PUBLICATIONS
Peer Reviewed Journal Papers:
1.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Shape
Evolution of a Precipitate During Strain-induced Coarsening - A
Computer Simulation", Script. Metall. et Mater., 25, 1387 (1991).
2.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Strain-induced
Modulated Structures in Two-phase Cubic Alloys", Script. Metall. et Mater.,
25, 1969 (1991).
3.
L. Q. Chen, Y.
Wang and A. G. Khachaturyan, "Transformation-induced Elastic Strain
Effect on Precipitation Kinetics of Ordered Intermetallics", Phil.
Mag. Lett., 64, 241(1991).
4.
L. Q. Chen, Y.
Wang and A. G. Khachaturyan, "Kinetics of Tweed and Twin Formation in
an Ordering Transition", Phil. Mag. Lett., 65, 15 (1992).
5.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Particle
Translational Motion and Reverse Coarsening Phenomena in Multiparticle Systems
Induced by a Long-Range Elastic Interaction", Phy. Rev. B, 46, 11194 (1992).
6.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Kinetics of
Strain-Induced Morphological Transformation in Cubic Alloys with a Miscibility
Gap", Acta Metall. et Mater., 41,
279 (1993).
7.
Y. Wang, H. Y. Wang, L. Q. Chen and A. G. Khachaturyan,
"Shape Evolution of a Coherent Tetragonal Precipitate in Partially
Stabilized Cubic ZrO2", J. Am. Ceram. Soc., 76, 3029 (1993).
8.
Y. Wang and A. G. Khachaturyan, "Effect of Antiphase
Domains on Shape and Spatial Arrangement of Coherent Ordered
Intermetallics", Scripta Metall. et Mater., 31,
1425 (1994).
9.
A. G.
Khachaturyan, Y. Wang and H. Y. Wang, "Metastable Phase and Nuclei:
Computer Modeling", Materials Science Forum, 155-156,
345 (1994).
10.
Y. Wang and A. G. Khachaturyan, "Shape Instability
during Precipitate Growth in Coherent Solids", Acta Metall. et Mater. 43,
1837 (1995).
11.
Y. Wang, H. Y. Wang, L. Q. Chen and A. G. Khachaturyan,
"Microstructural Development of Coherent Tetragonal Precipitates in
Mg-Partially Stabilized Zirconia: A Computer Simulation", J.
Am. Ceram. Soc., 78,
657 (1995).
12.
Y. Wang and A. G. Khachaturyan, "Microstructural
Evolution during Precipitation of Ordered Intermetallics in Multi-Particle
Coherent Systems", Phil. Mag. A, 72, 1161 (1995).
13.
Y. H. Wang, Y.
Wang, A. G. Khachaturyan, and T. Tsakalakos, "Indirect Nucleation in
Phase Transformations with Symmetry Reduction", Phil. Mag. A. 74, 1407-1420 (1996).
14.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Three
Dimensional Dynamic Calculation of the Equilibrium Shape of a Coherent
Tetragonal Precipitate in Mg-Partially Stabilized Cubic ZrO2", J.
Am. Ceram. Soc. 79, 987 (1996).
15.
L. Q. Chen and Y.
Wang, “The Continuum Field Approach to Modeling Microstructural
Evolution,” JOM, pp13-18, Vol. 48, No 12, 1996.
16.
Y. Wang and A. G. Khachaturyan, "Three-Dimensional Field
Model and Computer Modeling of Martensitic Transformation", Acta
Metall. et Mater , 45,
759-773 (1997).
17.
Y. Wang, D. Banerjee, C. C. Su and A. G. Khachaturyan,
“Field Kinetic Model and Computer Simulation of Precipitation of L12
ordered Intermetallic from FCC Solid Solution, Acta Mater, 46, 2983-3001 (1998).
18.
C. Ciobanu, Y.
Liu, Y. Wang and B. Patton, “Numerical Calculation of Electrical
Conductivity of Porous Electroceramics”, J. Electroceramics, 3:1,15-22
(1999).
19.
A. Kazaryan, Y.
Wang and B. R. Patton, “Generalized Phase Field Approach for Computer
Simulation of Sintering: Incorporation of Rigid-Body Motion,” Scripta
mater. 41, 487-492 (1999).
20.
D. Banerjee,
21.
Y. H. Wen, Y.
Wang and L. Q. Chen, “Effect of Elastic Interaction on the Formation
of Complex Multi-Domain Microstructural Pattern during a Coherent Hexagonal to
Orthorhombic Transformation,”, Acta mater. 47, 4375 (1999).
