Georges MARTIN

Georges P. Martin's CV (pdf)
Table of Contents :
Titles, Positions, Field of research p. 2
Teaching, Supervision of PhD thesis, Invited lectures p. 3
International cooperations p. 4
Books and Scientific Magazines, Scientific committees, Awards p. 5
Member of Societies p. 6
Selected Publications p. 7
Main scientific achievements p.13
Managing research laboratories p.17
Theses prepared under G. Martin’s supervision (Comprehensive list) p.19
Invited talks at meetings (a selection) p.20
Published courses, overviews p.23
Comprehensive list of peer reviewed publications p.24
Technical reports p.40

Georges P. Martin, Ph.D.

Born May 28, 1940, married, 2 children, 4 grand children.

Titles, Positions, Field of research

Titles:

• 1963 “Ingénieur Civil des Mines” (École des Mines de Paris, France);
• 1964 MS in Nuclear Metallurgy (Orsay-Saclay; Pr. P. Lacombe);
• 1965 MS in Solid State Physics (Orsay; Pr. J. Friedel);
• 1973 “Docteur es Sciences Physiques” ^[1] (Orsay);
• 1995 “Research Director” at CEA ^[2];
• 1998 Member of Academia Europaea.

Positions

• 1964 / 84 Research Scientist, Physical Metallurgy, CEA Saclay, France;
• 1984 / 88 Head of “Centre de Chimie Métallurgique”, CNRS, Vitry, France;
• 1988/2002 Head of the Physical Metallurgy Lab. (SRMP ^[3]), CEA Saclay;
• 2001/2005 Head of CPR ^[4] “Precipitation”;
• 2002/2010 Scientific advisor by the Haut Commissaire à l’Énergie Atomique, CEA Head Quarter.

Field of research:

Physical Metallurgy (experiments, theory and computer modeling from the atomic scale up)

• Solid-state diffusion and diffusion-controlled kinetics;
• Materials under irradiation (fundamentals of-): microstructural evolution, phase instability, non equilibrium segregations, plasticity; Georges Martin introduced the concept of Driven Alloys and applied it to phase stability under irradiation, under plastic straining, friction and wear; various applications to nuclear materials (swelling of steels, stability of brazed joints, metallurgy of neutron absorbing alloys in control rods…), mechanical alloying (finding new processing routes for special compounds), wear of swift trains wheels (French TGV);
• Miscellaneous: crystal growth, corrosion, solute hardening, solid-state amorphyzation, metallurgy of an icosahedral phase, stability of INVAR alloys and of mixed phosphides.

This resulted in more than 240 publications and reports (list below)

Teaching, Supervision of PhD thesis, Invited lectures

Teaching:

• 1975/95: MS degree “Metallurgy and Materials” (Université de Paris Sud Orsay and Saclay): cohesion, elasticity, dislocations, diffusion, phase transformations, irradiation effects...
• 1996: Co-organizer of the EDF-INRIA-CEA school on computer modeling, devoted to “Modeling Materials from the Atomic Scale” : lectures on “Solid State Kinetics”;
• 1998/2001: MS “Solid State Physics” (Université de Paris Sud Orsay) : “Physical Metallurgy”;
• Few weeks courses on: Materials under irradiation (1980, Chinese Academy of Sciences and CEA, Peking); "Solid State kinetics" (1993, Université de Paris Sud Orsay), "Solid state diffusion and kinetics" (2002, Northwestern University);
• Many advanced courses at summer schools (CNRS, NATO and others), such as: Aussois, Les Houches, Trieste, Rhodos, Viña del Mar (Chili), Urbana; topics covered “solid state precipitation”, “non linear diffusion”, “driven alloys”, “nucleation”, “surfaces and interfaces”, “materials under irradiation”…

Supervision of PhD thesis : 18 students among whom 3 have University carriers (U of I at Urbana Champaign, U Deakin Australia, INP- Grenoble France), 5 are research scientists at CEA (basic science or technology), 2 are researchers at CNRS, 4 have industrial carriers (EDF, ARCELORMITTAL, scientific instruments, finance).

Invited lectures : (full list below). Among these, six Physical Metallurgy Gordon Conferences (Grain boundaries, Diffusion, Segregations, Phase transformations, Irradiation, Far from equilibrium processing), each of the five yearly PTM (Phase Transformation in Metals) initiated in 1981, the last of which was a plenary lecture in Avignon 2010 (“Driven Alloys”), several MRS and TMS annual meetings, the last of which was a keynote lecture at TMS 2011 SanDiego (“Solid-state diffusion and transformation kinetics”). Invited lectures were also given in several Academic centers, such as: Academia Sinica -Pekin, ISS Bangalore -India, U. of Tokyo, in the US at U. of I at Urbana Champaign, U. Northwestern, U. of California at Berkeley, MIT Boston, ITP at UCSB, in Germany at KFA Jülich, HMI Berlin, U. of Göttingen, and in France… Invited lectures at industrial research centers include IBM Yorktown Heights, LLNL, KFA Karlsruhe and in France, EDF-Renardières, IRSID in Metz (steel industry). Georges Martin contributed to two DOE BES prospective meetings.

International cooperations

International cooperations:

Visiting laboratories abroad:

Visiting laboratories abroad:

