Mg-Al-Sn ternary alloys", Calphad, 68 (2020) 101710.

14. Z. Zhoua, Yu. Gua, G. Xua, Y. Guoa, Y. Cuia, "Diffusion research in HCP Mg-Al-Sn ternary alloys", CALPHAD : Computer Coupling of Phase Diagrams and Thermochemistry, 68 (2020) 101710.

15. W. Zhong, M. S. Hooshmand, M. Ghazisaeidi, W. Windl, J.-C. Zhao, "An inegrated experimental and computational study and diffusion and atomic mobility of the aluminum-magnesium sysem", Acta Mater., 189 (2020) 214-31.

16. R. Shi, Z. Zhu, A. A. Luo, "Assessing phase equilibria and atomic mobility of intermetallic compounds in aluminum-magnesium alloy system", J. Alloys and Compounds, 825 (2020) 153962.

17. W. Zhong, M. S. Hooshmand, M. Ghazisaeidi, W. Windl, "An integrated and computational study of diffusion and atomic mobility of the aluminum-magnesium system", Acta Mater., 189, (2020) 214-31.

18. J. Wang, W. Zheng, G. Xu, J. Llorca, Y. Cui, "High-throughput extraction of the anisotropic interdiffusion coefficients in hcp Mg-Al alloys", J. Alloys and Compounds, 805 (2019) 237-46.

19. Zhong, Wei, Zhao, Ji-Cheng, "Measurements of diffusion coefficients of Ce, Gd and Mn in Mg", Materialia, 7 (2019) 100353.

20. R. Agarwal, D. R. Trinkle, "Ab initio magnesium-solute transport database using exact diffusion theory", Acta Materialia, 150 (2018) 339-50.

21. W. Zhong and J.-C. Zhao, "First experimental measurement of calcium diffusion in magnesium using novel liquid-solid diffusion couples and forward-simulation analysis", Scripta. Mater., 127 (2017) 92-6.

22. R. Agarwal, D. R. Trinkle, "Exact model of vacancy-mediated solute transport in magnesium", Phys. Rev. Lett., 118 (2017) 105901.

23. W. Zhong, J.-C. Zhao, "First reliable diffusion coefficients for Mg-Y and additional reliable diffusion coefficients for Mg-Sn and Mg-Zn", Metall. Mater. Trans. A, 48A (2017) 5778-82.

24. A. A. Luo, J.-C. Zhao, A. Riggi,d W. Joost, "High-throughput study of diffusion and phase transformation kinetics of magnesium-based systems for automotive cast magnesium alloys", 2016, Ohio State University, Lightweight Materials, Project Final Report. 全17ページ. *

25. R. Agarwal, D. R. Trinkle, "Light-element diffusion in Mg using first-principles calculations : Anisotropy and elastodiffusion", Phys. Rev. B, 94 (2016) 054106.

26. B.-C. Zhou, S.-L Shang, Y. Wang, Z.-K. Liu, "Diffusion coefficients of alloying elements in dilute Mg alloys : A comprehensive first-principles study", Acta Mater., 103 (2016) 573-86.

27. C. C. Kammerer, N. S. Kulkarmi, B. Warmack, Y. H. Sohn, "Interdiffusion in ternary magnesium solid solutions of aluminum and zinc", J. Phase Equilibria and Diffusion, 37 (2016) 65-74.

28. H. Wu, T. Mayaeshiba, D. Morgan, "High-throughput ab-initio dilute solute diffusion database", Sci. Data 3, Article number : 160054 (2016).

29. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang, Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.

30. J. D. Robson, S. J. Haigh, V. Davis, D. Griffiths, "Grain boundary segregation of rare-earth elements in magnesium alloys", Met. Trans. A, 47A (2016) 522-30.

31. K. Klykin, M. G. Shelyapina, D. Fruchart, "DFT calculations of hydrogen diffusion and phase transformations in magnesium", J. Alloys and Compounds, 644 (2015) 371-7.

32. M. Paliwal, S. K. Das, J. Kim, I.-H. Jung, "Diffusion of Nd in hcp Mg and interdiffusion coefficients in Mg-Nd system", Scripta Mater., 108 (2015) 11-4.

33. B.-C. Zhou, S.-L. Shang, Y. Wang, Z.-L. Liu, "Data set for diffusio coefficients of alloying elements in dilute Mg alloys from first-principles", Data in Brief, 5 (2015) 900-12*.

34. Z. L. Bryan, P. Alieninov, I. S. Berglund, M. V. Manuel, "A diffusion mobility database for magnesium alloy development", Calphad, 48 (2015) 123-30.

35. S. K. Das, Y.-B. Kang, TK Ha and I.-H. Jung, "Thermodynamic modeling and diffusion kinetic experiments of binary Mg-Gd and Mg-Y systems", Acta Mater., 71 (2014) 164-75.

36. C. Kammerer, N. Kulkami, R. Warmack, K. Perry, I. Belova, G. Murch, "Impurity diffusion coefficients of Al and Zn in Mg determined from solid-to-solid diffusion couples", Magnesium Technology 2014, 505-09, Ed. M. Alderman et al., TMS.

37. S. K. Das, N. Brodusch, R. Gauvin, I.-H. Jung, "Grain boundary diffusion of Al in Mg", Scripta Mater., 80 (2014) 41-4.

38. S. K. Das, I.-H. Jung, "Effect of the basal plane orientation on Al and Zn diffusion in hcp Mg", Mater. Character., 94 (2014) 86-92.

39. S. K. Das, "Diffusion study of Mg-based alloys : an experimental and modeling approach", McGill University, Doctor of Philosophy, Thesis, 2014.*

40. S. K. Das, D.-H. Kang, I.-H. Jung, "Experimental and diffusion simulation for the homogenization of as-cast Mg-Al, Mg-Zn, and Mg-Al-Zn alloys", Met. Mater. Trans. A, 45 (2014) 5212-25.

41. S. K. Das, Y.-M. Kim, T. K. Ha, R. Gauvin, I.-H. Jung, "Anisotropic diffusion behavior of Al in Mg : Diffusion couple study using Mg single crystal", Metall. Mater. Trans. A, 44A (2013) 2539-47and Erratum to : this article, Metall. Mater. Trans. A, 44A (2013) 3420-2.*

42. S. K. Das, Y.-M. Kim, T. K. Ha, I.-H. Jung, "Investigation of anisotropic diffusion behavior of Zn in hcp Mg and interdiffusion coefficients of intermediate pahses in the Mg-Zn system", Calphad, 42 (2013) 51-8.

43. C. Kammerer, "Interdiffusion and impurity diffusion in magnesium solid solutions", University of Cetral Florida, Master Thesis, 2013. Electronic Theses and Dissertations, 2547. https://stars.library.ucf.edu/etd/2547*

44. S. Brennan, A. P. Warren, K. R. Coffey, N. Kulkarni, P. Todd, M. Klimov, Y. Sohn, "Aluminum impurity diffusion in magnesium", J. Phase Equilibria and Diffusion, 33 (2012) 121-5.

45. L. Huber, I. Elfimov, J. Rottler, M. Militzer, "Ab initio calculations of rare-earth diffusion in magnesium", Phys. Rev. B, 85 (2012) 144301.

46. J. E. Saal,d C. Wolverton, "Solute-vacancy binding of the rare earth in magnesium from first principles", Acta Mater., 60 (2012) 5151-9.

47. G. Ganeshan, L. G. Hecgtor Jr., Z.-K. Liu, "First-principles calculations of impurity diffusion coefficients in dilute Mg alloys using the 8-frequency Mg alloys using the 8-frequency model", Acta Mater., 59 (2011) 3214-28.

48. S. Brennan, AP. Warren, KR. Coffey, Y. Sohn, N. Kulkarni, P. Todd, "Impurity and tracer diffusion studies in magnesium and its alloys", Warrendale, PA : Minerals, Metals and Materials Society, 2010.

49. D. Shin, C. Wolverton, "First-principles study of solute-vacancy binding in magnesium", Acta Mater., 58 (2010) 531-40.

50. J. Ceemak, L. Kral, "Hydrogen diffusion in Mg-H and Mg-Ni-H alloys", Acta Mater., 56 (2008) 2677-86.

51. J. Cemak, I. Stloukal, Phys. Stat. Sol., (a) 203 (2006) 2386.

52. H. G. Schimmel, G. J. Kealey, J. Huot, F. M. Mulder, J. Alloys and Compounds, 404-406 (2005) 235-7.

53. I. Stloukal, J. Cermak, "Study of Ga volume and grain boundary diffusion in polycrystalline magnesium", Defect and diffusion Forum, 237-240 (2005) 1287-92.

54. J. F. Fernandez, C. R. Sanchez, "Rate determining step in the absorption and desorption of hydrogen by magnesium", J. Alloys. Comp., 340 (2002), 189-98.

55. H. Krimmel, M. Fahnle, "Ab initio calculation of the formation and migration enerugies for monovacies in Mg", Phys. Rev. B, 62 (2000) 5489.

2b. 藤川辰一郎, 軽金属, 42 (1992), 826-7.

11b. J. Combronde and G. Brebec, Acta Metall., 20 (1972) 37.

47b. D. Zhao, Y. Kong, A. Wang, L. Zhou, S. Cui, X. Yuan, L. Zhang, Y. Du, "Self-diffusion coefficient of fcc Mg : First-principles calculations and semi-empirical predictions", JPEDAV, 32 (2011) 128-37.*

P.285 掲載の参考文献

1. R. A. Perez, H. Nakajima and F. Dyment, "Diffusion in α-Ti and Zr", Mater. Trans., 44 (2003) 2-13.

2. H. Nakajima, M. Koiwa, "Diffusion in α-titanium", Defect and Diffusion Forum, 95-98 (1993) 775-82.

3. C. Herzig, Y. Mishin, S. Divinski, "Bulk and interface boundary diffusion in group IV hexagonal close-packed metals and alloys", Met. Mater. Trans. A, 33A (2002) 1-11.

