Table of contents

1. Front Cover
2. Rapidly Quenched Materials, Part 2
3. Copyright Page
4. Table of Contents
5. Conference Organization
6. Chapter 1. The influence of hydrogen contamination on the amorphization reaction of CuTi alloys
7. Chapter 2. Amorphization in an immiscible Cu–V system by mechanical alloying and its structure observed by neutron diffraction
8. Chapter 3. Structural investigation of a mechanically alloyed Al–Fe system
9. Chapter 4. The structure of equiatomic NiTi, CuTi, NiZr and CuZr prepared by mechanical alloying
10. Chapter 5. X -ray diffraction studies of an amorphous Fe80–xCoxSi6B14 alloy system
11. Chapter 6. Short range order in Fe80–xMxB20
12. Chapter 7. The atomic and magnetic structure of melt-spun amorphous Dy7Ni3
13. Chapter 8. The atomic and magnetic structure of melt-spun amorphous Dy7Ni3
14. Chapter 9. Determination of static structure factors of metallic glasses by energy dispersiveX-ray scattering
15. Chapter 10. Quasicrystals: local structure versus global structure
16. Chapter 11. Site of ruthenium in icosahedral Al–Mn–Ru–Si
17. Chapter 12. Mössbauer measurements and susceptibility measurements on crystalline and icosahedral AlCuFe alloys
18. Chapter 13. Lattice properties of a model quasicrystalline phase in comparison with those of crystalline and amorphous phases
19. Chapter 14. The scattering amplitudes for icosahedral quasicrystals with decorations
20. Chapter 15. On the nature of icosahedral phases in Al–(Fe,V,Si) alloys
21. Chapter 16. Quasicrystalline microstructures in Al85–xCuxCr15 splats
22. Chapter 17. Molecular dynamics study of the collective density excitations in monatomic glass
23. Chapter 18. Structure and vibrational dynamics of Ca70Mg30 glass
24. Chapter 19. Molecular dynamics simulation of structural anisotropy in glassy metals
25. Chapter 20. Flow defects and diffusion defects in metallic glasses
26. Chapter 21. Annealing effects on X-ray diffraction peaks of melt-spun Al–Cu–Fe quasicrystals
27. Chapter 22. The inflation pattern of the three-dimensional Penrose tiling
28. Chapter 23. Quasicrystals in Al–Ni alloys
29. Chapter 24. Crystallization of the "stable" quasicrystal AlCuFe
30. Chapter 25. Element redistribution and embrittlement of amorphous Ni–P during structural relaxation
31. Chapter 26. A neutron diffraction study on amorphous Fe0.25Zr0.75
32. Chapter 27. Atomic motion at the glass transition: comparison between experimental and molecular-dynamics investigations
33. Chapter 28. Characterization of defects in metallic glasses
34. Chapter 29. X-ray diffraction and EXAFS studies of sputter-deposited Ti-Pd films
35. Chapter 30. Interpretation of the asymmetry of the first neighbour peak in the pair correlation function of amorphous materials
36. Chapter 31. X-ray structure analysis of Ni–Ti–Al and Cu–Ti–Al alloy glasses
37. Chapter 32. Structural characterization of Ni–V amorphous alloys prepared by mechanical alloying
38. Chapter 33. Neutron irradiation effects in metallic glasses
39. Chapter 34. Thermal expansion and fractional free volume changes of metallic glasses during heating
40. Chapter 35. Effect of cooling condition on the internal field distribution function of amorphous Fe–Si–B alloys
41. Chapter 36. The rhomb unit structural model of amorphous alloys
42. Chapter 37. Structure and density of transition metal–metalloid amorphous alloys
43. Chapter 38. Pair potentials, inherent structure and crystallization of liquids
44. Chapter 39. The use of rapidly solidified ribbons in automotive exhaust gas catalyst substrates
45. Chapter 40. Oxidation of amorphous NiZr sputtered films
46. Chapter 41. Passivity of amorphous and crystalline Ni–Ti alloys
47. Chapter 42. The structure and morphology of the corrosion products formed on the surfaces of a rapidly solidified Mg–3.5A1 alloy
48. Chapter 43. The effect of molybdenum on the corrosion behavior of amorphous Fe–Cr–Mo–P–C alloys in hydrochloric acid
49. Chapter 44. The catalytic properties of Fe78Si12B10 alloys prepared by ball milling