• 1970 / 71: University of Illinois, Urbana, Dept of Physics (1 academic year with Pr. D. Lazarus).
• 1975: IBM Yorktown Heights (2 weeks lecturing together with P. Benoist, on grain boundary diffusion);
• 1980: Academy of Science, Peking, China : 3 weeks lectures on materials under irradiation.
• 1981: MPI Stuttgart, Pr. K. Urban.
• 1981-82: University of Trento in Povo, Italy: several visits with Pr. G. Jacucci (Numerical Statistical Physics);
• 1984 & 96: Institute for Theoretical Physics, UCSB: Seminars on: (84) "Interface between Theoretical Physics and Materials Science" & (96) “Grand Challenges in Numerical Materials Modeling".
• 1985 – 86: Humboldt Prize : 6 months in Germany: Hahn Meitner Institut, Berlin (Pr. Wollenberger), KFA Jülich (Pr. Schilling) and University of Göttingen (Physical Metallurgy, Pr. Haasen);
• 1988/2011: Northwestern University, Evanston USA, several 1 to 3 months visits: collaboration with Pr D. Seidman, on “Solid State Kinetics from the Atomic Scale up”;
• 1994: Indian Institute of Science, Bangalore, India: Pr G. Ananthakrishna : 2 weeks seminar on “Non Linear Phenomena in Materials Science” ;
• 2002 & 04: DOE-BES: seminars on Advanced Computer Materials Modeling: irradiation effects;
• 2004: Lawrence Livermore National Laboratory; Pr. Tomas Diaz de la Rubia: 2 weeks on Computer Modeling in Materials Science;
• 2005 / 09: Tokyo, Japan, Pr. Kinoshita: consulting with the cross-disciplinary program “NXO” (Oxides for nuclear applications), 4 seminars.

Foreign long-term visitors:

Foreign long-term visitors:

• 1981: K. Urban, KFA Jülich, Germany;
• 1988: W. Johnson, U. of Virginia, Charlottesville;
• 1989: F. Haider, U of Ulm, Germany;
• 1998: C. Abromeit, HMI Berlin, Germany.
• 1992-2002: Pr. V.G. Vaks (several one month stays), Kurchatov Institute, Moscow.

Books and Scientific Magazines, Scientific committees, Awards

Books and Scientific Magazines:

Books and Scientific Magazines:

Editor (principal) of "Surfaces and interfaces in metallurgy" (in French, summer school of Physical Metallurgy) Trans. Tech. (1975);

Editor (together with L. Kubin) of "Non linear phenomena in materials science" vol I, II, III: Trans. Tech. (1987; -92; -95);

Associate editor of Progress in Materials Science (Pergamon 1987-1995);

Associate editor of Applied Physics Letters (1997-2000)

Associate editor of Materials Science Forum (1997-2002)

Member of Societies

Scientific committees:

Scientific committees:

• CNRS: “Comité national” (1983-86), and (1985-) evaluation committees of several CNRS Materials Science laboratories (Dijon, Rouen, Strasbourg, Nancy, Poitiers, Marseille, Toulouse, Caen, CNRS-ONERA);
• AERS: Evaluation committee of SIMAP, Grenoble (2010);
• CEA-Nuclear Reactor Division (1998 - 2000);
• CPR “SMIRN” (2003-06): joint research program between CNRS-EDF-CEA on metallic materials under irradiation;
• CPR “ISMIR” (2003-06): joint research program between CNRS-CEA on iono-covalent materials under irradiation;
• CPR “ODISSEE” (2011- ): joint research program between CEA, CNRS, AREVA, EDF and Mécachrome, on oxide dispersed steels.

Scientific advisory committees of

Scientific advisory committees of

• former PECHINEY (aluminum industry), 1989-91;
• former USINOR => ARCELOR (steel industry) 1998-2004;
• Max Planck Institut Düsseldorf (MPI für Eisenforschung 2000-2005);

Awards

Awards

• 1985 Alexander Von Humboldt Stiftung Prize;
• 1992 Prize from Académie des Sciences;
• 1997 Portevin Medal (SF2M^[5]);
• 1998 Knight of “Ordre National du Mérite”;
• 1998 Member of Academia Europea (section: Physics and Engineering);
• 2001 Great Medal of SF2M;
• 2002 “Eshbach visiting Scholar” (Northwestern University);
• 2005 First Rhine-Ruhr International Materials Award 2005;
• 2006 ‘‘Eshbach visiting Scholar’’ (Northwestern University);

Member of:

Member of:

• Société Française de Physique & European Physical Society;
• Société Française de Métallurgie et Matériaux (SF2M);
• The Institute of Metals (up to 2002); - Materials Research Society; - TMS.

Selected publications (by topic)=

Selected publications (by topic)

I. SOLID STATE DIFFUSION

I. SOLID STATE DIFFUSION

I.1 Autodiffusion au joint de grains de bicristaux d'argent soumis à une pression hydrostatique

(Grain boundary self diffusion under high pressure in silver)

G. MARTIN, D.A. BLACKBURN, Y. ADDA, Phys. Stat. Sol. 23 (1967) 223

I.2 Atomic model for grain boundary and surface diffusion

P. BENOIST, G. MARTIN, Thin Solid Films 25 (1975) 181

I.3 Measurements of grain boundary diffusion

G. MARTIN, B. PERRAILLON, in "Grain-boundary structure and kinetics" ASM (1980) 239

I.4 Interdiffusion in concentrated quaternary Ag-In-Cd-Sn alloys, modeling and measurements C. DESGRANGES, F. DEFOORT, S. POISSONNET and G. MARTIN, Defect and Diffusion Forum 143147 (1997) 603.

I.5 The atomic mobility in Cahn's diffusion Model

G. MARTIN, Phys. Rev., B41 (1990) 2279

I.6 Self-consistent formulation of configurational kinetics close to equilibrium: the phenomenological coefficients for diffusion in crystalline solids

M. NASTAR, V. YU DOBRETSOV, G. MARTIN, Phil. Mag. A80 (2000) 155-184.

I.7 Coupled relaxation of concentration and order fields in the linear régime

BELLON and G.MARTIN, Phys. Rev. B66 (2002) 184208

I.8 A diffuse interface model for the interfacial transfer coefficient

G. MARTIN, Acta Materialia, 53 (2005) 2629-2632

II. SOLID STATE KINETICS

II. SOLID STATE KINETICS

II.1 The mechanism of morphogenesis in a phase-separating concentrated multicomponent alloy:

ZUGANG MAO, C.K. SUDBRACK, K.E. YOON, G. MARTIN and D. SEIDMAN,

Nature Materials, 6, 3 (2007), 210-216

II.2 The theories of unmixing kinetics of solid solutions

G. MARTIN, in "Solid state phase transformations in metals and alloys",

Editions de Physique, Orsay, France (1980) 337

II.3 Kinetic Monte Carlo Method to Model Diffusion Controlled Phase Transformations in the Solid State G. MARTIN and F. SOISSON, in Handbook of Materials Modeling (Sidney Yip ed., Springer Netherland, 2005) 2223-2248.