4. 中嶋英雄, 小岩昌宏, 「チタンにおける拡散」, 日本金属学会会報, 30 (1991) 526-535.

5. H. Nakajima, M. Koiwa, "Diffusion in titanium", ISIJ Int. 31 (1991) 757-66.

6. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

7. Landolt-Bornstein, vol. 26, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Condensed Matter, vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, 60, 151.

8. Smithells metals reference book, seventh edition, Ed. E. A. Brandes & G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

9. M. Koppers, Chr. Herzig, M. Friesel, Y. Mishin, "Intrinsic self-diffusion and substitutional Al diffusion in α-Ti", Acta Mater., 45 (1997) 4181-91.

10. M. Koppers, D. Derdau, M. Friesel, Chr. Herzig, Defect and Diffusion Forum, 143-147 (1997) 43-48.

11. M. L. Mirassou, R. A. Perez, F. Dyment, Defect and Diffusion Forum, 143-147 (1997) 67-72.

12. R. A. Perez, M. Behar, F. Dyment, Phil. Mag. A, 75 (1997) 993-1004.

13. Chr. Minkwitz, Chr. Herzig, Defect and Diffuion Forum, 143-147 (1997) 61-6.

14. O. Taguchi, Y. Iijima, Phil. Mag. A, 72 (1995) 1649.

15. R. A. Perez, F. Dyment, Hj. Matzke, G. Linker, H. Dhers, J. Nucl. Mater., 217 (1994) 48-53.

16. R. A. Perez, F. Dyment, Phil. Mag., A, 71 (1995) 965-73.

17. J. H. R. dos Santos, P. F. P. Fichtner, M. Behar, R. Perez, F. Dyment, Appl. Phys. A, 58 (1994) 453-7.

18. R. A. Perez, F. Dyment, G. G. Bermudez, H. Somacal, D. Abriola, J. Nucl. Mater., 207 (1993) 221-7.

19. M. Behar, F. Dyment, R. A. Perez, J. H. R. dos Santos, R. L. Maltez, E. J. Savino, Phil. Mag. A, 63 (1991) 967.

20. H. Nakajima, K. Ogasawara, S. Yamaguchi, M. Koiwa, Mater. Trans. JIM, 31 (1990) 249-54.

21. Y. Nakamura, H. Nakajima, S. Ishioka, M. Koiwa, Acta Metall., 36 (1988) 2787-95.

22. H. Nakajima, J.-I. Nakazawa, Y. Minonishi, M. Koiwa, Phil. Mag. A, 53 (1986) 427.

23. H. Nakajima, S. Maekawa, Y. Aoki, M. Koiwa, Trans. Japan Inst. Metals, 26 (1985) 1-6.

24. H. Nakajima, S. Ishioka, M. Koiwa, Phil. Mag. A, 52 (1985) 743-51.

25. J. Raisanen, A. Anttila, J. Keinonen, J. Appl. Phys., 57 (1985) 613.

26. H. Nakajima, M. Koiwa, Y. Minonishi, S. Ono, Trans. Jpn. Inst. Met., 24 (1983) 655.

27. H. Nakajima, M. Koiwa, S. Ono, Scripta. Metall., 17 (1983) 1431-4.

28. H. Nakajima, M. Koiwa, Defect Diffusion Forum, 95-98 (1993) 775.

29. T. P. Papazoglou, M. T. Hepworth, Trans. Met. Soc. AIME, 242 (1968) 682-5.

30. S. Kadkhodaei, A. Davariashtiyani, "Phonon-assisted diffusion in bcc phase of titanium and zirconium from first principles", Phys. Rev. Materials, 4 (2020) 043802,

31. E. Eifano, G. Hug, "First-principle study of the solubility and diffusion of oxygen and boron in γ-TiAl", Computational Mater. Sci., 174 (2020) 109475.

32. A. Tripathi, K. C. Hari Kumar, K. N. Kulkarni, "Kinetic modeling of β-BCC phase in Ti-Al-Nb system in the temperature range of 1060-1200℃", Calphad, 68 (2020) 101725.

33. J. Zhou, Y. Xu, Z. Zhang, C. Gong, L. Xu, Y. Wang, W. Chen, "Interdiffusion and atomic mobility in the bcc Ti-rich Ti-Cr-Mn system", Calphad, 68 (2020) 101747.

34. F. Fan, Y. Gu, G. Xu, H. Chang, Y. Cui, "Diffusion research in bcc Ti-Al-Zr ternary alloys", J. Phase Equiilibria and Diffusion, 40 (2019) 686-96.

35. W. Bai, G. Xu, Z. Yang, L. Liu, L. Zhang, L. Zeng, D. Wu, "Diffusivities and atomic mobilities in bcc Ti-Nb-Ta alloys", Caphad, 65 (2019) 299-315.

36. L. Zhu, Z. Chen, W. Zhong, C. Wei, G. Cai, L. Jiang, Z. Jin, J.-C. Zhao, "Measurement of diffusion coefficients in the bcc phase of the Ti-Sn and Zr-Sn binary systems", Met. Mater. Trans. A, 50 (2019) 1409-20.

37. W. Bai, Y. Tian, G. Xu, Z. Yang, L. Liu, P. J. Masset, L. Zhang, "Diffusivities and atomic mobilities in bcc Ti-Zr-Nb alloys", Calphad, 64 (2019) 160-74.

38. S. Kadkhodaei, A. Davariashtiyani, "Phonon-assisted diffusion in bcc phase of titanium from first-principles", arXiv : 1910.05806

39. D. G. Sangiovanni 他6 人, "Superioniclike diffusion in an elemental crystal : bcc titanium", Phys. Rev. Lett., 123 (2019) 105501.

40. L. Scotti, N. Warnken, A. Mottura, "Non-classical interstitial sites and anomalous diffusion mechanisms in hcp-titanium", Acta Mater., 177 (2019) 68-81.

41. S.-Y. Ma, S.-Q. Wang, "The formation and anisotropic/isotropic diffusion behaviors of vacancy in typical twin boundaries of α-Ti : An ab initio study", Computational Mater. Sci., 159 (2019) 257-64.

42. L.-J. Zhang, Z.-Y. Chen, Q.-M. Hu, R. Yang, "On the abnormal fast diffusion of solute atoms in α-Ti : A first-principles investigation", J. Alloys and Compounds, 740 (2018) 156-66.

43. Z. Chen, Z.-K. Liu, J.-C. Zhao, "Exeprimental determination of impurity and interdiffusion coefficients in seven Ti and Zr binary systems using diffusion multiples", Met. Mater. Trans. A, 49A (2018) 3108-16.

44. Y. Gu, F. Fan, Y. Guo, G. Xu, H. Chang, L. Zhou, Y. Cui, "Diffusion and atomic mobility of BCT Ti-Al-Nb alloys : Experimental determination and computational modeling", Calphad, 62 (2018) 83-91.

45. G. Lindall, K.-W. Moon, Z. Chen, M. Mengason, M. E. Williams, J. M. Gorham, J.-C. Zhao, C. E. Campbell, "Diffusion in the Ti-Al-V system", J. Phase Equilib. Diffus., 39 (2018) 731-46.

46. Q. Wu, J. Wang, Y. Gu, Y. Guo, G. Xu, Y. Cui, "Experimental diffusion research on BCC Ti-Al-Sn ternary alloys", J. Phase Equilibria and Diffusion, 39 (2018) 724-30.

47. S. E. Kulkova, A. V. Bakulin, S. S. Kulkov, "First-principles calculations of oxygen diffusion in Ti-Al alloys", Latvian J. Phys. Tech. Sci., 2018, N6, 20-9.*

48. L. Zhu, Q. Zhang, Z. Chen, C. Wei, G.-M. Cai, L. Jiang, Z. Jin, J.-C. Zhao, "Measurement of interdiffusion and impurity diffusion coefficients in the bcc phase of the Ti-X (X = Cr, Hf, Mo, Nb, V, Zr) binary systems using diffusion multiples", J. Mater. Sci., 52 (2017) 3255-68.

49. L.-J. Zhang, T. I. Spiridonova, S. E. Kulkova, R. Yang, Q.-M. Hu, Computational Mater. Sci., 128 (2017) 236-242.

50. B. Gao, Y. Gu, Q. Wu, Y. Guo, Y. Cui, "Diffusion research in BCC Ti-Al-Ni ternary alloys", J. Phase Equilibria and Diffusion, 38 (2017) 502-8.

51. W. W. Xu, S. L. Shang, B. C. Zhou, Y. Wang, L. J. Chen, C. P. Wang, X. J. Liu, d Z. K. Liu, "A first-principles study of the diffusion coefficients of alloying elements in dilute α-Ti alloys", Phys. Chem. Chem. Phys., 18 (2016) 16870-81.

52. L. Scott, A. Mottura, "Interstitial diffusion of O, N, and C in α-Ti from firstprinciples : Analytical model and kinetic Monte Carlo simulations", J. Chem. Phys., 144 (2016) 084701.*

53. L. Scotti, "First-principles study of solute diffusion mechanisms in alpha-Ti", A thesis to the University of Birmingham for the degree of Doctor of Philosophy, 2016. 全211頁.*

54. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang, Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.

55. H. H. Wu, P. Wisesara, D. R. Trinkle, "Oxygen diffusion in hcp metals from first principles", Phys. Rev. B, 94 (2016) 014307.

56. L. Scotti, A. Mottura, "Diffusion anisotropy of poor metal solute atoms in hcp-Ti", J. Chem. Phys., 142 (2015) 204308.

57. N. Bernstein, A. Shabaev, S. G. Lambrakos, "First principles study of normal and fast diffusing metallic impurities in hcp titanium", Computational Mater. Sci., 109 (2015) 380-7.

58. J. L. Wang, L. B. Liu, B. Y. Tuo, W. M. Bai, X. Wang, X. Li, X. P. Hu, "Computational study of mobilities and diffusion in Ti-Sn alloy", J. Phase Equili. Diff., 36 (2015) 248-53.

