Physical metallurgy principles:
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| Ausgabe: | 4. ed., SI ed. |
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| Beschreibung: | XVII, 749 S. Ill., graph. Darst. |
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| 020 | |a 9780495438519 |9 978-0-495-43851-9 | ||
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| 084 | |a ZM 4000 |0 (DE-625)157033: |2 rvk | ||
| 100 | 1 | |a Abbaschian, Reza |e Verfasser |4 aut | |
| 245 | 1 | 0 | |a Physical metallurgy principles |c Reza Abbaschian ; Lara Abbaschian ; Robert E. Reed-Hill |
| 250 | |a 4. ed., SI ed. | ||
| 264 | 1 | |a Stamford, CT [u.a.] |b Cengage Learning |c 2010 | |
| 300 | |a XVII, 749 S. |b Ill., graph. Darst. | ||
| 336 | |b txt |2 rdacontent | ||
| 337 | |b n |2 rdamedia | ||
| 338 | |b nc |2 rdacarrier | ||
| 650 | 0 | 7 | |a Metallkunde |0 (DE-588)4169605-0 |2 gnd |9 rswk-swf |
| 650 | 0 | 7 | |a Metallurgie |0 (DE-588)4074756-6 |2 gnd |9 rswk-swf |
| 689 | 0 | 0 | |a Metallurgie |0 (DE-588)4074756-6 |D s |
| 689 | 0 | |5 DE-604 | |
| 689 | 1 | 0 | |a Metallkunde |0 (DE-588)4169605-0 |D s |
| 689 | 1 | |5 DE-604 | |
| 700 | 1 | |a Abbaschian, Lara |e Verfasser |4 aut | |
| 700 | 1 | |a Reed-Hill, Robert E. |e Verfasser |4 aut | |
| 856 | 4 | 2 | |m Digitalisierung UB Bayreuth |q application/pdf |u http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017712219&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |3 Inhaltsverzeichnis |
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Datensatz im Suchindex
| _version_ | 1804139346515722240 |
|---|---|
| adam_text | CHAPTER
1
CHAPTER
2
CHAPTER
3
Contents
THE STRUCTURE OF METALS
1.1
The Structure of Metals,
1 1.2
Unit Cells,
2 1.3
The Body-Centered
Cubic Structure (BCC),
3 1.4
Coordination Number of the Body-Centered Cubic
Lattice,
4 1.5
The Face-Centered Cubic Lattice (FCC),
4 1.6
The Unit Cell of the
Hexagonal Closed-Packed (HCP) Lattice,
5 1.7
Comparison of the Face-
Centered Cubic and Close-Packed Hexagonal Structures,
6 1.8
Coordination
Number of the Systems of Closest Packing,
7 1.9
Anisotropy,
7 1.10
Textures or
Preferred Orientations,
8 1.11
Miller Indices,
9 1.12
Crystal Structures of the
Metallic Elements,
14 1.13
The
Stereographic
Projection,
15 1.14
Directions
that Lie in a Plane,
16 1.15
Planes of a Zone,
17 1.16
The
Wulff
Net,
17
1.17
Standard Projections,
21 1.18
The Standard
Stereographic
Triangle for
Cubic Crystals,
24
Problems,
26
References,
28
CHARACTERIZATION TECHNIQUES
29
2.1
The Bragg Law,
30 2.2 Laue
Techniques,
33 2.3
The Rotating-Crystal
Method,
35 2.4
The Debye-Scherrer or Powder Method,
36 2.5
The X-Ray
Diffractometer,
39 2.6
The Transmission Electron Microscope,
40
2.7
Interactions Between the Electrons in an Electron Beam and a Metallic
Specimen
46 2.8
Elastic Scattering,
46 2.9
Inelastic Scattering,
46
2.10
Electron Spectrum,
48 2.11
The Scanning Electron Microscope,
48
2.12
Topographic Contrast,
50 2.13
The Picture Element Size,
53 2.14
The
Depth of Focus,
54 2.15
Microanalysis of Specimens,
55 2.16
Electron Probe
Х
-Ray Microanalysis,
55 2.17
The Characteristic X-Rays,
56 2.18
Auger*
Electron Spectroscopy (AES),
58 2.19
The Scanning Transmission Electron
Microscope (STEM),
60
Problems,
60
References
61
CRYSTAL BINDING
62
3.1
The Internal Energy of a Crystal,
62 3.2
Ionic Crystals,
62 3.3
The Born
Theory
oí
ionic Crystals,
63 3.4
Van
Der Waals
Crystals,
68 3.5