II.4 Monte-Carlo computation of clusters free energies in the Ising model: a test for the validity of the capillarity approximation

G. JACUCCI, A. PERINI, G. MARTIN, J. Phys. A : Math. Gen. 16 (1983) 369 ; (II) , Phys. Rev. B29

(1984) 2689

II.5 Effects of the Interaction between Order Parameter and Concentration on the Kinetics of Alloy Ordering V.YU. DOBRETSOV, G. MARTIN, F. SOISSON and V.G. VAKS, Europhysics Letters, 31 (1995) 417422.

II.6 Monte Carlo Simulations of Copper Precipitation in Dilute iron-copper Alloys during Thermal Ageing and under Electron Irradiation

F. SOISSON, A. BARBU and G. MARTIN: Acta Metal. and Mater., 44 (1996) 3789.

II.7 A Monte Carlo study of B2 ordering and precipitation via vacancy mechanism in BCC lattice

M. ATHENES, P. BELLON, G. MARTIN and F. HAIDER, (I) Acta Mater. 44 (1996) 4739 ; (II) Phil. Mag. A 76 (1997) 565 ; (III) Acta mater. 48 (2000) 2675.

II.8 Monte Carlo simulations of the decomposition of metastable solid solutions : transient and steady state nucleation kinetics

F.SOISSON and G. MARTIN, Phys. Rev.B 62 (2000-I) 203-214.

II.9 Kinetic features of phase separation under alloy ordering

V.YU. DOBRETSOV, V.G. VAKS and G. MARTIN, Phys. Rev., B54 (1996-I) 3227.

II.10 Computer simulation of diffusional phase transformations: Monte Carlo algorithm and application to precipitation of ordered phases

T.A. ABINANDANAN, F. HAIDER and G. MARTIN, Acta Mater. 46 (1998) 4243-4255.

II.11 Ordering and phase separation in Ni-Cr-Al : Monte Carlo simulation vs. three dimensional atom probe C. PAREIGE, F. SOISSON, G. MARTIN and D. BLAVETTE, Acta mater 47 (1999) 1889-1899.

II.12 Amorphization by solid-state diffusion in granular systems

E. GAFFET, J.C. ANGLEZIO, J. BIGOT, G. MARTIN, J. Less Comm. Metals 140 (1988) 49.

II.13 Reactive solid state dewetting

L. SCHMIERGELD-MIGNOT, P.J.A. MOLINÀS-MATA, S. POISSONNET and G. MARTIN

Phil. Mag. Letters, 80 (2000) 33-40.

II.13 Precipitation kinetics of Al₃Zr and Al₃Sc in aluminum alloys modeled with cluster dynamics E. CLOUET, A. BARBU, L. LAE and G. MARTIN, Acta Materialia, 53 (2005) 2313-2325.

II.14 Reconciling the Classical Theory of Nucleation and Atomic Scale Observations and Modeling G. MARTIN

in Solid-Solid Phase Transformations in Inorganic Materials 2005, Edited by Howe et al, TMS , pp 291299.

II.15 Driving force and mobility for microstructural evolutions : the rate of grains rotation across a grain boundary

G. MARTIN, Phys. Stat. Sol.b172 (1992) 121.

II.16 Sintering of crystalline solids: a new modelization technique, A. PAVLOVITCH*, G. MARTIN, 1st Tohwa Utr Int. Symp. on Slow dynamics in condensed matter; Fukuoka, Nov. 1991.

III. MATERIALS UNDER IRRADIATION

III. MATERIALS UNDER IRRADIATION

III.1 Considérations sur la relation entre le fluage sous irradiation et les dommages créés par l'irradiation en l'absence de contrainte (Relationship between irradiation creep and zero stress irradiation damage) G. MARTIN, J.P. POIRIER, J. Nucl. Mater. 39 (1971) 93.

III.2 Instabilité des solides cristallins sous irradiation (Instability of crystalline solids under irradiation) G. MARTIN, Phil. Mag. 32 (1975) 615.

III.3 Void lattices and other radiation induced periodic structures G. MARTIN, J. de Physique Colloque 38 (1977) C7-419.

III.4 Modèle simple d'évolution de la microstructure des solides sous irradiation (Simple model for microstructural evolution under irradiation)

P. VALENTIN, G. MARTIN, Phil. Mag. A 46 (1982) 971.

III.5 Biais des dislocations dans les alliages dilués (Dislocation bias in dilute alloys) P. VALENTIN, G. MARTIN, Phil. Mag. 51 (1985) 715.

III.6 The elimination of irradiation point defects in crystalline solids : sink strengths N.V. DOAN and G. MARTIN, Phys. Rev. B67 (2003) 134107.

III.7 Premières évaluations des dégâts d'irradiation par ions lourds de très haute énergie à GANIL

A. BARBU, G. MARTIN, M. TOULEMONDE, J.C. JOUSSET, C.R.A.S. 299, Série II, n°8 (1984) 409.

III.8 The contribution of electronic energy losses to radiation damage in metallic materials

A. AUDOUARD, E. BALANZAT, A. BARBU, J. DEVAUD-RZEPSKI, C. DIMITROV, A. DUNLOP, J.

DURAL, G. FUCHS, J.C. JOUSSET, D.LESUEUR, N. LORENZELLI, G. MARTIN, L. THOME, A.M. WACHE, Radiation Effects and Defects in Solids, 110 (1989) 113.

III.9 Influence of the cascade size on the amorphization of phosphide in Ni base filler metals

L. BOULANGER, P. BELLON, Y. SERRUYS, N.V. DOAN, G. MARTIN

J. Nucl. Mater. 191-194 (1992) 473- 477.

III.9 Kinetic model for equilibrium and nonequilibrium segregation in concentrated alloys under irradiation Y. GRANDJEAN, P. BELLON and G. MARTIN, Phys. Rev., B 50 (1994) 4228.