59. Y. Chen, J. Li, B. Tang, H. Kou, J. Segrado, Y. Cui, "Computational study of atomic mobility for bcc phase in Ti-Al-Fe system", Calphad, 46 (2014) 205-12.

60. Y. Lu and P. Zhang, "First-principles study of temperature-dependent diffusion coefficients : Hydrogen, deuterium, and tritium in α-Ti", J. Appl. Phys., 113 (2013) 193502.

61. R. C. Pasianot, R. A. Perez, "First-principles appraisal of solute ultra-fast diffusion in hcp Zr and Ti", J. Nucl. Mater., 434 (2013) 158-61.

62. D. Connetable, J. Huez, E. Andrieu, C. Mijoule, "First-principles study of diffusion and interactions of vacancies and hydrogen in hcp-titanium", J. Phys. : Condesed Matter, 23 (2011) 405401.*

63. J. Fiebig, S. Divinski, H. Rosner, Y. Estrin, G. Wilde, "Diffusion of Ag and Co in ultrafine-grained -Ti deformed by equal channel angular pressing", J. Appl. Phys., 110 (2011) 083514.

64. S. L. Shang, L. G. Hector, Jr., Y. Wang, Z. K. Liu, "Anomalous energy pathway of vacancy migration and self-diffusion in hcp Ti", Phys. Rev. B, 83 (2011) 224104.

65. Y. Liu, L. Zhang, and D. Yu, "Computational study of mobilities and diffusivities in bcc Ti-Zr and bcc Ti-Mo alloys", J. Phase Equilibria and Diffusion, 30 (2009) 334-44.

66. A. Meyer, J. Horbach, O. Heinen, D. Holland-Moritz and T. Unruh, "Self diffusion in liquid titanium : Quasielastic neutron scattering and molecular dynamics simulation", Defect Diff. Forum, 289-292 (2009) 609-14.

67. S. V. Divinski, F. Hisker, T. Wilger, M. Friesel, Chr. Herzig, "Tracer diffusion of boron in α-Ti and γ-TiAl", Intermetallics, 16 (2008) 148-55. (B)

68. M. Manjeera, "A first-principles methodology for diffusion coefficients in metals and dilute alloys", Doctor of Philosophy, The Pensylvania State University, 2008*

68. F. L. Bregolin, M. Behar, F. Dyment, "Diffusion study of 18O implanted into α-Ti using the nuclear resonance technique", Applied Physics A, 86 (2007) 481-4.

69. F. L. Bregolin, M. Behar, F. Dyment, "Diffusion study of 15N implanted into α-Ti using the nuclear resonance technique", Applied Physics A, 90 (2008) 347-9.

70. M. Behar, J. H. R. dos Santos, F. Bermardi, F. Dyment, "Diffusion of Ga implanted α-Ti studied by means of the Rutherford backscattering technique", Defect Diffusion Forum, 213-215 (2003) 1-18.

71. R. A. Perez, F. Dyment, M. Behar, "Diffusion of Sn in different purityα -Ti", Mater. Lett., 57 (2003) 2670-4.

72. R. A. Perez, F. Dyment, G. G. Bermudez, D. Abriola, M. Behar, Appl. Phys. A, 76 (2003) 247-50.

73. Chr. Herzig, T. Wilger, T. Przeorski, F. Hisker, S. Divinski, "Titanium tracer diffusion in grain boudaries of α-Ti, α2-Ti3Al, and γ-TiAl and in α2/γ interphase boundaries", Intermetallics, 9 (2001) 431-42.

74. L. L. Araujo, M. Behar, "Al and Ag diffusion study in α-titanium", Appl. Phys. A, 71 (2000) 169.

75. Y. Mishin, Chr. Herzig, "Diffusion in the Ti-Al system", Acta Mater., 48 (2000) 589-623.

76. M. Behar, M. R. F. Soares, F. Dyment, R. A. Perez, S. Balart, "Diffusion of Pd in -Ti studied by means of Rutherford back-scattering and channelling techniques", Phil. Mag. A, 80 (2000) 1319-34.

77. M. I. De Barros, D. Rats, L. Vandenbulcke, G. Farges, "Influence of internal diffusion barriers on carbon diffusion in pure titanium and Ti-6Al-4V during diamond deposition", Diamond Relat. Mater., 8 (1999) 1022.

29b. R. J. Wasilewski, G. L. Kehl, Metallurgica, 50 (1954) 225-230.

56b. R. A. Perez, J. A. Gordillo, N. Di Lalla, "U diffusion in IV-B elements in their HCP phase", Procedia Mater. Sci., 8 (2015) 861-7.

72b. J. R. Fernandez, A. M. Monti, R. C. Pasianot, R. C. Pasianot, "Grain-boundary diffusion by vacancy mechanism in α-Ti and α-Zr", Meta. Mater. Trans. A, 33 (2002) 791-6.

P.293 掲載の参考文献

1. W. ヒュームロザリー著, 平野賢一訳, 鉄鋼物性工学入門-鉄とその合金の構造, 280-302, 共立出版, 1968.

2. 及川洪, 「鉄中の格子拡散」, 鉄と鋼, 1982, 1489-97.

3. H. Oikawa, Tech. Reports Tohoku University, 47 (1982) 67 and 48 (1983) 7.

4. 邦武立郎, 「鉄および鋼中の炭素の拡散-実験的研究を主として」, 日本金属学学会会報, 3 (1964), 466-76.

5. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

6. Y. Iijima, J. Alloys Comp., 234 (1996) 290-4.

7. P. Klugkist, Chr. Herzig, Phys. Stat. Sol., (a) 148 (1995) 413.

8. W. Wang, S. Zhang, X. He, Acta Met.Mater., 43 (1995) 1693-9.

9. D. Bergner, Y. Khaddour, Defect and Diffusion Forum, 95-98 (1993) 709-14.

10. Y. Iijima, K. Kimura, C.-G. Lee, K.-I. Hirano, Mat. Trans. JIM, 34 (1993) 20-6.*

11. C.-G. Lee, Y. Iijima, T. Hiratani, K.-I. Hirano, Mat. Trans. JIM, 31 (1990) 255-61.*

12. D. Bergner, Y. Khaddour, S. Lorx, Defect and Diffusion Forum, 66-69 (1989) 1407.

13. Y. Iijima, K. Kimura, K. Hirano, Acta Metall., 36 (1988) 2811-20.

14. J. Geise, Ch. Herzig, Z. Metallk., 78 (1987) 291.

15. K. Kimura, Y. Iijima, K.-I. Hirano, Trans. JIM, 27 (1986) 1-4.*

16. K. Kimura, Y. Iijima, K.-I. Hirano, Trans. Japan Inst. Met., 27 (1986) 1-4.

17. S. Kurokawa, J. E. Ruzzante, A. M. Hey, F. Dyment, J. Met. Sci., 17 (1983) 433-8.

18. H. Mehrer, D. Hopfel, G. Hettich, in : DIMETA 82, Diffusion in Metals and Alloys, Trans. Tech. Publ., 1983, p. 360.

19. T. Matsuyama, H. Hosokawa, H. Suto, Trans. Japan. Inst. Metals, 24 (1983) 589-94.

20. I. Richter, M. Feller-Kniepmeier, Phys. Stat. Sol., (a) 68 (1981) 289.

21. B. I. Bozic, R. J. Lucic,J. Mater. Sci., 11 (1976) 887.

22. L. Ruch, D. R. Sain, H. L. Yeh, L. A. Girfalco, "Analysis of diffusion in ferromagnets", J. Phys. Chem. Sol., 37 (1976) 649-53.

23. 野原清彦, 平野賢一, 日本金属学会誌, 40 (1976) 1053-61.

24. G. A. Bruggeman, J. A. Roberts, Met. Trans. A, 6 (1975) 755.

25. J. S. Kirkaldy, P. N. Smith, R. C. Sharma, Metall. Trans., 4 (1973) 624.

26. T. Eguchi, Y. Iijima, K. Hirano, Crystal Latt. Defects, 4 (1973) 265.

27. K. Nohara, K. Hirano, Trans. Iron Steel Inst. Jpn. (Suppl.), 11 (1971) 1267.

28. A. W. Bowen, G. M. Leak, Metall. Trans., 1 (1970) 1695.

31. M. Badia, A. Vignes, Acta Metall., 17 (1969) 177.

32. D. W. James, G. M. Leak, Philos. Mag., 14 (1966) 701.

33. T. Suzzuoka, Trans. JIM, 5 (1964) 911.

34. R. J. Borg, D. Y. F. Lai, Acta Met., 11 (1963) 861-6.

35. E. S. Buffington, K. I. Hirano, M. Cohen, Acta Metall., 9 (1961) 434.

36. P. E. Busby nad C. Wells, "Diffusion of boron in alpha iron", JOM, 5 (1953), 1463-8, and JOM, 6 (1954) 972.

37. A. Schneider, C.-C. Fu, F. Soisson, C. Barreteau, "Atomic diffusion in α-iron across the Curie Point : An efficient and transferable Ab initio-based modeling approach", Phys. Rev. Lett., 124 (2020) 215901.*

38. L. Zhu, S. Honrao, B. Rijal, R. G.Hennig and M. V. Manuel, "Phase equilibria and diffusion coefficients in the Fe-Zn binary system", Materials & DesignVolume 188, March 2020, 108437

39. S. Starikov, M. Mrovec and R. Drautz, "Study of grain boundary self-diffusion in iron with different atomistic models", Acta Mater., 188 (2020) 560-9.

40. N. Tsujino, A. Marza, and D. Yamazaki, "Pressure dependence of Si diffusion in γ-Fe", American Mineralogist, J. Earth and Planetary Mater., 105, (2020) 319-24.