22.
Y. Wang, Y. Liu, C. Ciobanu, and B. R. Patton,
“Simulating Microstructural Evolution and Electrical Transport in Ceramic
Gas Sensors,” J. Am. Ceram. Soc., 83, 2219-26 (2000).
23.
Y. H. Wen, Y.
Wang and L. Q. Chen, “Phase Field Simulation of Domain Structure
Evolution during a Coherent Hexagonal to Orthorhombic Transformation,” Phil.
Mag. A80, No. 9, 1967-1982 (2000).
24.
J. P. Simmons, C.
Chen and Y. Wang, “Phase Field Modeling of Simultaneous Nucleation
and Growth by Explicitly Incorporating Nucleation Events,” Scripta
mater. 43, 935-942 (2000).
25.
A. Kazanyan, Y.
Wang, S. A. Dregia and B. P. Patton, “Generalized Phase-Field Model
for Computer Simulation of Grain Growth in Anisotropic Systems.” Phys.
Rev. B61, 14275 – 14278 (2000).
26.
Y. H. Wen, Y.
Wang, L. A. Bendersky and L. Q. Chen. “Microstructural Evolution
during Precipitation of an Orthorhombic Phase in a Hexagonal Matrix in Ti-Al-Nb
System: Phase-Field Simulation and Experimental Validation.” Acta
mater. 48, 4125-4135 (2000).
27.
A. Antemov, Y.
Wang and A. G. Khachaturyan, “Three-Dimensional Phase Field Model and
Simulation of Martensitic Transformations in Multilayer System under Applied
Stress,” Acta mater. 48, 2503
(2000).
28.
S. Chwieroth, B.
R. Patton and Y. Wang, “Conduction and Gas – Surface
Reaction Modeling in TiO2-x CO Cas Sensors.” J. Electroceramics 6(1),
27-41
(2001).
29.
Y. H. Wen, Y.
Wang, and L. Q. Chen. “Influence of an Applied Strain Field on
Microstructural Evolution during a2 à O-phase Transformation in
Ti-Al-Nb System,” Acta mater. 49, 13-20 (2001).
30.
Y. H. Wen, L. Q.
Chen, P. M. Hazzledine and Y. Wang, “A Three-Dimensional Phase
Field Model for Computer Simulation of Lamellar Structure Formation in
TiAl Intermetallic Alloys.” Acta mater. 49, 2341-2353 (2001).
31.
A. Kazaryan, Y.
Wang, S. A. Dregia and B. R. Patton, “Grain Growth in Systems with
Anisotropic Boundary Mobility: Analytical Model and Computer Simulation,”
Phy.
Rev. B. 63, 1841021 (2001).
32.
K. Wu, J. E.
Marrol and Y. Wang, “A Phase Field Study of Microstructural
Changes due to the Kirkendall Effect in Two-Phase Diffusion Couples,” Acta
mater. 49, 3401 – 3408
(2001).
33.
Y. H. Wen, Y.
Wang, and L. Q. Chen, “Coarsening Dynamics of Self-Accommodating
Coherent Patters,” Acta mater. 50, 13-21 (2002).
34.
A. Kazaryan, B.
R. Patton, S. A. Dregia and Y. Wang, ”On the Theory of Grain
Growth in Systems with Anisotropic Boundary Mobility,” Acta
mater. 50, 499-510 (2002).
35.
A. Kazaryan, Y.
Wang, S. A. Dregia and B. R. Patton, “Grain Growth in Anisotropic
Systems: Comparison of Effect of Energy and Mobility,” Acta
mater. 50, 2491-2502 (2002).
36.
M. Upmanyu, G.
Hassold, A. Kazaryan, E. Holm, Y. Wang and D. J. Srolovitz,
“Microstructural Evolution during Grain Growth in Anisotropic Thin
Films,” Interface Science, 10,
201 – 216 (2002).
37.
A. Kazaryan, Y.
Wang Y. M. Jin, Yu. U. Wang, A. G. Khachaturyan and D.
38.
Y. M. Jin, Yu. U.
Wang, A. Kazaryan, Y. Wang, D. E. Langhlin and A. G. Khachaturyan, “Magnetic Structure and Hysteresis in
Hard Magnetic Nanocrystalline Film: Computer Simulations,” J.
App. Phys. 92, 6172 – 6181 (2002).
39.