Dipoles,
68
3.6
Inert Cases,
69 3.7
Induced Dipoles,
70 3.8
The Lattice Energy of an
Inert-Gas Solid,
71 3.9
The Debye Frequency,
72 3.10
The Zero-Point
Energy,
73 3.11
Dipole-Quadrupole and Quadrupole-Quadrupole Terms,
75
3.12
Molecular Crystals,
75 3.13
Refinements to the Born Theory of Ionic
Crystals,
75 3.14
Covalent and Metallic Bonding,
76
Problems
80
References,
81
VII
Vlil
Contents
CHAPTER
4
CHAPTER
S
CHAPTER
6
INTRODUCTION TO DISLOCATIONS
82
4.1
The Discrepancy Between the Theoretical and Observed Yield Stresses of
Crystals,
82 4.2
Dislocations,
85 4.3
The Burgers Vector,
93 4.4
Vector
Notation for Dislocations,
95 4.5
Dislocations in the Face-Centered Cubic
Lattice,
96 4.6
Intrinsic and Extrinsic Stacking Faults in Face-Centered Cubic
Metals,
101 4.7
Extended Dislocations in Hexagonal Metals,
102 4.8
Climb of
Edge Dislocations,
102 4.9
Dislocation Intersections,
104 4.10
The Stress Field
of a Screw Dislocation,
107 4.11
The Stress Field of an Edge Dislocation,
109
4.12
The Force on a Dislocation, 111
4.13
The Strain Energy of a Screw
Dislocation,
114 4.14
The Strain Energy of an Edge Dislocation,
115
Problems,
116
References,
118
DISLOCATIONS AND PLASTIC DEFORMATION
119
5.1
The Frank-Read Source,
119 5.2
Nucleation of Dislocations,
120 5.3
Bend
Gliding,
123 5.4
Rotational Slip,
125 5.5
Slip Planes and Slip Directions,
127
5.6
Slip Systems,
129 5.7
Critical Resolved Shear Stress,
129 5.8
Slip on
Equivalent Slip Systems,
133 5.9
The Dislocation Density,
133 5.10
Slip
Systems in Different Crystal Forms,
133 5.11
Cross-Slip,
138 5.12
Slip
Bands,
141 5.13
Double Cross-Slip,
141 5.14
Extended Dislocations and
Cross-Slip,
143 5.15
Crystal Structure Rotation During Tensile and
Compressive
Deformation,
144 5.16
The Notation for the Slip Systems in
the Deformation of FCC Crystals,
147 5.17
Work Hardening,
149 5.18
Considère s
Criterion,
150 5.19
The Relation Between Dislocation Density and
the Stress,
151 5.20
Taylor s Relation,
153 5.21
The Orowan Equation,
153
Problems,
154
References,
157
ELEMENTS OF GRAIN BOUNDARIES
158
6.1
Grain Boundaries,
158 6.2
Dislocation Model of a Small-Angle Grain
Boundary,
159 6.3
The Five Degrees of Freedom of a Grain Boundary,
161
6.4
The Stress Field of a Grain Boundary,
162 6.5
Grain-Boundary
Energy,
165 6.6
Low-Energy Dislocation Structures,
LEDS, 167 6.7
Dynamic
Recovery,
170 6.8
Surface Tension of the Grain Boundary,
172
6.9
Boundaries Between Crystals of Different Phases,
175 6.10
The Grain
Size,
178 6.11
The Effea of Grain Boundaries on Mechanical Properties:
Hall-Petch Relation,
180 6.12
Grain Size Effects in Nanocrystalline
Materials,
182 6.13
Coincidence Site Boundaries,
185 6.14
The Density of
Coincidence Sites,
186 6.15
The Ranganathan Relations,
186 6.16
Examples
Involving Twist Boundaries,
187 6.17
Tilt Boundaries,
189
Problems,
192
References,
193
CHAPTER
7
VACANCIES
194
7.1
Thermal Behavior of Metals,
194 7.2
Internal Energy,
195 7.3
Entropy,
196
7.4
Spontaneous Reactions,
196 7.5
Gibbs Free Energy,
197
Contents
IX
CHAPTER
8
CHAPTER
9
7.6
Statistical Mechanical Definition of Entropy,
199 7.7
Vacancies,
203
7.8
Vacancy Motion,
209 7.9
Interstitial Atoms and Divacancies,
211
Problems,
214
References,
215
ANNEALING
216
8.1
Stored Energy of Cold Work,
216 8.2
The Relationship of Free Energy to
Strain Energy,
217 8.3
The Release of Stored Energy,
218 8.4
Recovery,
220
8.5
Recovery in Single Crystals,
221 8.6
Polygonization,
223 8.7