41. G. Da Rosa, P. Maugis, A. Portavoce, J. Drillet, N. Valle, E. Lentzen, and K. Hoummada, "Grain-boundary segregation of boron in high-strength steel studied by nano-SIMS and atom probe tomography", Acta Mater., 182 (2020) 226-34.*

42. 濱名桂佑, 仲村龍介, 沼倉宏, 鈴木健之, 「二次イオン質量分析法によるα鉄中のホウ素の拡散浸透プロファイルの測定と拡散係数の決定」, 鉄と鋼, 106 (2020) 302-309.*

43. 関戸信彰, 木村勇太, 小山内匠, 宮城俊美, 沼倉宏, 吉見享佑, 「高周波グロー放電発光分析法を用いた鉄固溶体におけるホウ素の固溶限測定」, 鉄と鋼, 106 (2020) 292-301.*

44. S. Starikow, M. Mrovec, and R. Drautz, "Study of grain boundary self-diffusion in iron with different atomistic models", Acta Mater., 188 (2020) 560-9.

45. R. Rosa, P. Veronesi, and A. Casagrande, "On the effect of steel substrate alloying elements on the in-situ formation of intermediate thermal diffusion barrier layers", Mater. Chem. Phys., 240 (2020) 122231.

46. L. Zhu, S. Honrao, B. Rijal, R. G. Hennig, and M. V. Manuel, "Phase equilibria and diffusion coefficients in the Fe-Zn binary system", Mater. Design, 188 (2020) 108437.

47. X. Wang, J. Fasbender, and M. Poselt, "Efficient calculation methods for the diffusion coefficient of interstitial solutes in dilute alloys", Materials, 12 (2019) 1491.

48. R. Herschberg, C.-C. Fu, M. Nastar, and F. Soisson, "Atomistic modelling of the diffusion of C in Fe-Cr alloys", Acta Mater., 165, (2019) 638.

49. S. Ali, A.M.A. Rani, R. A. Mufti, S. Hstuty, M. Hussain, N. Shehzad, Z. Baig, and A. A. A. Aliyu, Metals, 9 (2019) 755.

50. A. Meyer, L. Henning, F. Kargl and T. Unruh, "Iron self diffusion in liquid pure iron and iron-carbon alloys", J. Phys. : Condens. Matter, 31 (2019) 395401 (5pp).

51. C. Garcia, V. P. Ramunni, "Diffusion in the bulk and in a symmetric tilt grain boundary of the Fe-Cr system", J. Nucl. Mater., 517 (2019) 296-306.

52. E. Baibuz, S. Vigonski, J. Lahtinen, J. Zhao, V. Jansson, V. Zadin, and F. Djurabekova, "Data sets of migration barriers for atomistic Kinetic Monte Carlo simulation of Fe self-diffusion", Data in Brief, 19 (2018) 564-9.

53. M. A. Hendy, T, M. Hatem, and A. El-Awady, "Atomistic simulations of carbon and hydrogen diffusion and segregation in alfa-iron deviant CSL grain boundaries", MRS Advances, 3 (Issue 45-46), (2018) 2795-800. Cambridge Core.*

54. T. Q. Nguyen, K. Sato, and Y. Shibutani (渋谷陽二), "Development of Fe-C interatomic potential for carbon impurities in α-iron", Comutational Mater. Sci., 150 (2018) 510-6.

55. E. Akshaya Devi, R. Chinnappan, and C. S. Sundar, "First-principles study of interaction energies of atomic defects in bcc ferromagnetic iron", Phys. Rev. B, 98 (2018) 144104.

56. O. A. Restrepo, N. Mousseau, M. Trochet, F. EI-Mellouhi, O. Bouhali, and C. S. Becquart, "Carbon diffusion paths and segregation at high-angle tilt grain boundaries in α-Fe studied by using a kinetic activation-relation technique", Phys. Rev. B, 97 (2018), 054309.

57. H. Wang, X. Gao, H. Ren, S. Chen and Z. Yao, "Diffusion coefficients of rare earth elements in fcc Fe : A first-principles study", J. Phys. Chem. Solids, 112 (2018) 153-7.

58. S. Yang, S.-H. Yun and T. Oda, "Molecular dynamics simulation on stability and diffusivity of hydrogen around a <111> symmetric tilt grain boundary in bcc-Fe", Fusion Eng. Design, 131 (2018) 105-10.

59. C. Nandipati, X. Jianng. R. S. Vemuri, S.Mahaudhu and A. Rohatgi, "Self-learning kinetic Monte Carlo simulation of diffusion in ferromagnetic α-Fe-Si alloys", J. Phys. : Condens. Matter, 30 (2018) 035903.

60. N. Anento, A. Serra, and Y. Osetsky, "eEffect of nickel on point defects diffusion in Fe-Ni alloys", Acta Mater., 132 (2017) 367-73.

61. J. Wang, X.-G. Lu, N. Zhu, and W. Zheng, "Thermodynamic and diffusion kinetic studies of the Fe-Co system", Calphad, 58 (2017) 82-100.

62. C. D. Versteylen, N. H. van Dijk, and M. H. F. Sluiter, "First-principles analysis of solute diffusion in dilute bcc Fe-X alloys", Phy. Rev. B, 96 (2017) 094105.

63. E. I. Galindo-Nava, B. I. Y. Basha and P. E. J. Rivera-Diaz-del-Castillo, "Hydrogen transport in metals : Integration of permeation, thermal desorption and degassing", J. Mater. Sci. Tech., 33 (2017) 1433-47.

64. J. Takahashi, K. Ishikawa, K. Kawakami, M. Fujioka and N. Kubota, "Atomic-scale study on segregation behabior at austenite grain boudaries in boron-and molybdenum-added steel", Acta Mater., 133 (2017) 41-54.

65. R. Mohammadzadeh, M. Mohammadzadeh, "Grain boundary and lattice diffusion in nanocrystal α-iron : An atomistic simulation study", Physica : Statisical Mechanics and its Applications, 482 (2017) 56-64.

66. K. Arioka, Y. Iijima, T. Miyamoto, "Rapid nickel diffusion in cold-worked type 316 austenitic steel at 360-500℃", Int. Mater. Res., 108 (2017) 791-7.

67. Y. Li, C. Hah, C. Zhang, K. Jia, P. Han and X. Wu, "Effects of alloying on the behavior of B and S at Σ5 (210) grain bundary in γ-Fe", Computational Mat. Sci., 115 (2016) 170-6.

68. Luca Messina, Maylise Nastar, Nils Sandberg, and P. Olsson, "Systematic electronic-structure investigation of substitutional impurity diffusion and flux coupling in bcc iron", Phys. Rev. B, 93 (2016) 184302.

69. L. Messina, M. Nastar, N. Sandberg, and P. Olsson, "Systematic electronic-structure investigation of substitutional impurity diffusion and flux coupling in bcc iron", Phys. Rev. B, 93, (2016) 184302.

70. X. Gao, H. Ren, C. Li, H. Wang, Y. Ji and H. Tan, "First-principles calculations of rare earth (Y. La and Ce) diffusivities in bcc Fe", J. Alloys and compounds, 663 (2016) 316-20.

71. O. A. Resrepo, N. Mousseau, F. EI-Meliouhi, O. Bouhali, M. Trochet, C. S. Becauart, "Diffusion properties of Fe-C systes studied by using kinetic activation-relaxation technique", Comp. Mater. Sci., 112, Part A (2016) 96-106.

72. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang and Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.

73. N. Sandberg, Z. Chang, L. Messina, P. Olsson, P. Korzhavyi, "Modeling of the magnetic free energy of self-diffusion in bcc Fe", Phys. Rev. B, 92 (2015) 184102.*

74. D. Murali, M. Posselt, M. Schiwarth, "First-principles calculation of defect free energies : General aspects illustrated in the case of bcc Fe", Phys. Rev. B, 92 (2015) 064103.

75. V. P. Ramunni, A. M. F. Rivas, "Diffusion behavior of Cr diluted in bcc and fcc Fe : Classical and quantum simulation methods", Mater. Chem. Phys., 162 (2015) 659-70.

76. G. Stechauner and E. Kozeschnik, "Assessment of substitutional self-diffusion along short-circuit paths in Al, Fe and Ni", Calphad, 47 (2014) 92-9.

77. P. Liu, W. Xing, X. Cheng, D. Li, Y. Li and X.-Q. Chen, "Effects of dilute substitutional solutes on interstitial carbon in α-Fe : interactions and associated carbon diffusion from first-principles calculations", Phys. Rev. B, 90 (2014) 024103.

78. C. Zhang, J. Fu, R. Li, P. Zhang, J. Zhao and C. Dong, "Solute/impurity diffusivities in bcc Fe : A first-principles study", J. Nucl. Mater., 455 (2014) 354-9.

79. H. Ding, V. I. Razumovkiy and M. Asta, "Self diffusion anomaly in ferromagnetic metals : A density-functional-theory investigation of magnetetically ordered and disoodered Fe and Co", Acta Mater., 70 (2014) 130-6.

80. S. L. Shang, H. Z. Fang, J. Wang, C. P. Guo, Y. Wang, P. D. Jablonski, Y. Du and Z. K. Liu, "Vacancy mechanism of oxygen diffusivity in bcc Fe : A first-principles study", Corrosion Sci., 83 (2014) 94-102.

81. H. Wen and C. H. Woo, "Temperature dependence of enthalpies and entropies of formation and migration of mono-vacany in BCC iron", J. Nucl. Mater., 455 (2014) 31-6.

82. B. Zhang, "Calculation of self-diffusion coefficients in iron", AIP Advances (2014) 017128.*

83. X. Hu, X.-G. Lu, Y. He, "Assessents of impurity diffusion coefficients of selected pure metals in fcc Fe", Adv. Mater. Res., 936 (2014) 545-51.

84. D. Liu, L. Zhang, Y. Du, S. Cui, W. Jie and Z. Jin, "Development of an atomic mobility database for disordered and ordered fcc phases in multicomponent Al alloys : focusing on binary systems", Int. J. Mater. Res., (formerly Z. Metallkd.) 104 (2013) 135-48.

85. E. J. Song, D.-W. Suh and H. K. D. H. Bhadeshia, "Theory for hydrogen desorption in ferritic steel", Computational Mater. Sci., 79 (2013) 36-44.