Y. H. Wen, J. P.
Simmons, C. Shen, C. Woodward and Y. Wang, “Phase Field Modeling
of Bimodal Particle Size Distributions during Continuous Cooling,” Acta
mater. 51, 1123-1132 (2003).
40.
C. Shen and Y.
Wang, “Modeling Dislocation Network and Dislocation –
Precipitate Interaction at Mesoscopic Scale Using Phase Field Method,”
Int. J.
Multiscale Computational
41.
C. Shen and Y.
Wang, “Phase Field Model of Dislocation Networks,” Acta
mater. 51, 2595 – 2610
(2003).
42.
N. Ma, S. A.
Dregia and Y. Wang, “Segregation
Transition and Drag Force at Grain Boundaries,” Acta mater. 51, 3687-3700
(2003).
43.
L.S. Wang, D.E.
Laughlin, Y. Wang and A.G. Khachaturyan, “Magnetic domain structure of Fe-55 at. %Pd alloy at
different stages of atomic ordering,” J Appl. Phys. 93, 7984-7986 (2003).
44.
J. P. Simmons, Y.
H. Wen, C. Shen and Y. Wang, “Microstructural Development
Involving Nucleation and Growth Phenomena Simulated with the Phase Field
Method,” Mat. Sci.
45.
M. Huang, Y. A.
Chang and Y. Wang, “Grain Growth in Sputtered Nanoscale PdIn Thin
Films,” Thin Solid Films 449/1-2,
113-119 (2004).
46.
Q. Chen, N. Ma,
K. Wu and Y. Wang, “Quantitative Phase Field Modeling of
Diffusion-Controlled Precipitate Growth and Dissolution in Ti-6Al-4V,” Scripta
mater. 50:471-476 (2004).
47.
C. Shen, Q. Chen,
Y. Wen, J. P. Simmons and Y. Wang, “Increasing Length Scale of
Quantitative Phase Field Modeling of Growth-Dominant or Coarsening-Dominant
Process,” Scripta mater. 50:1023-1028 (2004).
48.
C. Shen, Q. Chen,
Y. Wen, J. P. Simmons and Y. Wang, “Increasing Length Scale of
Quantitative Phase Field Modeling of Concurrent Growth and Coarsening
Processes,” Scripta mater. 50:1029-1034 (2004).
49.
K. Wu, Y. A. Chang
and Y. Wang, “Simulating Interdiffusion Microstructure in Ni-Al-Cr
Diffusion Couples: A Phase Field Approach Coupled with CALPHAD Database,”
Scripta
mater. 50:1145-1150 (2004).
50.
C. Shen and Y.
Wang, “Incorporation of g-Surface to Phase
Field Model of Dislocations: Simulating Dissociation of Dislocations in f.c.c.
51.
K. Wu, J. E.
Morral and Y. Wang, “Movement of Kirkendall Markers, Second Phase
Particles and Type 0 Boundary in Two-Phase Diffusion Couple Simulations,”
Acta
Mater. 52:1917-1925 (2004).
52.
N. Ma, A.
Kazaryan, S. A. Dregia and Y. Wang, “Computer Simulation of
Texture Development during Grain Growth: Effect of Boundary Properties and
Initial Microstructure,” Acta mater. 52:3869-3879 (2004).
53.
H. W. Yang, J. E.
Morral and Y. Wang, “On Diffusion Path with “Horns”
and the Formation of Single Phase Layers in Multiphase Diffusion
Couples,” Acta Mater. 53 (2005) 3775-3781.
54.
Y. Wang, N. Ma, Q. Chen, F. Zhang, S.-L. Chen, Y. A. Chang,
“Predicting of Phase Equilibrium, Phase Transformation, and
Microstructure Evolution in Advanced Titanium Alloys,” JOM,
pp32-39 (Sept. 2005).
55.
N. Ma, C. Shen,
S. A. Dregia and Y. Wang, “Segregation and Wetting Transition at
Dislocations,” Met. Trans. A. 37A (2006) 1773-1783.
56.
Y.H. Wen, B.
Wang, J.P. Simmons and Y. Wang, “A Phase-Field Model for Heat
Treatment Applications in Ni-base Alloys, Acta Mater. 54 (2006) 2087-2099.
57.
N. Ma, Q. Chen
and Y. Wang, “Simulating Microstructural Evolution with High
Interfacial Energy Anisotropy Using the Phase Field Method”, Scripta
Mater. 54 (2006) 1919-1924.