Dislocation
Movements in Polygonization,
226 8.8
Recovery Processes at High and Low
Temperatures,
229 8.9
Recrystallization,
230 8.10
The Effect of Time and
Temperature on Recrystallization,
230 8.11
Recrystallization Temperature,
232
8.12
The Effect of Strain on Recrystallization,
233 8.13
The Rate of Nucleation
and the Rate of Nucleus Growth,
234 8.14
Formation of Nuclei,
235
8.15
Driving Force for Recrystallization,
237 8.16
The Recrystallized
Grain Size
237 8.17
Other Variables in Recrystallization,
239 8.18
Purity
of the Metal,
239 8.19
Initial Grain Size,
240 8.20
Grain Growth,
240
8.21,
Geometrical Coalescence,
243 8.22
Three-Dimensional Changes in Grain
Geometry,
244 8.23
The Grain Growth Law,
245 8.24
Impurity Atoms in
Solid Solution,
249 8.25
Impurities in the Form of Inclusions,
250 8.26
The
Free-Surface Effects,
253 8.27
The Limiting Grain Size,
254 8.28
Preferred
Orientation,
256 8.29
Secondary Recrystallization,
256 8.30
Strain-Induced
Boundary Migration
257
Problems,
258
References,
259
SOLID SOLUTIONS
261
9.1
Solid Solutions,
261 9.2
Intermediate Phases,
261 9.3
Interstitial Solid
Solutions,
262 9.4
Solubility of Carbon in Body-Centered Cubic Iron,
263
9.5
Substitutional Solid Solutions and the Hume-Rothery Rules,
267
9.6
Interaction of Dislocations and Solute Atoms,
267 9.7
Dislocation
Atmospheres,
268 9.8
The Formation of a Dislocation Atmosphere,
269
9.9
The Evaluation of A,
270 9.10
The Drag of Atmospheres on Moving
Dislocations,
271 9.11
The Sharp Yield Point and
Lüders
Bands,
273 9.12
The
Theory of the Sharp Yield Point,
275 9.13
Strain Aging,
276 9.14
The
Cottrell-Bilby Theory of Strain Aging,
277 9.15
Dynamic Strain Aging
282
Problems,
285
References,
286
CHAPTER
IO
PHASES
287
10.1
Basic Definitions,
287 10.2
The Physical Nature of Phase Mixtures,
289
10.3
Thermodynamics of Solutions,
289 10.4
Equilibrium Between Two
Phases,
292 10.5
The Number of Phases in an Alloy System,
293 10.6
Two-
Component Systems Containing Two Phases,
303 10.7
Graphical
Determinations of Partial-Molal Free Energies,
304 10.8
Two-Component
Systems with Three Phases in Equilibrium,
306 10.9
The Phase Rule,
307
10.10
Ternary Systems,
309
Problems,
310
References,
311
X
Contents
CHAPTER
1 1
BINARY PHASE DIAGRAMS
312
11.1
Phase Diagrams,
312 11.2
Isomorphous Alloy Systems,
312 11.3
The Lever
Rule,
314 11.4
Equilibrium Heating or Cooling of an Isomorphous Alloy,
317
11.5
The Isomorphous Alloy System from the Point of View of Free Energy,
319
11.6
Maxima and Minima,
320 11.7
Superlattices,
322 11.8
Misdbility
Gaps,
326 11.9
Eutectic Systems,
328 11.10
The
Microstructures
of Eutectic
Systems,
329 11.11
The Peritectic Transformation,
334 11.12
Monotectics,
337
11.13
Other Three-Phase Reactions,
338 11.14
Intermediate Phases,
339
11.15
The Copper-Zinc Phase Diagram,
341 11.16
Ternary Phase Diagrams,
343
Problems,
346
References,
347
CHAPTER
12
DIFFUSION IN SUBSTITUTION
AL
SOLID SOLUTIONS
348
12.1
Diffusion in an Ideal Solution,
348 12.2
The Kirkendall Effect,
352
12.3
Pore Formation,
355 12.4
Darken s Equations,
357 12.5
Fick s Second
Law,
360 12.6
The Matano Method,
363 12.7
Determination of the Intrinsic
Diffusivities,
366 12.8
Self-Diffusion in Pure Metals,
368 12.9
Temperature
Dependence of the Diffusion Coefficient,
370 12.10
Chemical Diffusion at
Low-Solute Concentration,
372 12.11
The Study of Chemical Diffusion
Using Radioactive Tracers,
374 12.12
Diffusion Along Grain Boundaries and