III.10 Microstructural kinetics in alloys undergoing transmutations: application to AIC neutron absorbers C. DESGRANGES, G. MARTIN, F. DEFOORT, Mat. Res. Soc. Symp. Proc. 439 (1997) 401.

III.11 Dislocation pinning by small interstitial loops : a molecular dynamics study

D. RODNEY and G. MARTIN, Phys. Rev. Lett. 82 (1999) 3272 ;(II) Phys. Rev. B 61 (2000) 8714 ; (III) + Y. BRECHET, Mat. Sci. Eng. A 309-310 (2001) 198-202.

III.12 Interstitial cluster motion in nickel: a Molecular Dynamics study

N. V. DOAN, D. RODNEY and G. MARTIN, Defect and Diffusion Forum, 194-199 (2001) 43-48.

III.13 Dose, Flux, Fluence

G. MARTIN, Note technique CEA-SRMP - 97.83.

III.14 Les matériaux du nucléaire et l’irradiation (nuclear materials and irradiation effects) G. MARTIN and D. LESUEUR in “Les matériaux du nucléaire”, A. Zaoui et al Editors, Academy of Sciences, rst n°5 (TEC & DOC Paris, 2000), Chapter 1.

III.15 Enhanced Annealing of the Dislocation Network under Irradiation D. MORDEHAI and G. MARTIN, Phys. Rev. B accepted (2011).

IV. DRIVEN ALLOYS

IV. DRIVEN ALLOYS'':

Overview:

Driven Alloys

G. MARTIN and P. BELLON, Solid State Physics 50 (1996) 189.

IV.a ALLOYS DRIVEN BY IRRADIATION

IV.a1 Radiation induced precipitation in NiSi solid solutions : dose-rate effects A. BARBU, G. MARTIN, Scrip. Met. 11 (1977) 771.

IV.a2 The contribution of dissipative processes to radiation induced solid solution instability G. MARTIN, Phys. Rev. B21 (1980) 2122.

IV.a3 Solid solutions under irradiation : I ; II ; III

R. CAUVIN and G. MARTIN, Phys. Rev. B 23 (1981) 3322 ; Phys. Rev. B 23 (1981) 3333 ; Phys. Rev. B25 (1982) 3385.

IV.a4 Precipitate coarsening induced by point defect recombination in alloys under irradiation K. URBAN and G. MARTIN, Acta Met. 30 (1982) 1209.

IV.a5 Phase stability under irradiation : Ballistic effects G. MARTIN, Phys. Rev. B30 (1984) 1424.

IV.a6 Irradiation induced formation of metastable phases, a master equation approach P. BELLON and G. MARTIN, Phys. Rev. B 38 (1988) 2570.

IV.a7 Cascade effects in a non-equilibrium phase transition with metallurgical relevance P. BELLON and G. MARTIN, Phys. Rev. B 39 (1989) 2403.

IV.a8 Cascade effect on respective stability of ordered phases in Ni4Mo under irradiation P. BELLON and G. MARTIN, J. of the Less Com. Metals 145 (1988) 465-475.

IV.a9 Quantitative description of mixing with light ions

A. TRAVERSE, M.G. LE BOITE and G. MARTIN, Europhys. Lett. 8 (1989) 633-637.

IV.a10 Non equilibrium transitions in driven AB3 compounds with FCC lattice : a multivariate master equation approach : F. HAIDER, P. BELLON and G. MARTIN, Phys. Rev. B 42 (1990) 8274.

IV.a11 Cascade size effects on phase stability under irradiation: a stochastic description P. BELLON and G. MARTIN, Radiation Effects and Defects in Solids, 113 (1990) 165.

IV.a12 Dynamical lattice model for binary alloys under radiation: mean field solutions and Monte Carlo simulations

E. SALOMONS, P. BELLON, F. SOISSON and G. MARTIN, Rev. B 45 (1992) 4582.

IV.a13 Two-phase dynamical equilibria driven by irradiation in ordered alloys SOISSON, P. BELLON and G. MARTIN, Phys. Rev. B46 (1992) 11332.

IV.a14 Dynamical phase changes induced by point defect fluxes under irradiation C. ABROMEIT and G. MARTIN, J. Nucl. Mater, 271 &272 (1999) 251-255.

IV.b ALLOYS DRIVEN BY SEVERE PLASTIC STRAINING

IV.b1 Transformations de phases et plasticité (Phase transformations and plasticity) G. MARTIN, Ann. Chim. Fr. 6 (1981) 46.

IV.b2 Cavitation en volume dans des solutions binaires à base de Nickel fatiguées à haute temperature (Bulk cavitation in Ni base solid solutions under high temperature cyclic loading) B. ARNAUD, R. Le HAZIF and G. MARTIN, Acta Met. 33 (1985) 1105.

IV.b3 Ball milling amorphization mechanism of NiZr alloys

E. GAFFET, N. MERK, G. MARTIN and J. BIGOT, J. of the Less Comm. Metals : 145 (1988) 251-260.

IV.b4 Ball milling induced amorphization in NixZry : a parametric study

Y. CHEN, M. BIBOLE, R. LE HAZIF and G. MARTIN, Phys. Rev.B48 (1993) 14.

IV.b5 Order-disorder transformation in Fe-Al under ball milling

P. POCHET, E. TOMINEZ, L. CHAFFRON and G. MARTIN, Phys. Rev., B52 (1995) 4006-4016.

IV.b6 Taking advantage of the concept of Driven Alloys to study the wear of swift train wheels Y. LE BOUAR, L. CHAFFRON, G. SAINT-AYES and G. MARTIN, Scripta Mater, 49 (2003) 985.