86. E. Hayward and C.-C. Fu, "Interplay between hydrogen and vacancies in α-Fe", Phys. Rev. B, 87 (2013) 174103.*

87. K. Kawakami and T. Matsumiya, "Ab-initio investigation of hydrogen trap state by cementite in bcc-Fe", ISIJ International, 53 (2013) 709-13.*

88. Y. A. Du, J. Rogal and R. Drautz, "Diffusion of hydrogen within idealized grains of bcc Fe : A kinetic Monte Carlo study", Phys. Rev. B, 86 (2012) 174110.*

89. H. Ding, S. Huang, G. Ghosh, P. K. Liaw and M. Asta, "A computational study of impurity diffusivities for 5d transition metal solutes in α-Fe", Scripta Mater., 67 (2012) 732-5.

90. J. P. Wharry, Z. Jiao, G. S. Was, "Application of the inverse Kirkendall model of radiation-induced segregation to ferritic-martensite alloys", J. Nucl. Mater., 425 (2012) 117-24.

91. R. A. Perez and D. N. Torres, "W diffusion in paramagnetic and ferromagnetic α-Fe", Applied Physics A, 104 (2011) 329-33.

92. H. Fujii (藤井啓道) and S. Tsurekawa, "Diffusion of carbon in iron under magnetic fields", Phys. Rev., B, 83 (2011) 054412.

93. H. Kimizuka (君塚肇), H. Mori and S. Ogata, "Effect of temperature on fast hydrogen diffusion in iron : A path-integral quantum dynamics approach", Phys. Rev. B, 83 (2011) 094110.*

94. O. I. Gorbatov, P. A. Korzhavyi, A. V. Ruban, B. Johansson and Yu. N. Gornostyrev, "Vacancy-solute interactions in ferromagnetic and paramagnetic bcc iron : Ab initio calculations", J. Nucl. Mater., 419 (2011) 248-55.*

95. D. Murali, B. K. Panigrahi, M. C. Valsakumar, C. S. Sundar, "Diffusion of Y and Ti/Zr in bcc iron : A first principles study", J. Nucl. Mater., 419 (2011) 208-12.

96. S. Huang, D. L. Worthington, M. Asta, V. Ozolins, G. Ghosh and P. K. Liaw, "Calculation of impurity diffusivities in α-Fe using first-principles methods", Acta Mater., 58 (2010) 1982-93.

97. A. Galdikas, T. Moskaliviene, "Stress induced nitrogen diffusion during nitriding of austenitic stainless steel", Computaional Mater. Sci., 50 (2010) 796-9.

98. J.-W. Jang, J. Kwon, B.-J. Lee, "Effect of stress on self-diffusion in bcc Fe : An atomistic simulation study", Scripta Mater., 63 (2010) 39-42.

99. Y. Liu, J. Wang, Y. Du, L. Zhang and D. Liang, "Mobilities and diffusivities in fcc Fe-X (X=Ag, Au, Cu, Pd and Pt) alloys", Calphad, 34 (2010) 253-62.

100. J. Sanchez, J. Fullea, M. C. Andrade and P. L. de Andres, "Ab initio molecular dynamics simulation of hydrogen diffusion in α-iron", Phys. Rev. B, 81 (2010) 132102.*

101. R. A. Perez, D. N. Torres and F. Dyment, "As diffusion in ferromagnetic α-Fe", Applied Phys. A, 97 (2009) 381-5.

102. R. A. Perez, D. N. Torres and F. Dyment and M.Weissman, "The effect of magnetism on Fe diffusion : New experimental results and ab-initio calculations", Defect and Diffusion Form, 237-240 (2009) 462-7.

103. Y. Liu, L. Zhang, Y. Du, D. Liang, "Ferromagnetic ordering and mobility endmembers for impurity diffusion in bcc Fe", Calphad, 33 (2009) 732-6.

104. R. A. Perez, D. N. Torrez, F. Dyment, Appl. Phys. A, 97 (2009) 381-5. (alpa iron, para, As)

105. D. H. Fors and G. Wahnstrom, "Nature of boron and diffusion in α-iron", Phys. Rev. B, 77 (2008) 132102.

106. S. Taketomi, R. Matsumoto and N. Miyazaki, "Atomic study of hydrogen distribution and diffusion around a {112} <111> edge dislocation in alpha iron", Acta Mater., 56 (2008) 3761-9.*

107. Q. Chen, J. Jeppsson and J. Agren, "Analytical treatment of diffusion durinng precipitate growth in multicomponent systems", Acta Mater., 56 (2008) 1890-6.

108. A. Ramasubramaniam, M. Itakura, M. Ortiz and E. A. Carter, "Effect of atomic scale plasticity on hydrogen diffusion in iron : Quatum mechanically informed and on-the-fly kinetic Monte Carlo simulations", J. Mater. Res., 23 (2008), 2757.*

109. C. S. Marchi, B. P. Somerday and S. L. Robinson, "Permability, solubility and diffusivity of hydrogen isotopes in stainless steels at high gas pressures", Int. J. Hydrogen Energy, 32 (2007) 100-16.

110. A. Inoue, H. Nitta and Y. Iijima, "Grain boudary self-diffusion in high purity iron", Acta Mater., 55 (2007) 5910-6.

111. S. Takemoto, N. Nitta, Y. Iijima, Y. Yamazaki, "Diffusion of tungsten in α-iron", Phil. Mag., 87 (2007) 1619-29.

112. C. Domain and C. S. Becquart, "Diffusion of phosphorus in α-Fe : an ab initio study", Phys. Rev. B, 71 (2005) 214109.

113. R. A. Perez, D. N. Rorres, F. Dyment, "Sb diffusion in α-Fe", Appl. Phys. A, 81 (2005) 787-91.

114. Y. Iijima, "Diffusion in high-purity iron : Influence of magnetic transformation on diffusion", J. Phase Equi. Diff., 26 (2005) 466-71.

115. S. V. Divinski, J. Geise, E. Rabkin and Chr. Herzig, "Grain boundary self-diffusion in α-iron of different purity : effect of dislocation enhanced diffusion", Z. Metallk., 95 (2004) 945-52.

116. R. A. Perez, M. Weissann, "Ab initio study of magnetic effects on diffusion in α-Fe", J. Phys : Condes. Matter, 16 (2004) 7033.

117. Y. Yamazaki, Y. Iijima, "Enhanced diffusion in -Fe and Au by vacancies induced under elevated hydrogen pressure", Defect and Diffusion Forum, 233-234 (2004) 115-26.

118. R. A. Perez and M. Weissmann, "Ab initio study of magnetic effects on diffusion in α-Fe", J. Phys. : Condens. Matter, 16 (2004) 7033

119. D. E. Jiang and E. A. Carter, "Diffusion of interstitial hydrogen into and through bcc Fe from first principles", Phy. Rev. B, 70 (2004) 064102.*

120. J. Yang, J. I. Goldstein, "Magnetic contribution to the interdiffusion coefficients in bcc (α) and fcc (γ) Fe-Ni alloys", Met. Mater. Trans. A, 35 (2004) 1681-90.

121. Chr. Herzig, J. Geise, S. V. Divinski, "Niobium bulk and grain boundary diffusion in alpha-iron", Z. Metalkd., 93 (2002) 1180-7.

122. N. Oono, H. Nitta, Y. Iijima, "Diffusion of niobium in α-iron", Mat. Trans., 44 (2003) 2078-83.

123. D. N. Torres, R. A. Perez, F. Dyment, "Diffusion of tin in α-iron", Acta Mater., 48 (2000) 2925-31.

124. O. Taguchi, M. Hagiwara, Y. Yamazaki, Y. Iijima, Defect and Diffusion Forum, 194-199 (2001) 91.

125. A. Seeger, "Lattice vacancies in high-purity α-iron", Phys. Stat. Sol. (a), 167 (1998) 289-311.

126. W. Wang, S. Znang and X. He, "Diffusion of boron in alloys", Acta Metall. Mater., 43 (1995) 1693-9.

5b. Landolt-Bornstein, vol. 26, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Condensed Matter, vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, (1990), p. 60, p. 151.

5c. Smithells metals reference book, seventh edition, Ed. E. A. Brandes & G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

12b. A. Schroder, M. Feller-Knipmeier, Phys. Stat. Sol., (a) 110 (1988) 107.

31b. Th. Heumann, R. Imm, J. Phys. Chem. Sol., 29 (1968) 1613.

51b. M. A. A. Hasan, J. Wang, Y. C. Lim, A. Hu, S. Shin, "Concentration dependece of hydrogen diffusion in α-iron from atomistic perspectives", Int. J. Hydrogen Energy, 44 (2019) 27876-84.

59b. U. K. Chohan, S. P. K. Koehler, E. Jimnez-Melero, "Diffusion of hydrogen into and through γ-iron by density functional theory", Surf. Sci., 672-673 (1018) 56-61.

65b. Y. He, Y. Li, C. Chen, H. Yu, "Diffusion coefficient of hydrogen interstitial atom in α-Fe, γ-Fe and ε-Fe crystal by first-principle", Int. J. Hydrogen Energy, 42 (2017) 27438-45.

72b. D. Zhu, T. Oda, "Trap effect of vacancy on hydrogen diffusivity in bcc-Fe", J. Nucl. Mater., 469 (2016) 237-43.

75b. X. Li, C. Gao, X. L. Xiong, Y. Bai, Y. J. Su, "Hydrogen diffusion in α-Fe under an applied 3-axis strain : A quantum manifestation", Int. J. Hydrogen Energy, 40 (2015) 10340-5.

87b. T. Tsuru, Y. Kaji, "First-principles thermodynamic calculation of diffusion characteristics of impurities in γ-iron", J. Nucl. Mater., 442 (2013) 5684-7.

121b. H. Nitta, Y. Yamamoto, R. Kanno, K. Takazawa, T. Iida, Y. Yamazaki, S. Ogu, Y. Iijima, Acta Mater., 50 (2002) 4117.