Free Surfaces,
377 12.13
Fick s First Law in Terms of a Mobility and an
Effective Force,
380 12.14
Diffusion in Non-Isomorphic Alloy Systems,
382
Problems,
386
References,
388
CHAPTER
13
INTERSTITIAL DIFFUSION
389
13.1
Measurement of Interstitial Diffusivities,
389 13.2
The
Snoek
Effect,
391
13.3
Experimental Determination of the Relaxation Time,
398 13.4
Experimental Data,
405 13.5
Anelastic Measurements at Constant Strain,
405
Problems,
406
References,
407
CHAPTER
14
SOLIDIFICATION OF METALS
4O8
14.1
The Liquid Phase,
408 14.2
Nucleation,
411 14.3
Metallic Glasses,
413
14.4
Crystal Growth from the Liquid Phase,
420 14.5
The Heats of Fusion
and Vaporization,
421 14.6
The Nature of the Liquid-Solid Interface,
423
14.7
Continuous Growth,
425 14.8
Lateral Growth,
427 14.9
Stable
Interface Freezing,
428 14.10
Dendritic Growth in Pure Metals,
429
14.11
Freezing in Alloys with Planar Interface,
432 14.12
The Scheil
Equation,
434 14.13
Dendritic Freezing in Alloys,
437 14.14
Freezing of Ingots,
439 14.15
The Grain Size of Castings,
443 14.16
Segregation,
443
14.17
Homogenization
445 14.18
Inverse Segregation,
450 14.19
Porosity,
450
14.20
Eutectic Freezing,
454
Problems,
459
References,
461
Contents
XI
CHAPTER
15
NUCLEATION AND GROWTH KINETICS
463
CHAPTER
16
CHAPTER
17
15.1
Nucleation of a Liquid from the Vapor,
463 15.2
The
Becker-Döring
Theory,
471 15.3
Freezing,
473 15.4
Solid-State Reactions,
475
15.5
Heterogeneous Nucleation,
478 15.6
Growth Kinetics,
481 15.7
Diffusion Controlled Growth,
484 15.8
Interference of Growing Precipitate
Particles,
488 15.9
Interface Controlled Growth,
488 15.10
Transformations
That Occur on Heating,
492 15.11
Dissolution of a Precipitate,
493
Problems,
495
References,
497
PRECIPITATION HARDENING
498
16.1
The Significance of the Solvus Curve,
499 16.2
The Solution Treatment,
500
16.3
The Aging Treatment,
500 16.4
Development of Precipitates,
503
16.5
Aging of Al-Cu Alloys at Temperatures Above 100°C
(373
K),
506
16.6
Precipitation Sequences in Other Aluminum Alloys,
509 16.7
Homogeneous Versus Heterogeneous Nucleation of Precipitates,
511
16.8
Interphase
Precipitation,
512 16.9
Theories of Hardening,
515
16.10
Additional Factors in Precipitation Hardening,
516
Problems,
518
References,
519
DEFORMATION TWINNING AND MARTENSITE REACTIONS
521
17.1
Deformation Twinning,
521 17.2
Formal Crystallographic Theory
of Twinning,
524 17.3
Twin Boundaries,
530 17.4
Twin Growth,
531
17.5
Accommodation of the Twinning Shear,
533 17.6
The Significance of
Twinning in Plastic Deformation,
534 17.7
The Effect of Twinning on Face-
Centered Cubic Stress-Strain Curves,
535 17.8
Martensite,
537 17.9
The Bain
Distortion,
538 17.10
The Martensite Transformation in an Indium-Thallium
Alloy,
540 17.11
Reversibility of the Martensite Transformation,
541
17.12
Athénnal
Transformation,
541 17.13
Phenomenological Crystallographic
Theory of Martensite Formation,
542 17.14
Irrational Nature of the Habit Plane,
548 17.15
The Iron-Nickel Martensitic Transformation,
549
17.16
Isothermal Formation of Martensite,
551 17.17
Stabilization,
551
17.18
Nucleation of Martensite Plates,
552 17.19
Growth of Martensite
Plates,
553 17.20
The Effect of Stress,
553 17.21
The Effect of Plastic
Deformation,
554 17.22
Thermoelastic Martensite Transformations,
554
17.23
Elastic Deformation of Thermoelastic Alloys,
556 17.24
Stress-Induced
Martensite (SIM),
556 17.25
The Shape-Memory Effect,
557