V. MISCELLANEOUS

V. MISCELLANEOUS

V.1 Dodecahedral shaped quasicrystalline precipitates in dilute AlMn solid solutions:

K. YU ZHANG, J. BIGOT, J.P. CHEVALIER, D. GRATIAS, G. MARTIN and R. PORTIER Phil. Mag. B 58 (1988) 1-13.

V.2 Incubation time and frequency of pitting of passive layers

G. MARTIN and B. BAROUX, Europhysics Letters 5 (1988) 629.

V.3 Influence of substrate induced misfit stresses on Miscibility Gap in Epitaxial Layers ; Application to III - V Alloys

F.C. LARCHE, W.C. JOHNSON, C.S. CHIANG and G. MARTIN, J.Appl.Phys. 64 (1988) 5251.

V.4 Chemical ordering in Ga_xIn_1-xP semiconductor alloys grown by metallorganic vapor phase epitaxy P. BELLON, J.P. CHEVALIER, G. MARTIN, E. DUPONT NIVET, C. THIEBAUT and J.P. ANDRE

Appl. Phys. Letters 52 (1988) 567.

V.5 Study of self-limiting oxidation of silicon nanoclusters by atomistic simulations

J. DALLA TORRE, J.L. BOCQUET, Y. LIMOGE, J.P. CROCOMBETTE, E. ADAM, G. MARTIN,

T. BARON, P. RIVALLIN and P. MUR, J. Appl. Phys. 92 (2002) 1084-1094.

V.6 Chemical disorder induced amorphization in NiZr2: a constant temperature - constant pressure molecular dynamics study combined with the tight binding approach

C. MASSOBRIO, V. PONTIKIS and G. MARTIN, Phys.Rev.Letters 62 (1989) 1142.

V.7 A study of phase stability in INVAR FeNi alloys by anomalous X-Ray scattering :

J.P. SIMON, O. LYON, F. FAUDOT, J. RZEPSKI, O. DIMITROV*, L. BOULANGER and G. MARTIN

in "Physical Metallurgy of controlled expansion Invar type alloys", K.C. Russell and D.F. Smith Editors, The Minerals, Metals and Materials Society, 1990, p. 51.

V.8 Antisite defects and non equilibrium phase transitions in intermetallics

G. MARTIN and P. BELLON, MRS Bulletin, 16 (1991) 33.

V.9 Modélisation numérique en Science des Matériaux de l'échelle atomique à l'échelle mésoscopique

(Materials computer modeling form the atomic- up to the meso-scale)

G. MARTIN, A. PAVLOVITCH, Mem. Sci. Rev. Met. 89 (1992) 555

V.10 Relationship between the electronic structure and the precipitation of FeTiP in interstitial-free ferritic steels

R.P. GUPTA, G. MARTIN, S. LANTERI, P. MAUGIS and M. GUTTMANN Phil. Mag. A 80 (2000) 2393-2403.

V.11 Dislocation glide in model Ni(Al) solid solutions by molecular dynamics

E. RODARY, D. RODNEY, L. PROVILLE, Y. BRECHET and G. MARTIN Phys.Rev. B 70 (2004) 054111.

V.12 Atomic-scale study of dislocation glide in a model solid solution

L. PROVILLE, D. RODNEY, Y. BRECHET and G. MARTIN

Phil. Mag. 86, 25-26 (2006), 3893-3920.

V.13 Nucleation problems in metallurgy of the solid state: recent developments and open questions Y. BRÉCHET and G. MARTIN

Comptes Rendus Physique 7 (2006), 959-976.

V.14 Contribution to : ”La Métallurgie”, RST Nº 31, Academy of Sciences, Yves Quéré et André Pineau Editors, EDP, France, 2011.

Main scientific achievements

Main scientific achievements

All of Georges P. Martin’s work is motivated by developing basic science for materials technologies (nuclear and non nuclear).[^Index refers to the full list of publications.]

1964-1977: Interfacial Diffusion

Grain-boundary (GB) diffusion was known to have a deleterious effect in the early nuclear fuel cladding (dispersion strengthened Mg) and, later, grain boundary electro migration was acknowledged to have a key role in the failure of micro-conductors in supercomputers. In this context, Georges Martin measured two basic characteristics of grain boundary diffusion in a simple model metal, silver: the activation volume¹ and the effective valence⁴, which measures the proportionality between the fluxes of atoms and of electrical charges. The measurements were performed on bycrystals, using radiotracer techniques, which implied very low activity measurements. The activation volume we measured pointed to a vacancy diffusion mechanism at the grain boundary (an unconventional idea in those days): this result got confirmed 20 years later in U. of Münster, in Germany. The effective valence Martin found was of the same sign as in the bulk, which ruled out some speculations in the literature on the possibility for hole conduction at the GB’s.

The GB diffusion models used at that time were very rough (a high diffusivity slab of finite thickness), while electron microscopy and field ion microscopy in metals were revealing undisturbed crystalline atomic packing up to the contact surface between the adjacent grains, in metals. For this reason, Martin proposed, together with Dr. P. Benoist (Wigner medal 1996), a lattice model for surface and GB diffusion, where the fast diffusion paths are confined to the contact surface between the two crystals⁹. We could thus specify the physical meaning of the parameters used in the classical models.

Martin later extended the formalism of GB diffusion to alloys¹⁷ and to phase boundaries¹⁰, two cases of practical relevance, where interfacial equilibrium conditions must be handled with care.

Martin's other work included measuring the activation volume for Na diffusion in NaCl (at U of I Urbana, Pr. D. Lazarus), confirming a positive relaxation volume of the Schotky pair⁶, at variance with the best theoretical values of those days (the use of a linear approximation for the displacement to force ratio was at the origin of the error).

Martin also reformulated the rate of decay of capillarity waves, in the limit where adatom emission / absorption at surface steps is the rate controlling process, rather than surface diffusion from step to step (as postulated by Mullins in his famous work)²¹.

1969-1984: High temperature irradiation effects

In the late 60’s British scientists discovered irradiation induced swelling of stainless steel used as a cladding material in the Donrey fast reactor. The latter discovery triggered a worldwide interest. Swelling still raises problems in some core components of PWR’s. As is often the case in nuclear technologies, this swelling phenomenon challenged materials science and engineering, since no macroscopic theory can account for it: one must link the atomic scale, where nuclear collisions are well described, to the time evolution of the strain tensor, from which engineers can handle structural mechanics computations. Martin found this approach to be higly appealing.