58.
K. Wu, J. E.
Morral and Y. Wang, “Horns on Diffusion
Path in Multiphase Diffusion Couples,” Acta Mater. 54 (2006) 5501-5507.
59.
Y. Wang and A.G. Khachaturyan, “Multi-Scale Phase Field
Approach to Martensitic Transformations,” Mat. Sci.
60.
J. Gruber, N. Ma,
Y. Wang, A.D. Rollett, G.S. Rohrer, “Sparse Data Structure and
Algorithm for the Phase Field Method,” Modelling Simul. Mater. Sci.
61.
C. Shen, J. P.
Simmons and Y. Wang, “Effect of Elastic Interaction on Nucleation
– I. Calculation of Strain Energy of Nucleus Formation in Elastically
Anisotropic
62.
W. Guo, Y.P.
Zong, L. Zuo and Y. Wang, “Simulation of Effect of Applied Strain
on the Microstructure of Ti-25Al-10Nb Alloy by Phase Field Method”, Acta
Metallurgica Sinica, 42, 549 (2006).
63.
C. Shen, J. P.
Simmons and Y. Wang, “Effect of Elastic Interaction on Nucleation
– II. Simulation Study using Phase Field Method,” Acta
Mater. 55 (2007) 1457-1466.
64.
W. Luo, C. Shen and Y. Wang,
“Nucleation of Ordered Particles at Dislocations and Formation of
65.
P.M. Sarosi, B.
Wang, J.P. Simmons, Y. Wang and M.J. Mills, “Formation of
Multimodal Size Distributions of g’ in a
Nicle-Base Superalloy during Interrupted Continuous Cooling,” Scripta
Mater. 57 (2007) 767-770.
66.
N. Zhou, C. Shen,
M.J. Mills and Y. Wang, “Phase Field Modeling of Channel
Dislocation Activity and g’ Rafting in Single Crystal Ni-Al,” Acta
Mater. 55 (2007) 5369-5381.
67.
C. P. Wang, X. J.
Liu, R. P. Shi, C. Shen, Y. Wang, I. Ohnuma, R. Kainuma and K. Ishida,
“Design and Formation Mechanism of Self-Organized Core/Shell Structure
Composite Powder in Immiscible Liquid Systems,” Applied Physics Letters 91
(2007), 141904.
68.
F. Zhang, S.L.
Chen, Y.A. Chang, N. Ma and Y. Wang, “Development of Thermodynamic
Description of a Pseudo Ternary System for Multicomponent Ti64 Alloy,” J.
Phase Equilib. Diffus. 28 (2007) 115.
69.
C. Shen, N. Zhou
and Y. Wang, “Phase Field Modeling of Microstructural Evolution in
Solids: Effect of Coupling among Different Extended Defects,” Met. Mat.
Trans. A. (available online DOI 10.1007/s11661-007-9266-7),
2008.
70.
C. Shen, J. Li
and Y. Wang, “Finding Critical Nucleus in
71.
B. Wang, Y.H.
Wen, J.P. Simmons and Y. Wang, “Systematic Approach to
Microstructure Design of Ni-Base Alloys Using classical Nucleation and Growth
Relations Coupled with Phase Field Modeling,” Met. Mat. Trans. A. 39A
(2008) 984-993.
72.
J.E. Morral, X.
Pan, N. Zhou, H. Larsson and Y. Wang, “Singularities in Multiphase
Diffusion Couples,” Scripta Mater. 58 (2008) 970-972.
73.
K. Wu, N. Zhou,
X. Pan, J.E. Morral and Y. Wang, “Multiphase Ni-Cr-Al Diffusion
Couple: A Comparison of Phase Field Simulations with Experimental Data,” Acta
Mater. 56 (2008) 3854-3861.
74.
N. Zhou, C. Shen, M. J. Mills and Y. Wang, "Contributions from Elastic
Inhomogeneity and from Plasticity to g¢ Rafting in Single Crystal Ni-Al," Acta Mater. 56 (2008) 6156-6173.
75.
G. Wang, D.S. Xu,
N. Ma, N. Zhou,
76.
N. Zhou, C. Shen,
P.M. Sarosi, M.J. Mills, T.M. Pollock and Y. Wang, “g¢ Rafting in Single Crystal Blade Alloys – A
Simulation Study,” Mat. Sci. Tech. (Feb. 2009).