P.302 掲載の参考文献

1. H. メーラー, 藤川辰一郎, 「固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程」, 丸善出版, 2012, p. 640.

2. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

3. Landolt-Bornstein, vol. 26, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Condensed Matter, vol. 26, Diffusion in Solid Metals and Alloys, Ed. H. Mehrer, Springer-Verlag, 1990, 54, 136.

4. Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 「金属における拡散-純金属および合金における拡散の基礎, 理論, 現象」, 2012, 丸善出版, 470.

5. Smithells Metals Reference Book, Seventh Edition, Ed. E. A. Brandes & G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

6. D. B. Butrymowicz, J. R. Manning and M. E. Read, "Diffusion in copper and copper alloys. Part I. Volume and surface self-diffusion in copper", J. Phys.Chem. Ref. Data 2. (1973) 643. (Published Online : 15 October 2009)*

7. D. B. Butrymowicz, J. R. Manning and M. E. Read, "Diffusion in copper and copper alloys. Part II. Copper-silver and copper-gold systems", J. Phys.Chem. Ref. Data 3. (1974) 527. (Published Online : 15 October 2009)*

8. D. B. Butrymowicz, J. R. Manning and M. E. Read, "Diffusion in copper and copper alloys. Part III. Diffusion in systems involving elements of the groups IA, IIA, IIIB, IVB, VB, V10

9. D. B. Butrymowicz, J. R. Manning and M. E. Read, "Diffusion in copper and copper alloys. Part IV. Diffusion in systems involving elements of group VIII", J. Phys. Chem. Ref. Data 5. (1976) 103. (Published Online : 15 October 2009)

10. D. B. Butrymowicz, J. R. Manning and M. E. Read, "Diffusion in copper and copper alloys. Part V. Diffusion in systems involving elements of group VA", J. Phys. Chem. Ref. Data 6. (1977), 1. (Published Online : 15 October 2009)*

11. S. J. Rothman, N. L. Peterson, Phys. Stat. Sol. 35 (1969) 305.

12. K. Maier, "Self-diffusion in copper at "low temperatures", Phys. Stat. Sol. (a), 44 (1977) 567-76.

13. S. Fujikawa, K. Hirano, Point Defects and Defect Interactions, Eds. J. Takamura, M. Doyama, K. Kiritani, The University of Tokyo Press, 1982, p. 554 ; S.-I. Fujikawa, Res. Rep. Lab. Nucl. Sci. Tohoku Uni. 15 (1982) 127.

14. 藤川辰一郎, 牛野俊一, 銅と銅合金, 42 (2003) 331 ; S.-I. Fujikawa, S. Ushino, Res. Rep. Lab. Nucl. Sci. Tohoku Uni., 24 (1991) 128.

15. A. Almazouzi, M. P. Macht, V. Naundorf, G. Neumann, Phys. Stat. Sol. (a), 167 (1998) 15.

16. A. Almazouzi, M.-P. Macht, V. Naundorf, G. Neumann, Phys. Rev. B, 54 (1996) 857.

17. A. Almazouzi, M.-P. Macht, V. Naundorf, G. Neumann, Phys. Stat. Sol. (a), 133 (1992) 305.

18. Y. Iijima, Y. Wakabayashi, T. Itoga, K. Hirano, Mater. Trans. Japan Inst. Metals, 32 (1991) 457.

19. Y. Minamino, T. Yamane, T. Kimura, J. Mater. Sci. Lett., 7 (1988) 365.

20. S. -I. Fujikawa, M. Werner, H. Mehrer, A. Seeger, Mater. Sci. Forum, 15-18 (1987) 431 ; S. Fujikawa, H. Mehrer, Application of Ion Beam in Materials Science, Hosei Univ. Press, 1988, p. 265.

21. S. Fujikawa, A. Seeger, Res. Rep. Lab. Nucl. Sci. Tohoku Uni., 20 (1987) 431.

22. R. Dohl, M. P. Macht, V. Naundorf, Phys. Stat. Sol. (a), 86 (1984) 603.

23. W. Gust, C. Ostrtag, B. Predel, U. Roll, A. Lodding, H. Oedelius, Phil. Mag. A, 47 (1983) 395.

24. G. Neumann, M. Pfudstein, P. Reimers, Phil. Mag. A, 45 (1982) 499.

25. G. Krautheim, A. Neidhardt, U. Reinhold, A. Zehe, Phys. Lett., 72A (1979) 181.

26. K. Maier, R. Kirchheim, G. Tolg, Mirochim. Acta, 8 (Suppl) (1979) 125.

27. G. Krautheim, A. Neidhardt, U. Reinhold, Kristall und Technik, 13 (1978) 1335.

28. G. Krautheim, A. Neidhardt, U. Reinhold, Phys. Stat. Sol. (a), 49 (1978) K125.

29. S. M. Klotsman, Ya. A. Rabovskity, V. K. Talinskiy, A. N. Timofeyev, Fiz. Met. Metalloved., 45 (1978) 1104.

30. K. Hoshino, Y. Ijima, K. Hirano, Metall. Trans., 8A (1977) 469.

31. Y. Iijima, K. Hoshino and K.-I. Hrano, Met. Trans., A 8 (1977) 997-1001.

32. V. A. Gorbachev, S. M. Klotsman, Ya. A. Rabovskity, V. K. Talinskiy, A. N. Timofeyev, Fiz. Met. Metalloved., 44 (1977) 214.

33. R. L Foglson, Ya. A. Ugay, I. A. Alimovy, Izv. Vyssh. Uchebn. Zaved., Tsvetn. Metall., (1) (1977) 172.

34. J. Bernardini, J. Cabane, Acta Metall., 21 (1973) 1561.

35. R. L. Fogelson, Ya.A Ugay, A. V. Pokoyev. Izv. Vyssh. Uchebn. Zaved., Tsvetn. Metall., (3) (1973) 143.

36. R. L. Fogelson.Ya.A Ugay, A. V. Pokoyev. Izv. Vyssh. Uchebn. Zaved., Chern. Metall., (9) (1973) 136.

37. K. J. Anusavire, R. T. Dehoff, Metal. Trans., 3 (1972) 1279.

38. V. A. Gorbachev, S. M. Klotsman, Ya. A. Rabovskity, V. K. Talinskiy, A. N. Timofeyev, Fiz. Met. Metalloved., 34 (1972) 879.

39. F. D. Reinke, C. E. Dahlstrom, Phil. Mag., 22 (1970) 57.

40. H. Oikawa, T. Obara, S. Karashima, Metall. Trans., 1 (1970) 2969.

41. F. D. Reinke, C. E. Dahlstrom, Phil. Mag., 22 (1970) 57.

42. E. Moya, G. E. Moya-Goutier, F. Cabane-Brouty. Phys. Stat. Sol., 35 (1969) 893.

43. K. Fueki, Y. Ouchi, Bull. Chem. Soc. Japan, 51 (1978) 2234-6.*

44. N. L. Peterson, S. J. Rothman, Phys. Rev., 154 (1967) 558.

45. K. Monma, H. Suto, H. Oikawa, J. Japan Inst. Metals 28 (1964) 192.

46. N. L. Peterson, Phys. Rev., 132 (1963) 2471.

47. S. Komura, N. Kinitomi, J. Phys. Soc., Japan, 18 (Suppl II), (1963) 208.

48. J. G. Mullen, Phys. Rev., 121 (1961) 1649.

49. M. C. Inman, L. W. Barr, Acta Metall., 8 (1960) 112.

50. N. H. Nachtrieb, C. T. Tomizuka, L. G. Schulz, Report AFOSR-TR-60-23, The University of Chicago, (1960).

51. J. Hino, C. T. Tomizuka, C.A. Wert, Acta Metall., 5 (1957) 41.

52. M. C. Saxena, B. D. Sharma, Trans Indian, 23 (1970) 16.

53. R. L. Folgelson Ya. A. Ugay, A. V. Pokoyev, Fiz. Tvrd. Tela, 13 (1971) 1028.

54. P. Spindler, K. Nachtrieb, Phys. Stat. Sol. (a) 37 (1976) 449 ; Metal. Trans. 9A (1978) 763.

55. R. L. Fogelson, Ya. A. Ugay, A. V. Pokoyev, Fiz. Met. Metalloved., 34 (1972) 1104.

56. S. J. Wang, H. J. Grabke, Z. Metallk., 61 (1970) 597.

57. C. Inmann, L. W. Barr, Acta Metall., 8 (1960) 112.

58. V. A. Gorbachev, S. M. Klotsman, Ya. A. Rabovskity, V. K. Talinskiy, A. N. Timofeyev, Fiz. Met. Metalloved., 35 (1973) 889.

59. G. Krautheim, A. Neidhardt, U. Reinhold, Phys. Lett., 72A (1979) 181.

60. G. Rummel, H. Mehrer, Defect and Diffusion Forum, 66-69 (1989) 453.

61. R. L. Fogelson, Ya. A. Ugay, I. A. Akimova, Fiz. Met. Metalloved., 37 (1974) 1107.

62. S. M. Klotsman, Ya. A. Rabovskity, V. K. Talinskiy, A. N. Timofeyev, Fiz. Met. Metallovede., 28 (1969) 1025.

63. M. B. Dutt, S. K. Sen, Japan J. Appl. Phys., 18 (1979) 1025.

64. K. Hoshino, Y. Iijima, K. Hirano, Point Defects and Defect Interactions, Eds. J. Takamura, M. Doyama, K. Kiritani, The University of Tokyo Press, 1982, p. 562.

65. C. A. Mackliet, Phys. Rev., 109 (1958) 1964.

66. G. Neumann, V. Tolle, Phil. Mag. A, 57 (1988) 319.

67. R. L. Fogelson, Ya.A. Ugay, A.V. Pokoyev, Fiz. Met. Metalloved., 33 (1972) 1102.

68. D. Connetable and M. David, "Diffusion of interstitial species (H and O atoms) in fcc systems (Al, Cu, Co, Ni and Pd) : Contribution of first and second order transition states", J. Alloys and Compounds, 772 (2019) 280-7.