Problems,
559
References,
560
CHAPTER
18
THE IRON-CARBON ALLOY SYSTEM
562
18.1
The Iron-Carbon Diagram,
562 18.2
The Proeutectoid Transformations of
Austenite,
565 18.3
The Transformation of Austenite to Pearlite,
566 18.4
The
Growth of Pearlite,
572 18.5
The Effect of Temperature on the Pearlite
XII
Contents
Transformation,
573 18.6
Forced-Velocity Growth of Pearlite,
575 18.7
The
Effects of Alloying Elements on the Growth of Pearlite,
578 18.8
The Rate of
Nucleation of Pearlite,
581 18.9
Time-Temperature-Transformation Curves,
583
18.10
The Bainite Reaction,
584 18.11
The Complete T-T-T Diagram
of an Eutectoid Steel,
591 18.12
Slowly Cooled Hypoeutectoid
Steels,
593 18.13
Slowly Cooled Hypereutectoid Steels,
595 18.14
Isothermal
Transformation Diagrams for Noneutectoid Steels,
597
Problems,
600
References,
602
CHAPTER
19
THE HARDENING OF STEEL
6ОЗ
19.1
Continuous Cooling Transformations (CCT),
603 19.2
Hardenability,
606
19.3
The Variables that Determine the Hardenability of a Steel,
614
19.4
Austenitic Grain Size,
614 19.5
The Effect of Austenitic Grain Size on
Hardenability,
615 19.6
The Influence of Carbon Content on Hardenability,
615
19.7
The Influence of Alloying Elements on Hardenability,
616
19.8
The Significance of Hardenability,
621 19.9
The Martensite
Transformation in Steel,
622 19.10
The Hardness of Iron-Carbon
Martensite,
627 19.11
Dimensional Changes Associated with Transformation of
Martensite,
631 19.12
Quench Cracks,
632 19.13
Tempering,
633 19.14
Tempering of a Low-Carbon Steel,
639 19.15
Spheroidized
Cementite,
641
19.16
The Effect of Tempering on Physical Properties,
643 19.17
The
Interrelation Between Time and Temperature in Tempering,
646 19.18
Secondary Hardening,
646
Problems,
647
References,
649
CHAPTER 2O SELECTED NONFERROUS ALLOY SYSTEMS
6бТ
20.1
Commercially Pure Copper,
651 20.2
Copper Alloys,
654 20.3
Copper
Beryllium,
658 20.4
Other Copper Alloys,
659 20.5
Aluminum Alloys,
659
20.6
Aluminum-Lithium Alloys,
660 20.7
Titanium Alloys,
668
20.8
Classification of Titanium Alloys,
670 20.9
The Alpha Alloys,
670
20.10
The Beta Alloys,
676 20.11
The Alpha-Beta Alloys,
677
20.12
Superalloys,
679 20.13
Creep Strength,
680
Problems,
683
References,
684
CHAPTER
21
FAILURE OF METALS
686
21.1 Faüure
by Easy
Güde, 686 21.2
Rupture by Necking (Multiple Glide),
688
21.3
The Effect of Twinning,
689 21.4
Cleavage,
690 21.5
The
Nucleation of Cleavage Cracks,
691 21.6
Propagation of Cleavage Cracks,
693
21.7
The Effect of Grain Boundaries,
696 21.8
The Effect of the State of
Stress,
698 21.9
Ductile Fractures,
700 21.10
Intercrystalline Brittle
Fracture,
705 21.11
Blue Brittleness,
705 21.12
Fatigue Failures,
706
21.13
The Macroscopic Character of Fatigue Failure,
706 21.14
The Rotating-
Beam Fatigue Test,
708 21.15
Alternating Stress Parameters,
710 21.16
The
Microscopic Aspects of Fatigue Failure,
713 21.17
Fatigue Crack Growth,
717
21.18
The Effect of Nonmetallic Inclusions,
720 21.19
The Effect of Steel
Contents XIII
Microstructure
on
Fatigue,
721 21.20
Low-Cycle
Fatigue,
721 21.21
The
C of fin-Manson
Equation,
726 21.22
Certain
Practical
Aspects
of
Fatigue,
727
Problems,
728
References,
729
APPENDICES
731
A angles
Between Crystallographic Planes in the
Cubic System* (In degrees),
731
В
angles Between crystallographic Planes for
HEXAGONAL ELEMENTS*,
733
С
INDICES OF THE REFLECTING PLANES FOR CUBIC STRUCTURES,
734
D
Conversion Factors and Constants,
734
E