Peer Reviewed
Articles Published in Bound Research Proceedings:
77.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Computer
Simulation of Microstructure Evolution in Coherent Solids", pp245-265 in Solid à Solid phase Transformations, Edited by W. C. Johnson, J. M. Howe, D. E. Laughlin
and W. A. Soffa, The Minerals, Metals & Materials Society, 1994.
78.
L. Q. Chen, Y.
Wang and A. G. Khachaturyan, "Morphology Transformations in Ordering
and Phase Separating Materials", pp. 587-604 in Statics and Dynamics of Alloy Phase Transformations, edited by P.
E. A. Turchi and A. Gonis, NATO ASI Series, Plenum Press, New York, 1994.
79.
Y. Wang, L. Q. Chen and A. G. Khachaturyan, "Modeling of
Dynamical Evolution of Micro/Mesoscopic Morphological Patterns in Coherent
Phase Transformations", pp325-371 in
Computer simulation in Materials Science - Nano/Meso/Macroscopic Space and Time
Scales, H. O. Kirchner, K. P. Kubin and V. Pontikis (eds.), ATO ASI Series,
Kluwer Academic Publishers, 1996.
80.
L. Q. Chen, D. N.
Fan, Y. Wang and A. G. Khachaturyan, "Continuum Diffuse-Interface
Model for Modeling Microstructural Evolutions", in Stability of Materials, NATO ASI Series, edited by A. Gonis, P. E.
A. Turchi and J. Kudrnously, Plenum Publishing Co., 1997.
81.
D. Banerjee, R.
Banerjee and Y. Wang, “An Alternating Mechanism for the Formation
of Split Patterns of g’ Precipitates in Ni-Al Alloys”, pp187-196
in Computer-Aided Design of
High-Temperature Materials, edited by A. Pechenik, R. K. Kalia and P.
Vashishta, Oxford University Press, New York, 1999.
82.
Y. H. Wen, Y.
Wang, L. Bendersky and L. Q. Chen, “Phase-Field Approach to Modeling
Microstructure Evolution during Structural Phase Transformations –
Application to Hexagonal to Orthorhombic Transformations,” pp725-732 in Solid à Solid Phase Transformations, The Japan Institute of Metals Proceedings, Vol. 12
(JIMIC) Part-I, edited by M. Koiwa, K. Otsuka and T. Miyazaki, Japan 1999.
83.
A. Kazaryan, C.
Shen, Y. Wang and B. R. Patton, “Generalized Phase-Field Modeling
of Microstructural Evolution in Solids: Incorporation of Rigid-Body Motion of
Grains and Mobility/Energy Anisotropy of Grain Boundaries,” pp. 89-108 in
Phase Transformations and Evolution in
Materials, eds. P. E. A. Turchi and A. Gonis, The Minerals, Metals & Materials Society, 2000.
84.
J. P. Simmons, C.
Shen and Y. Wang, “Phase Field Approach to Transformations
Involving Concurrent Nucleation and Growth,” pp935-942 in MRS Sym. Proc., 580 (Nucleation and
Growth Processes in Materials), 2000.
85.
K. Wu, J.E.
Morral and Y. Wang, “Predicting Interdiffusion Microstructures
Using the Phase Field Approach,” pp. 133-142 in Elevated Temperature Coatings: Science and Technology IV. Edited by
N.B. Dahotre, J.M. Hampikian, J.E. Morral (TMS,
86.
C. Shen, J. P.
Simmons, K. Wu and Y. Wang, “Development of Computational Tools
for Microstructural Engineering of Ni-Based Superalloys by Means of the Phase
Field Method,” pp.57-74 in Materials
Design Approaches and Experiences, edited by J. –C. Zhao, M. Fahrmann
and T. M. Pollock (TMS, Warrendale, PA, 2001).
87.
B. Radhakrishnan,
G. Sarma, T. Zacharia, A. Kazaryan and Y. Wang, “Mesoscale
Modeling of Abnormal Subgrain Growth,“ pp37-47 in Microstructure Modeling and Prediction during Thermal Mechanical
Processing, edited by R. Srinivasan et. al. (TMS,
88.
C. Shen, A,
Kazaryan, P. M. Anderson and Y. Wang, “Phase Field Modeling of
Dislocation Network Coarsening, Dislocation – Impurity and Dislocation
– Precipitate Interactions,” pp 259-262 in Proceedings of the
second International Conference on Computational Nanoscience and
Nanotechnology, edited by M. Laudon and B. Romanowicz, Computational
Publications, Cambridge, MA, 2002.