50. Chapter 45. Photoelectron spectroscopic investigations of the surface reactivity of crystalline and amorphous Ti–Cu alloys
51. Chapter 46. Corrosion resistance and surface structure of sputtered FeNiCrMoZr amorphous alloys
52. Chapter 47. Microstructural characterization and comparative electrochemical behaviour of Fe–Ni–Cr and Fe–Ni–Cr–P laser surface alloys
53. Chapter 48. Pitting potential and structure of sputter-deposited Al–Ti alloys
54. Chapter 49. A scanning Auger microprobe study of the surface layer of FeCrPCSi amorphous ribbons
55. Chapter 50. High temperature oxidation behaviour of rapidly solidified Fe–Cr–Al ribbons
56. Chapter 51. Corrosion and electrochemical characterization of rapidly solidified Cu–B, Cu–Al–B, Cu–Cr–Zr alloys
57. Chapter 52. XPS analysis of amorphous Ni–Nb–Sn–Pt alloy catalysts for electro-oxidation of formaldehyde
58. Chapter 53. The effect of hydrogen on the passivity of iron-based and nickel-based amorphous alloys
59. Chapter 54. Oxidation and crystallization studies of Fe–22.5Al–10Zr rapidly solidified metallic glass ribbons
60. Chapter 55. Structural studies of changes in amorphous Cu61Zr39 in the dehydrogenation of 2-propanol
61. Chapter 56. Aluminium RS metallurgy
62. Chapter 57. Microstructural characterization of atomized powder ofAl–5Mn–5Fe–2Si (wt.%) alloy
63. Chapter 58. Large scale manufacturing of rapidly solidified aluminum alloys
64. Chapter 59. The consolidation of rapidly solidified Al–5wt.%Cr–2wt.%Zr(–1wt.%Mn) alloy particulate by hot rolling
65. Chapter 60. Spray forming of aluminium–copper alloys
66. Chapter 61. Rapid solidification of aluminium by the Hydro Aluminium process
67. Chapter 62. About the amorphization criteria in aluminium-based alloys
68. Chapter 63. New amorphous alloys with significant supercooled liquid region and large reduced glass transition temperature
69. Chapter 64. Rapid solidification of FeAl intermetallics containing ZrB2
70. Chapter 65. Microstructure of rapidly solidified aluminium-based immiscible alloys
71. Chapter 66. Surface characterization of a rapidly solidified A15Mn2.5Cr powder before and after hot extrusion
72. Chapter 67. The microstmcture and properties of high pressure gas-atomized Al–Li–Hf alloy powders
73. Chapter 68. The development of microstructure during extrusion of Al–8Fe flake
74. Chapter 69. A kinetic study of precipitation in rapidly solidified Al–8Fe during processing
75. Chapter 70. Rapid solidification of Al–Cr–Zr–Mn alloys
76. Chapter 71. Geometry of melt-spun ribbons
77. Chapter 72. An analysis of precipitation kinetics in rapidly quenched Al–Fe alloys
78. Chapter 73. Metastable phase characterization in ion implanted and rapidly solidified aluminium-based alloys
79. Chapter 74. Precipitation of metastable phases in a rapidly quenched Al–6wt.%Cu alloy
80. Chapter 75. Structure and mechanical properties of rapidly solidified Al–Li–Cu–Mg alloys containing minor zirconium and rare earths
81. Chapter 76. Microstructural characterization of rapidly solidified Al–Mn–Cr alloys
82. Chapter 77. The influence of iron on precipitation from supersaturated Al–Mo solid solutions
83. Chapter 78. Rapid solidification of Mg–Al–Zn–Si alloys
84. Chapter 79. Stress–relaxation and creep behaviour of some rapidly solidified magnesium alloys
85. Chapter 80. Superplasticity in magnesium alloy AZ91
86. Chapter 81. Rapidly solidified Al–3Cr–X (Ni, Mo) ribbons: structure and decomposition behaviour
87. Chapter 82. Magnetothermal analysis of the phase transformation of quasicrystalline Al–14%Mn
88. Chapter 83. High mechanical strength of aluminum-based crystalline alloys produced by warm consolidation of amorphous powder
89. Chapter 84. Icosahedral quasicrystals in an AlMnCrSi alloy
90. Chapter 85. Nucleation and formation of quasicrystalline phases in undercooled Al–Mn melts
91. Chapter 86. Degassing of USGA-atomized A15Mn6Cr powder after exposure to a humid atmosphere
92. Chapter 87. The creep behaviour of rapidly solidified Al–Zr–V alloys at low stresses
93. Chapter 88. The microstructure and properties of rapidly solidified Al–Hf alloys