Martin’s first contribution in this field together with Jean-Paul Poirier, dealt with the plastic deformation in metals under irradiation: based on simple defect balances we pointed, for the first time, to the possibility of a creep rate proportional to square of the shear stress². Martin then focused on more generic aspects of materials under high temperature irradiation, i.e. temperatures where the irradiation produced point defects can migrate distances large enough for a (quasi) stationary defect population to prevail in the solid. Such materials can be viewed as an open system sustained by external forcing (injection of defects) in some stationary state, the stability of which is not governed by thermodynamical potentials (an active field of research in the 70’s).

Martin’s first attempt along this line, dealt with the formation of void- (or other defect clusters) lattices¹³. According to this work, the latter appeared as a result of the spatial instability of the stationary uniform defect population, provided the defect-defect physical interaction is taken into account in the coupled reaction-diffusion equations, which govern time evolution of the vacancy and interstitial concentration fields. The model predicted that such a patterning would occur beyond some critical irradiation flux threshold, which depends on temperature, a prediction, which was confirmed by A. Barbu in his PhD thesis work.

This finding supported a suggestion by Adda et al. that depending on the irradiation flux and temperature, diffusion under irradiation might drive the material in opposite directions (order/disorder, dissolution/precipitation, amorphization/crystallization…). A.Barbu^{22, 31} showed that such is indeed the case for irradiation induce precipitation in undersaturated solid solutions (Ni-Si).

Martin’s model also gave a general argument to account for irradiation-induced instability of undersaturated solid solutions²⁸. Vacancy-interstitial mutual annealing introduces a weak coupling between the concentration fields of the solute and of the two types of defects: provided that the couplings between solute and defects fluxes is properly accounted for (“inverse Kirkendal effect”), the latter may destabilize the solid solution. Martin and Cauvin^{26, 35, 36, 43, 54} we found evidence of such an effect in Al base solid solutions: the full spectrum of reaction to irradiation of many distinct solid solutions could be rationalized with the above argument, while constraint thermodynamics arguments failed to do so²⁷. Potential consequences of the above mechanism on precipitate coarsening, or on the decomposition of INVAR alloys were explored by Martin with K. Urban⁴⁴ and C. Abromeit⁶⁹, respectively.

The above formalism relied on the existence of stationary defect concentration fields, while the latter slowly evolve because of the microstructural evolution, which modifies the density of point defect sinks. Martin and Valentin^{47, 51, 62}, modeled the coupled slow evolutions of various components of the microstructure, by eliminating the fast variables (defect concentration fields), which revealed some unexpected features, such as transient swelling, or a mechanism for the incubation of swelling, etc… One difficult point in modeling microstructures under irradiation deals with the evolution of the dislocation network. More recently, Martin and D. Mordehai addressed this problem paying special attention to the “coordinated climb” of neighboring dislocation segments²³¹.

1984-1998 Driven alloys (for an overview, see reference 166)

All the above models assumed that irradiation produces the point defects uniformly in space and time, while defects are produced in a correlated manner inside cascades, the size and density of which depends on the details of the slowing down of the irradiating particles. Moreover, cascades trigger local atomic mixing. From the theoretical viewpoint, cascades can be viewed as external noise imposed to the atomic configuration, with specific time and space correlation (at variance with thermal noise). A similar context prevails under sustained shear, such as during cyclic loading, materials processing by ball milling, etc., Martin suggested the analogy between the effects on phase stability, of irradiation and sustained shear in 1980³³.

Martin's first attempts failed to reveal any alteration of phase stability in Ni base binary solutions under high temperature cyclic loading, although an unexpected mechanism of bulk cavitation was found⁶⁴. Several evidences of shear induced alteration of phase stability, such as precipitate dissolution in persistent slip bands or non-equilibrium segregations, were found by other groups, but were not rationalized with Martin’s ideas. Alternatively, ball milling turned out to be more successful as he was able to define a “milling intensity” and demonstrate on model alloys (mainly FeAl and Ni_xZr_y compounds) that under milling, the alloy achieves a state (ordered or disordered, crystalline or amorphous), which depends on the milling conditions (intensity and temperature). The analogy with irradiation effects was established^{137, 156}. Advantage could be taken of this analogy in several studies of practical impact: optimizing the processing route of dispersed oxide compounds for electrical contact¹⁴² (among others), understanding the wear process of swift trains wheels²¹⁷, and more recently optimizing drug processing by milling (M. Descamp, AIP Conference Proceedings, Volume 982, 2008, 53-61).

Developing the theory of driven alloys spread on a long period of time. The effect of “ballistic mixing”, i.e. the atomic mixing forced by nuclear collisions or dislocation glide during shearing, was first treated by simply superimposing forced atomic jumps to the thermally activated ones in a Cahn Hilliard type diffusion equation. The result was that the evolution of the solute concentration field is no more governed by the Gibbs free energy functional, but by a Lyapunov functional; the latter writes as the Gibbs free energy evaluated at an “effective temperature”, which depends on the ratio of the forced to the thermal atomic jump frequencies⁵⁶. This idea yields qualitatively and sometimes quantitatively correct results⁹³.

Martin and his co-workers addressed the problem with increasing levels of sophistication:

1. The state of the compound is defined by a uniform order parameter, the value of which is governed by a the deterministic equation: single or multiple stationary states are found, depending on the forcing intensity and temperature, the local stability of which can be assessed^74,121.

2. The state of the compound is defined by a field of order parameter, the evolution of which is governed by time dependant Gingsburg Landau equation. Special care had to be devoted to the expression of the kinetic coefficient under purely thermal conditions. Martin proposed a mean field approximation, which treats thermodynamics and kinetics at the same level of sophistication¹⁰⁴. Based on this model, several problems could be addressed: coarsening under irradiation, kinetic pathways for precipitate dissolution, revealing the key role, on top of the reduce temperature, of the forcing intensity^{132, 143, 145}. A practical application of the above technique dealt with irradiation induced interfacial segregations, a key issue in stress corrosion cracking of core components^{153, 184}.