89.
L. Wang, D. E.
Laughlin, Y. Wang and A. G. Khachaturyan, “Magnetic Domain
Structure of Fe-55at.%Pd Alloy at Different States of Atomic Ordering,”
proceedings of 47th Annual Conference on Magnetism & Magnetic Materials,
Tempa, Florida November 2002.
90.
C. Chen, M. J.
Mills and Y. Wang, “Modeling Dislocation Dissociation and Cutting
of g’ Precipitates in Ni-based Superalloys by Phase
Field Method,” pp309-314 in Defect
Properties and Related Phenomena in Intermetallic Alloys, edited by E. P.
George, H. Inui, M. J. Mills and G. Eggeler, MRS Sym. Proc. Vol. 753 (2003).
91.
C. Shen, J.P.
Simmons and Y. Wang, “Simulating Nucleation in Elastically
Anisotropic Crystal of Arbitrary Microstructure,” Proc. Int. Conf. Solid
to Solid Phase Transformations in Inorganic Materials 2005, Vol. 2, ed. JM
Howe, DE Laughlin, JK Lee, U. Dahmen and WA Soffa, TMS (The Minerals, Metals
& Materials Society), 2005, pp375-380.
92.
W. Guo, Y. Zong,
G. Wang and Y. Wang, “Simulation of Microstructural Evolution
during alpha2 to O-Phase Transformation in Ti-Al-Nb Alloy under Applied Strain
by Phase Field Approach,” Proc. Int. Conf. Solid to Solid Phase
Transformations in Inorganic Materials 2005, Vol. 2, ed. JM Howe, DE Laughlin,
JK Lee, U. Dahmen and WA Soffa, TMS (The Minerals, Metals & Materials
Society), 2005, pp757-762.
93.
N. Zhou, C. Shen,
M.J. Mills and Y. Wang, “Phase Field Modeling of g’ Rafting in Single Crystal Ni-Al,” pp58-63 in Proceedings
of the International Conference on Advanced Materials, Design and Development
(ICAMMD 2005), M. Chakraborty, D.L. McDowell, S. Ghosh, F. Mistree, D.
Bhattacharya (eds), Elsevier, a division of Reed Elsevier India Pvt. Ltd.
94.
C. Shen, J. Li, M.J. Mills and Y.
Wang, “Modeling Shearing of g’ in Ni-Base Superalloys,” pp.
243-252 in Integral Materials Modeling,
ed. Gunter Gottstein, Wiley-VCH,
95.
N. Ma, F. Yang, C. Shen, G. Wang, G.B. Viswanathan, P.C. Collins, D.S.
Xu, R. Yang, H.L. Fraser and Y. Wang, “Modeling Formation of a Sideplates in a/b Ti-Alloys: Effect of
Interfacial Energy Anisotropy and Coherency Elastic Strain Energy,” Proceedings of the 11th World
Conference on Titanium (Ti-2007), Kyoto, Japan. 2007.
96.
E. Payton, G.
Wang, N. Ma, Y. Wang, M.J. Mills, D. Whitis, D. Mourer, and D. Wei,
“Integration of Simulations and Experiments for Modeling Superalloy Grain
Growth,” pp975-984 in Superalloys
08, edited by R.C. Reed, K.A. Green, P. Caron, T.P. Gabb, M.G. Fahrmann,
E.S. Huron and S.A. Woodard, TMS (The Minerals, Metals and Materials Society),
2008.
97.
R.R. Unocic, L.
Kovarik, C. Shen, P.M. Sarosi, Y. Wang, J. Li, S. Ghosh and M.J. Mills,
“Deformation Mechanisms in Ni-Base Disk Superalloys at Higher
Temperatures,” pp377-385 in Superalloys
08, edited by R.C. Reed, K.A. Green, P. Caron, T.P. Gabb, M.G. Fahrmann,
E.S. Huron and S.A. Woodard, TMS (The Minerals, Metals and Materials Society),
2008.
Book Chapters:
98. Y. Wang
and L. Q. Chen, “Simulation of Microstructural Evolution Using the Field
Method”, pp 2a.3.1 – 2a.3.23 in E.N. Kaufmann (ed) Methods in Material Research, John Wiley
& Sons. Inc. (2000).
99. C. Shen
and Y. Wang, Coherent
Precipitation, pp2117-2142 in Handbook
of Materials Modeling, Part B: Models, ed. by S. Yip, Springer, New York
(2005).