Twinning Elements of Several of the more
Important Twinning Modes,
735
F
Selected Values of intrinsic Stacking-Fault Energy yp
Twin-Boundary Energy yT, Grain-Boundary Energy yG,
and Crystal-Vapor Surface Energy
y
for Various
MATERIALS IN ERGS/CM2*,
735
LIST OF IMPORTANT SYMBOLS
737
LIST OF GREEK LETTER SYMBOLS
739
INDEX
74О
|
| any_adam_object | 1 |
| author | Abbaschian, Reza Abbaschian, Lara Reed-Hill, Robert E. |
| author_facet | Abbaschian, Reza Abbaschian, Lara Reed-Hill, Robert E. |
| author_role | aut aut aut |
| author_sort | Abbaschian, Reza |
| author_variant | r a ra l a la r e r h rer rerh |
| building | Verbundindex |
| bvnumber | BV035657750 |
| classification_rvk | UQ 7000 ZM 4000 |
| ctrlnum | (OCoLC)475780878 (DE-599)GBV606798358 |
| dewey-full | 669.9 |
| dewey-hundreds | 600 - Technology (Applied sciences) |
| dewey-ones | 669 - Metallurgy |
| dewey-raw | 669.9 |
| dewey-search | 669.9 |
| dewey-sort | 3669.9 |
| dewey-tens | 660 - Chemical engineering |
| discipline | Chemie / Pharmazie Physik Werkstoffwissenschaften / Fertigungstechnik |
| edition | 4. ed., SI ed. |
| format | Book |
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| id | DE-604.BV035657750 |
| illustrated | Illustrated |
| indexdate | 2024-07-09T21:42:37Z |
| institution | BVB |
| isbn | 9780495438519 0495438510 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-017712219 |
| oclc_num | 475780878 |
| open_access_boolean | |
| owner | DE-703 DE-29T DE-83 |
| owner_facet | DE-703 DE-29T DE-83 |
| physical | XVII, 749 S. Ill., graph. Darst. |
| publishDate | 2010 |
| publishDateSearch | 2010 |
| publishDateSort | 2010 |
| publisher | Cengage Learning |
| record_format | marc |
| spelling | Abbaschian, Reza Verfasser aut Physical metallurgy principles Reza Abbaschian ; Lara Abbaschian ; Robert E. Reed-Hill 4. ed., SI ed. Stamford, CT [u.a.] Cengage Learning 2010 XVII, 749 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Metallkunde (DE-588)4169605-0 gnd rswk-swf Metallurgie (DE-588)4074756-6 gnd rswk-swf Metallurgie (DE-588)4074756-6 s DE-604 Metallkunde (DE-588)4169605-0 s Abbaschian, Lara Verfasser aut Reed-Hill, Robert E. Verfasser aut Digitalisierung UB Bayreuth application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017712219&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis |
| spellingShingle | Abbaschian, Reza Abbaschian, Lara Reed-Hill, Robert E. Physical metallurgy principles Metallkunde (DE-588)4169605-0 gnd Metallurgie (DE-588)4074756-6 gnd |
| subject_GND | (DE-588)4169605-0 (DE-588)4074756-6 |
| title | Physical metallurgy principles |
| title_auth | Physical metallurgy principles |
| title_exact_search | Physical metallurgy principles |
| title_full | Physical metallurgy principles Reza Abbaschian ; Lara Abbaschian ; Robert E. Reed-Hill |
| title_fullStr | Physical metallurgy principles Reza Abbaschian ; Lara Abbaschian ; Robert E. Reed-Hill |
| title_full_unstemmed | Physical metallurgy principles Reza Abbaschian ; Lara Abbaschian ; Robert E. Reed-Hill |
| title_short | Physical metallurgy principles |
| title_sort | physical metallurgy principles |
| topic | Metallkunde (DE-588)4169605-0 gnd Metallurgie (DE-588)4074756-6 gnd |
| topic_facet | Metallkunde Metallurgie |
| url | http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=017712219&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA |
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