69. R. Rupp, B. Caerts, A. Vantomme, J. Fransaed, and A. Vlad, "Lithium diffusion in copper", J. Phys. Chem. Lett., 10 (2019) 5206-10.

70. G. Wilde and S. Dvinski, "Grain boundaries and diffusion phenomena in severely deformed materials", Mater. Trans., 60 (2019) 1302-15.

71. D. Prokoshkina, V. A. Esin, and S. V. Divinski, "Experimental evidence for anomalous grain boundary diffusion of Fe in Cu and Cu-Fe alloys", Acta Mater., 133 (2017) 240-6.

72. D. Gaertner, G. Wilde, S. V. Divinski, "Grain boundary diffusion and segregation of 57Co in high-purity copper : Radiotracer measurements in B- and C-type diffusion regimes", Acta Mater., 127 (2017) 407-15.

73. H.-S. Zhou, H.-D. Liu, Z.-Q. An, B. Li, Y.-P. Xu, F. Liu, M.-Z. Zho, Q. Xu, F. Ding and G.-N. Luo, "Deuterium permeation and retention in copper alloy", J. Nucl. Mater., 493 (2017) 398-403.

74. Y. Liu, C. Chen, D. Liu, Y. Du, S. Liu, X. Tao and Y. Ouyang, "Diffusivities and atomic mobilities for fcc Cu-Ni-Sn alloys", Calphad, 59 (2017) 84-9.

75. G. M. Poletaev, I. V. Zorya, D. V. Novoselova, M. D. Starostenkov, "Molecular dynamics simulation of hydrogen atom diffusion in crystal lattice of fcc metals", Int. J. Mater. Res., 108 (2017) 785-90.

76. H. Wu, T. Mayaeshiba and D. Morgan, "High-throughput ab-initio dilute solute diffusion database", Sci. Data 3, Article number : 160054 (2016).

77. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang and Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.*

78. D. Liu, L. Zhang, Y. Du, S. Cui, W. Jie and Z. Jin, "Development of an atomic mobility database for disordered and ordered fcc phases in multicomponent Al alloys : focusing on binary systems", Int. J. Mater. Res., (formerly Z. Metallkd.) 104 (2013) 135-48.

79. P. Eslami, A. K. Taheri, "An investigation on diffusion bonding of aluminum to copper using equal channel angular extrusion process", Mat. Lett., 65 (2011) 1862-4.

80. A. Meyer, "Self-diffusion in liquid copper as seen by quasielastic neutron scattering", Phys. Rev. B, 81 (2010) 012102.

81. C. E. Campbell and A. L. Rukhin, "Evaluation of self-diffusion data using weighted means statistics", Acata Mater., 59 (2011) 5194-201.

82. Y. Amouyal, S. V. Divinski, Y. Estrin and E. Rabkin, "Short-circuit diffusion in an ultrafine-grained copper-zirconium alloy produced by equal channel angular pressing", Acta Mater., 55 (2007) 5968-79.

83. B. Schonfelder, G. Gottstein and L. S. Shvindlerman, "Comparative study of grainboundary migration and grain-boundary self-diffusion of [001] twist-grain boundaries in copper by atomistic simulations", Acta Mater., 53 (2005) 1597-609.*

84. D. Fuks, K.C. Mundim, L. A. C. Malbouisson, A. Berner, S. Dorfman and D. E. Ellis, "Carbon in copper and silver : diffusion and mechanical properties", J. Mol. Str. (Theochem), 539 (2001) 199-214.

85. H. Magnusson and K. Frisk, "Self-diffusion and impurity diffusion of hydrogen, oxygen, sulphur and phosphorus in copper", Swera KIMAB AB, 2013, 3-39, SKB TR-13-24.*

86. 小野寺夏生, 青野萌, 「拡散原子の基礎的性質に基づく銅および銀中の不純物拡散係数の予測」, 日本金属学会誌, 65 (2001), 779-82.

P.308 掲載の参考文献

1. G. Neumann and C. Tuijn, Self-diffusion and impurity diffuion in pure metals : handbook of experimental data, ELSEVIER, 2009.

2. Landolt-Bornstein, vol. 26, Numerical Data and Functional Relationships in Science and Technology, New Series, Group III, Condensed Matter, vol. 26, Diffusion in Solid Metals and Alloys, ed. H. Mehrer, Springer-Verlag, 1990, 52, 132.

3. Smithells Metals Reference Book, Seventh Edition, eds. E. A. Brandes, G. B. Brook, Butterworth-Heinemann, 1992, 13-9, 13-21.

4. M. S. A. Karunaratse, R. C. Reed, Defect and Diffusion Forum, 237-240 (2005) 420.

5. M. S. A. Karunaratse. R. C. Reed, Acta Mater., 51 (2003) 2905.

6. M. S. A. Karunaratse, R. C. Reed, Mater. Sci. Eng. A, 281 (2000) 229.

7. Y. Minamino, H. Yoshida, S. B. Jung, K. Hirao, T. Yamane, Defect and Diffusion Forum, 143-147 (1997) 257.

8. T. Takahashi, Y. Minamino, T. Asada, S. B. Jung, T. Yamane, J. High-Temp. Soc., 22 (1996) 121.

9. S. B. Jung, T. Yamane, Y. Minamino, K. Hirao, H. Araki, S. Saji, J. Mater. Sci. Lett., 11 (1992) 1333.

10. P. Neuhaus, Ch. Herzig, Z. Metallk., 80 (1989) 220.

11. G. Neumann, V. Tolle, Phil. Mag. A, 57 (1988) 621.

12. O. Taguchi, Y. Iijima, K. Hirano, J. Japan Inst. Metals, 48 (1984) 20.

13. S. Mantl, S. J. Rothman, L. J. Noidki, J. L. Lerner, J. Phys. F : Metal. Phys., 13 (1983) 1441.

14. W. Gust, M. B. Hintz, A. Lodding. H. Odelius. B. Predel, Acta Metall., 30 (1982) 75.

15. W. Gust, M. B. Hintz, A. Lodding, H. Odeliuls, B. Predel, Phys. Stat. Sol. (a), 64 (1981) 187.

16. V. L. Arbuzov, A. B. Vladimirov, S. Ye. Danilov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 49 (1980) 352.

17. A. B. Vladimirov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 48 (1979) 1113.

18. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 48 (1979) 319.

19. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 46 (1978) 1232.

20. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 45 (1978) 1015.

21. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 45 (1978) 1301.

22. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 41 (1976) 181.

23. K. Maier, H. Mehrer, E. Lessmann, W. Schule, Phys. Stat. Sol. (b), 78 (1976) 689.

24. A. B. Vladimirov, V. N. Kaygorodov, S. M. Klotsman, I. Sh. Trakhtenberg, Fiz. Met. Metalloved., 39 (1975) 319.

25. H. Bakker, J. Backus, F. aals, Phys. Stat. Sol. (b), 45 (1971) 633.

26. M. Badia, A. Vignes, Acta Metall., 17 (1969) 177.

27. H. Bakker, Phys. Stat. Sol., 28 (1968) 569.

28. M. S. Anand, S. P. Murarka, R. P. Agarwala, J. Appl. Phys., 36 (1965) 3860.

29. R. A. Swalin, A. Martin, Trans. AIME, 206 (1956) 567.

30. M. David, A. Prillieux, D. Monceau, and D. Connetable, "First-principles study of the insertion and diffusion of interstitial atoms (H, C, N and O) in nickel", J. Alloys and Compounds, 822, (2020) 153555.

31. J. Chen, J. Zhao, L. Zhng, X.-G. Lu and L. Liu, "Atomic mobilities in fcc Ni-rich Ni-X (X=Rh, Ta, W, Re, and Ir) systems", Calphad, 65 (2019) 316-25.

32. X. Zhou, N. Mousseau, and J. Song, "Is hydrogen diffusion along grain boundaries fast or slow?", Phys. Rev., 122 (2019) 215501.

PubMed

33. G. Wilde and S. Dvinski, "Grain boundaries and diffusion phenomena in severely deformed materials", Mater. Trans., 60 (2019) 1302-15.

34. X. Zhou, N. Mousseau, and J. Song, "Is hydrogen diffusion along grain boundaries fast or slow? Atomic origin and mechanistitic modeling", Phys. Rev. Lett., 122 (2019), 215501.

35. D. Connetable and M. David, "Diffusion of interstitial species (H and O atoms) in fcc systems (Al, Cu, Co, Ni and Pd) : Contribution of first and second order transition states", J. Alloys and Compounds, 772 (2019) 280-7.

36. L. J. Wirth, A. A. Farajian and C. Woodward, "Density functional study of self-diffusion along an isolated screw dislocation in fcc Ni", Phys. Rev. Mater., 3 (2019) 033605.

37. C. Z. Hargather, S.-L. Shang and Z.-K. Liu, "Data set diffusion coefficients and relative creep rate ratios of 26 dilute Ni-X alloy systems from first-principles calculations", Data in Brief, 20 (2018) 1537-51.*

38. C. Z. Hargather, S.-L. Shang and Z.-K. Liu, "A comprehensive first-principles study of solute elements in dilute Ni alloys : Diffusion coefficients and their implications to tailor creep rate", Acta Mater., 157 (2018) 126-41.*

39. Y. Gong, B. Graboski, A. Glensk, F. Kormann, J. Neugebauer, R. C. Reed, "Temperature dependence of the Gibbs energy of vacancy formation of fcc Ni", Phys. Rev. B, 97 (2018) 214106.*

40. K. Jin, C. Zhang, F. Zhang, H. Bei, "Influence of compositional complexity on interdiffusion in Ni-containing concentrated solid-solution alloys", Mater. Res. Lett., 6 (2018) 293-9.*

41. Y. Hanlumyuang, "Atomistic simulation of structural evolution at long time scales : Diffusion of aluminum in nickel at a low concentration limit", J. Sci. Technology Ubon Ratchathanl University : Special Issue November 2017, 5-13.