3. The above technique could incorporate “inverse Kirkendal effect” on top of ballistic mixing, yielding a unified treatment of both effects¹⁶⁶.

4. Keeping the homogeneous description, Martin addressed the stochastic aspect of the problem, based on a Fokker Planck or Kubo equation^{85, 86, 90, 92, 98, 113}. From these treatments, Martin and co-workers proposed phase diagrams of dynamical-equilibrium under irradiation for model compounds (FeAl and Ni4Mo), several predictions of which have been later confirmed by experiment. E.g. the order disorder transition in FeAl, which is of second order shifts to first order under appropriate irradiation conditions¹⁴⁸, the extension of the stability domain of ordered structures in Ni₄Mo, varies with the size of the cascade, keeping the irradiation flux the same (experiments done in Argonne by Bellon et al. and in HMI by Banerjee et al.). Kinetic Monte Carlo simulations enriched the theoretical treatment¹⁴⁷.

One of the applications of the above ideas about dynamical equilibria and microstructural evolution under irradiation dealt with the surprisingly good irradiation resistance of brazing of common use in PWR’s: the brittle Ni phosphides either amorphize or develop a dislocation network which makes them more ductile¹²⁶!

On a more general level, the above results might be used to clarify the notions of dose, dose rate, flux, fluence, which are sometimes confusing in nuclear technologies: taking as a guide the medical meaning of a “dose” (the elementary ingestion of some drug), Martin proposed (up to now, without success) to name “elementary dose” the cascade (as defined by it’s size and density); the “dose rate” is the number of doses per unit time (and per unit quantity of matter) and the “integrated dose” is the integral of the latter. As Martin and co-workers demonstrated and observed, the effect of a given irradiation depends on the three above parameters^R5.

1994-... Configurational kinetics

As described above, driven alloys are such that two diffusion mechanisms are competing: a forced one, which is deduced from particle matter interaction, and the thermal one, which also operates in the absence of forcing. The reliability of modeling a kinetic pathway rests on the precision with which actual diffusion mechanisms are modeled. When Martin and co-workers became involved involved in the field, most models were based on the kinetic Ising model, i.e. direct exchange diffusion mechanism and the same cohesive energy for the two components of the alloy, two features at variance of any metallurgical system: indeed, diffusion occurs because of vacancy jumps, and the alloy components have usually quite distinct cohesive energies, the latter scaling many of the vacancy properties (formation and migration energies). This was the driving force for revisiting the kinetic coefficient, which enters CahnHilliard’s diffusion equation. The expression Martin proposed, based on a broken bonds model, yields a unified description of configurational thermodynamics and kinetics, at the same level of sophistication¹⁰⁴. Based on this model, Martin and co-workers revisited many classical problems in solid-state kinetics, either using Kinetic Monte Carlo (KMC) simulations or various mean-field approximations:

1. The realism of Martin and his co-workers KMC simulations has been assessed by comparing the precipitation of Ni₃(Al,Cr) in a ternary model super alloy (NiAlCr) as observed by tomographic atom probe (TAP) and in our simulations¹⁹¹. In those days the improvement of the computing power, made it possible to run the real experiment and the virtual one on similar sample sizes. The quantitative and qualitative agreement between modeling and experiment was impressive. Martin improved the above study with D. Seidman, taking advantage of the recent explosion of the detection yield of Atom Probes. We could analyze a much greater number of precipitate nuclei, which revealed unexpected nuclei compositions and morphologies. The KMC simulations are based on first principle interatomic energies; the same parameters are used to compute the Onsager and diffusion matrices in the terminal solid solution. The origin of the unexpected features is demonstrated to be in the kinetic coupling among the fluxes of the alloy components, a coupling that is ignored by the classical models^{227, 232}.

2. More generic studies of kinetic pathways for the relaxation toward equilibrium were also made, based on KMC simulations. Martin and co-workers could identify the impact of the vacancy diffusion mechanism on various parameters such as the kinetic percolation limit, the Kolmogorov-Johnson-Mehl-Avrami exponent, or on qualitative features such as the uniform versus localized ordering process^{167, 173, 189}, or the incubation time for precipitation¹⁹³.

3. Few problems with direct practical relevance could be addressed based on such a KMC technique: Cu precipitation in Fe¹⁶⁰, formation of niobium carbides in low alloy steels, where the transient formation of a non-equilibrium iron carbide was predicted²¹¹.

The mean field approximation has been taken advantage of for revisiting basic problems of solidstate kinetics:

1. Computing the Onsager matrix coefficients from the spectrum of defect (vacancy¹⁸⁵ and later self interstitial) jump frequencies; Studying the coupled relaxation of the order and composition fields (the classical model, which ignore that both fields relax because of the very same vacancy jumps, omit a coupling term)^{222, 146, 166}; Expressing the interfacial transfer coefficient as a kinetic excess quantity^130,222.

2. Based on the same technique as the mean field model, Martin and co-workers could study precipitation complex alloy (Ag, In, Cd, Sn) undergoing transmutations, used as neutron absorber in PWR’s. Because the model used is based on a sound diffusion mechanism, the parameterization only required a small number of interdiffusion measurements¹⁷³.

Studying precipitation phenomena, Martin focused on various aspects of the nucleation theories³², in particular on the free energy of a nucleus. Together with G. Jacucci (U. Trento, Italy) we used computer calorimetry to compute the latter in the Ising model (2 and 3 D), with a great level of accuracy: we could evaluate the correction to the capillarity approximation for small nuclei^46,49,57,58. The free energies so computed can be used in cluster dynamics models for nucleation and growth. A direct assessment of the technique was done for the precipitation of AlZr, which was simulated using the KMC technique as described above, and using cluster dynamics parameterized as just described. The agreement is very good at least in the dilute case²²⁴. This research allowed to clarify some points of the classical nucleation theory²²⁴.