94. Chapter 89. Microhardness measurement of individual Al–Mn–Cr powder particles produced by rapid solidification
95. Chapter 90. Metastable phase formation in thin film reactions
96. Chapter 91. Electron diffraction investigations on new metastable solid solutions in quenched condensed V–Ag and Nb–Ag films
97. Chapter 92. Preparation of high Tc thallium-based superconducting films from cocondensed amorphous metal precursors
98. Chapter 93. Crystallization of amorphous thin films during heavy-ion irradiation
99. Chapter 94. Preparation of aluminum thin films by the facing targets sputtering system
100. Chapter 95. Microstructure and thermal stability of TbFeCo thin films prepared by plasma-free sputtering
101. Chapter 96. Atomic diffusion in thin film reactions
102. Chapter 97. The viscosity of amorphous metallic thin films
103. Chapter 98. Characterization of the banded structure in rapidly solidified Al–Cu alloys
104. Chapter 99. Solidification microstructures induced by laser surface alloying: influence of the substrate
105. Chapter 100. Formation and stability of magnetron sputtered Al–TM–RE metallic glasses
106. Chapter 101. Crystal orientation in titanium thin films deposited by the sputtering method without plasma damage
107. Chapter 102. Preparation of amorphous carbon films as protective layer by FTS system
108. Chapter 103. Microstructure of stainless steel films utilizable for magnetic recording
109. Chapter 104. Control of morphology and crystallinity of chromium sputtered film
110. Chapter 105. Thin films of mechanically hardened Fe–Mo–B–Cr–Ni alloys deposited by the facing targets sputtering method
111. Chapter 106. Amorphization by mechanical alloying and by solid-state reaction: Similarities and differences
112. Chapter 107. Atomic disorder in intermetallic compounds by mechanical attrition
113. Chapter 108. Characterization of AlNi formed by a self-sustaining reaction during mechanical alloying
114. Chapter 109. Nanocrystalline alloys prepared by mechanical alloying and ball milling
115. Chapter 110. Temperature dependence of mechanical alloying and grinding in Ni–Zr, Cu–Ta and Fe–B alloy systems
116. Chapter 111. Amorphization in Fe–metalloid systems by mechanical alloying
117. Chapter 112. Formation of a super-saturated solid solution in the Ag–Cu system by mechanical alloying
118. Chapter 113. Application of surface active substances in mechanical alloying
119. Chapter 114. Universal high performance ball-milling device and its application for mechanical alloying
120. Chapter 115. The contribution of strain and plastic deformations to the amorphization reaction of Ni–Zr alloys by mechanical alloying
121. Chapter 116. High-resolution electron microscopy study of Ni–Mo nanocrystals prepared by high-energy mechanical alloying
122. Chapter 117. Amorphization of soft magnetic alloys by the mechanical alloying technique
123. Chapter 118. Effects of ball milling on pure antimony, on Ga–Sb alloy and onGa + Sb powder mixture; oxidation, glass formation and crystallization
124. Chapter 119. Mechanical alloying of high melting point intermetallics
125. Chapter 120. Metastable phase transformations induced by ball-milling in the Cu–W system
126. Chapter 121. EXAFS study of the solid state amorphization process in an Fe–C alloy
127. Chapter 122. Comparison of solid-state amorphization by mechanical alloying and interdiffusion in Ni–Zr
128. Chapter 123. Ball milling mechanical alloying in the Fe100–xSix system
129. Chapter 124. Thermal behaviour of Cu–Ti and Cu–Ti–H amorphous powders prepared by ball milling
130. Chapter 125. Amorphization kinetics during cold rolling of Mg–Ni multilayers
131. Chapter 126. Mechanical alloying of the Pd–Si system. Investigation of the early and late milling stages
132. Chapter 127. Amorphization of Cu–Ta alloys by mechanical alloying
133. Chapter 128. Solid state amorphization in the Cu–Ta alloy system
134. Chapter 129. Microcrystalline or nanocrystalline grain size in two-phase alloys after mechanical alloying
135. Author Index Parts 1 (pp. 1– 858) and 2 (pp. 859 – 1421)
136. Subject Index Parts 1 (pp. 1– 858) and 2 (pp. 859 – 1421)