42. G. M. Poletaev, I. V. Zorya, D. V. Novoselva, and M. D. Starostenkov, "Molecular dynamics simulation of hydrogen atom diffusion in crystal lattice of fcc metals", Int.J. Mater. Res. (formally Z. Metallkd.), 108 (2017) 785-90.

43. H. Alimadadi, C. Kjartansdottir, A. Burrows, T. Kasama, and P. Moller, "Nickelaluminum diffusion : A study of evolution of microstructure and phase", Mater. Characterizaiton, 130 (2017) 105-12.

44. Y. Wang, N. Zhu, H. Wang nad X.-G. Lu, "Interdiffusion and diffusion mobility for fcc Ni-Co-Al alloys", Met. Mater. Trans. A, 48 (2017) 943-7.

45. E. I. Galindo-Nava, B. I. Y. Basha and P. E. J. Rivera-Diaz-del-Castillo,"Hydrogen transport in metals : Integration of permeation, thermal desorption and degassing", J. Mater. Sci. Tech., 33 (2017) 1433-47.

46. H. Wu, T. Mayaeshiba and D. Morgan, "High-throughput ab-initio dilute solute diffusion database", Sci. Data 3, Article number : 160054 (2016).

47. J. Chena, J. Xiao, L. Zhang and Y. Dua "Interdiffusion in fcc Ni-X (X=Rh, Ta, W, Re and Ir) alloys", J. Alloys and Compounds, 657 (2016) 457-63.

48. D. N. llin, A. A. Kutsenko, D. Taguy, and J.-M. Olive, "Effect of grain boundary trapping kinetics on diffusion in polycrystalline materials : hydrogen transport in Ni", Modelling Simul. Mater. Sci. Eng., 24 (2016) 035008.

49. J. Chen, J. Xiao, L. Zhang, and Y. Du, "Interdiffusion in fcc Ni-X (X=Rh, Ta, W, Re and Ir) alloys", J. Alloys and Compounds, 657 (2016) 457-63.

50. H. Wu, T. Mayaeshiba and D. Morgan, "High-throughput ab-initio dilute solute diffusion database", Sci. Data 3, Article number : 160054 (2016).

51. S.-L. Shang, B.-C. Zhou, W. Y.Wang, A. J. Ross, X. L. Liu, Y.-J. Hu, H.-Z. Fang, Y. Wang and Z.-K. Liu, "A comprehensive first-principles study of pure elements : Vacancy formation and migration energies and self-diffusion coefficients", Acta Mater., 109 (2016) 128-41.

52. J. Chen,J. Xiao, L. Zhang and Y. Du, "Interdiffusion in fcc Ni-X (X=Rh, Ta, W, Re and Ir) alloys", J. Alloys and compounds, 657 (2016) 457-63.

53. Y. L. Yang, Z. Shi, Y. S. Luo, Y. Lu, S. Y. Yang, J. J. Han, W. B. Li, C. P. Wang and X. J. Liu, "Interdiffusion and atomic mobility studies in Ni-rich fcc Ni-rich fcc Ni-Co-Al alloys", J. Phase Equilibria and Diffusion, 37 (2016) 269-76.

54. A. I. Epishin, A. O. Rodin, B. S. Bokshtein, G. Oder, T. Link, I. L. Svetlov, "Interdiffusion in binary Ni-Re alloys", The Physics of Metals and Metallography, 116 (2015) 175-81.

55. D. D. Stefano, M. Mrovec, C. Elsasser, "First-principles investigation of hydrogen trapping and diffusion at grain boundaries in nickel", Acta Mater., 98 (2015) 306-12.

56. G. Stechauner and E. Kozeschnik, "Assessment of substitutional self-diffusion along short-circuit paths in Al, Fe and Ni", Calphad, 47 (2014) 92-9.

57. J. J. M. Jebaraj, D. J. Morrison and L. l. Suni, "Hydrogen diffusion coefficients through Inconel 718 in different metallurgical conditions", Corrosion Sci., 80 (2014) 517-22.

58. X. Zhang, H. Deng, S. Xiao, Z. Zhang, J. Tang, L. Deng, W. Hu, "Diffusion of Co, Ru and Re in Ni-based superalloys : A first-principles study", J. Alloys and Compounds, 588 (2014) 163-9.*

59. I. L. Lomaev, D. L. Novikov, S. V. Okatov, Yu. N. Gornostyrev, A. Cetel, M. Maloney, R. Montero, S. F. Burlatsky, "On the mechanism of sulfur fast diffusion in 3-D transiton mtals", Acta Mater., 67 (2014) 95-101.

60. H. Z. Fang etal., "First-principles studies on vacancy-modified interstitial diffusion mechanism of oxygen in nickel, assosiated with large-scale atomic simulation technique", J. Appl. Phys., 115 (2014) 043501.

61. K. N. Goswami, A. Mottura, "Can slow-diffusing solute atoms reduce vacancy diffusion in advanced high-temperature alloys?", Mat. Sci. Eng. : A, 617 (2014) 194-9.

62. D. Prokoshikina, V. A. Esin, G. Wilde, S. V. Divinski, "Grain boundary width, enrgy and self-diffusion in nickel : Effect of material purity", Acta Mater., 61 (2013) 5188-97.*

63. D. Prokoshkina, V. A. Esin, G. Wilde, and S. V. Divinski, "Grain boudary width, energy and self-diffusion in nickel : Effect of material purity", Acta Mater., 61 (2013) 5188-97.

64. D. Liu, L. Zhang, Y. Du, S. Cui, W. Jie and Z. Jin, "Development of an atomic mobility database for disordered and ordered fcc phases in multicomponent Al alloys : focusing on binary systems", Int. J. Mater. Res. (formerly Z. Metallkd), 104 (2013) 135-48.*

65. T. Garnier, V. R. Manga, D. R. Trinkle, M. Nastar, P. Bellon, "Stress-induced anisotropic diffusion in alloys : Complex Si solute flow near a dislocation core in Ni", Phys. Rev. B, 88 (2013) 134108.

66. A. Oudriss, J. Creus, J. Bouhattate, E. Conforto, C. Berziou, C. Savall, and X. Feaugas, "Grain size and grain-boundary effects on diffusion and trapping of hydrogen in pure nickel", Acta Mater., 60 (2012) 6814-28.

67. A. Oudriss, J. Creus, J. Bouhattate, C. Savall, B. Peraudeau and X. Feaugas, "The diffusion and trapping of hydrogen along the grain boundaries in polycrystalline nickel", Scripta Mater., 66 (2012) 37-40.

68. Wl Qiong, L. Shu-Suo, M. Yue, G. Sheng-Kai, "First principles calculations of alloying element diffusion coefficients in Ni using the five-frequency model", Chinese Phys. B, 21 (2012) 109102.

69. C. E. Campbell and A. L. Rukhin, "Evaluation of self-diffusion data using weighted means statistics", Acata Mater., 59 (2011) 5194-201.

70. U. R. Kattner and C. E. Campbell, "Invited review : Modelling of thermodynamics and diffusion in multicomponent systems", Mat. Sci. Tech., 25 (2009) 443-59.

71. A. Meyer, S. Stuber, D. Holland-Moritz, O. Heinen and T. Unruh, "Determination of self-diffusion coefficients by quasielastic neutron scattering measurements of levitated Ni droplets", Phys. Rev. B, 77 (2008) 092201.

72. E. H. Megchiche, M. Amarouche, and C. Mijoule, "First-principles calculations of the diffusion of atomic oxygen in nickel : thermal expansion cotribution", J. Phys. : Condens. Matter, 19 (2007) 296201.

73. M. Krcmar, C. L. Fu, A. Janotti, R. C. Reed, "Diffusion rates of 3d transition metal solutes in nickel by first-principles calculations", Acta Mater., 53 (2005) 2369-76.

74. K. Wu, Y. A. Chang and Y. Wang, "Simulating interdiffusion microstructures in Ni-Al-Cr diffusion couples : a phase field approach coupled with CALPHAD database", Scrpta Mater., 50 (2004) 1145-50.

75. A. Janotti, M. Krcmar, C. L. Fu, R. C. Reed, "Solute diffusion in metals : Larger atoms can move faster", Phys. Rev. Lett., 92 (2004) 085901.

76. C. E. Campbell, W. J. Boettinger and U. R. Kattner, "Development of a diffusion mobility database for Ni-base superalloys", Acta Mater., 50 (2002) 775-92.

8b. R. V. Patil, G. B. Kale, J. Nucl. Mater., 230 (1996) 57-60.

29b. K. Monma, H. Suto, H. Oikawa, J. Japan Inst. Metals, 28 (1964) 188.

37b. P. Paranjape, P. Gopal, S. G. Srinivasan, "Forst-principles study of diffusion and interactions of hydrogen with silicon, phosphosrus, and sulfur impurities in nickel", J. Appl. Phys., 125 (2019) 125104.

43b. G. M. Poletaev, I. V. Zorya, D. V. Novoselova, M. D. Starostenkov, "Molecular dynamics simulation of hydrogen atom diffusion in crystal lattice of fcc metals", Int. J. Mater. Res., 108 (2017) 785-90.

訳者あとがき

P.313 掲載の参考文献

1) 「金属における拡散-純金属および合金における拡散の基礎, 理論, 現象」, Th. ホイマン著, H. メーラー協力, 藤川辰一郎訳, 丸善出版, 2012年.

「固体中の拡散-基礎と方法, 異種物質中の拡散, 拡散律速過程」, H. メーラー著, 藤川辰一郎訳, 丸善出版, 2012年.

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シュウモン 固体における拡散 原書2版(電子書籍版)

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目次

この書籍の参考文献

第1章 拡散方程式

第2章 拡散の原子論

第3章 希薄合金中の拡散

第4章 濃度勾配下での拡散

第5章 非金属中の拡散

第6章 高速拡散路

第7章 固体中のサーモトランスポートおよびエレクトロトランスポート

付表 代表的な金属中の各種元素の拡散データ