Miscellaneous

Martin contributed to several studies which were underway in the laboratories I was the head of: metallurgy of quasi-crystals⁷⁹, surface treatments by LASER heating⁷², interdiffusion induced amorphization^77,83,97,116, kinetic pathways in epitaxial growth^{87, 88, 96,105}, irradiation damage by swift ions^63,110.

The kinetics of morphological changes are fascinating, but difficult to phrase in general terms¹⁶: Martin addressed several questions such as the morphological stability of two phase super alloys with large precipitate volume fractions⁸¹, the rate of grain rotation across a grain boundary¹²³, dewetting of a surface layer as a result of an interfacial reaction^{196, 202, 206}, the incubation time for corrosion pitting⁸².

While the major part of Martin’s computer simulation work is based on Monte Carlo techniques, he devoted few years to using Molecular Dynamics to study atomistic aspects of crystalline plasticity: dislocation pinning by small self interstitial clusters and the unpinning mechanisms in irradiated model Ni^{191, 200} and solute hardening in dilute Ni(Al) solutions^{220, 226}. Both studies revealed features, which were not expected from continuum theories.

Managing research laboratories

Managing research laboratories (1984-2002)

Martin had two very different experience of management: one at CNRS (1984-88), the other at CEASaclay (1989-2002).

At CNRS, the “Centre d'Études de Chimie Métallurgique” (Vitry sur Seine) was one of the earliest CNRS laboratories (50 years old), with about 60 scientists, 40 technical staff and 20 to 30 students. Martin’s main goal has been to stimulate a skill in modeling, in a community dominated by experimentalists, as well as forcing scientific communication among the teams.

At CEA, the Physical Metallurgy Laboratory (SRMP), which Martin was heading, underwent a deep renewal of people, because of the French retirement system. With 25 staff members, and 15 students, post-doc and visiting scientists, Martin’s main goal has been to keep and develop an expertise in the scientific basis for nuclear materials, at a time where such a field was temporarily outdated, and part of the team did work on problems like new routes of materials processing (mechanical alloying, electro deposition of High Tc superconductors...). Modeling from the atomic scale up has been the main achievement of that team; in particular, first-principle electronic structure computations were developed both for static and kinetic problems and provided the input parameters for atomic scale modeling. The cohabitation in the same small team of researches on very basic questions and researches on rather applied problems has been very stimulating, provided the communication among both sort of people could be maintained.

One of the major practical impacts of this expertise has been to introduce such techniques to the EDF research laboratory (EDF-Renardières, in the early 90’s).

Theses prepared under G. Martin’s supervision

Theses prepared under G. Martin’s supervision

[Student’s name (type of these): title of the thesis translated into English (president of the jury)]

• A. Badirou (1975-76, thèse de spécialité - Orsay): Epitaxial silver layers vapor deposited under vacuum;
• A. Barbu (1975-78, doctorat d'état ès sciences physiques - Nancy): Phase changes under irradiation: a contribution (Pr. Jouffrey);
• R. Cauvin (1976-81, doctorat d'état ès sciences physiques - Nancy): Experimental and theoretical study of solid solution instability under irradiation (Pr. Guinier);
• P. Valentin (1979-84, doctorat d'état ès sciences physiques - Paris VI): Microstructural evolutions under irradiation (Pr. Friedel);
• B. Joulia-Arnaud (1981-85, doctorat d'état ès sciences physiques - Paris VI): Microstructural evolution under high temperature cyclic loading in nickel base solid solutions (Pr. Poirier); - E. Gaffet (1984-88, thèse de l'Université Paris VI, science des matériaux): Metastable phases produced by Laser heating or by solid-state interdiffusion (Pr. Fayard);
• P. Bellon (1985-88, thèse de l'Université Paris VI, science des matériaux): Constrained equilibria in materials science: a contribution (Pr. Friedel);
• M. Debuigne (1986-88, thèse École Centrale): Experimental study and modeling of Laser processing of TA6V alloys (Pr. Huetz);
• Ying Chen (1989-92, thèse de l'Université Paris XI, science des matériaux): Contribution to the physics of mechanical alloying (Pr. Philibert);
• F. Soisson (1990-93, thèse de L'Institut Polytechnique de Grenoble, science et génie des matériaux

P. Bellon co-supervisor): Ordered compounds under irradiation, dynamical equilibrium phase diagrams and kinetic pathways (Pr. Joud);

• P. Maugis (1991-94, thèse de l'Université Paris XI, G. Blaise co-supervisor): Thin films of TiAl intermetallic compound produced by reactive interdiffusion (Pr. Philibert);
• D. Galy (1991-95, thèse de l'Université Paris XI, L. Boulanger co-supervisor): Amorphization

of intermetallic compounds under ball milling (Pr. Revcolevschi);

• P. Pochet (1993-97, thèse de l'Université Lille, L. Chaffron co-supervisor): Phase changes under high energy milling (Pr. Foct);
• M. Athènes (1994-97, thèse de l'Université Paris VI, P. Bellon co-supervisor): Vacancy mediated diffusion in alloys and decomposition kinetics (Pr. Pétroff);
• C. Desgranges (1995-98, thèse de l'Université Paris XI): Understanding and predicting the evolution of neutron absorbing silver base alloys under neutron irradiation (Pr. Priester);
• D. Rodney (1997-2000, thèse INPG, Pr. Y. Brechet co-supervisor): Atomic scale modeling of dislocations (Pr. Friedel).
• D. Gendt (1998-2001, thèse Paris XI, F. Soisson co-supervisor): Experimental study and

modeling of NbC precipitation in low alloy steels;

• H. de Monestrol (1998-2001, thèse INPG, Mme L. Mignot co-supervisor): Reactive dewetting in the solid state (Pr. N Eustathopoulos).
• E. Rodary (1999-2002, thèse INPG, co direction avec D. Rodney): Atomic scale modeling of dislocation glide in solid solutions (Pr. P. Guyot).

Invited talks at meetings (a selection):

Invited talks at meetings (a selection):

Unpublished:

• Gordon conferences on Physical Metallurgy (1978, -82, -84, -88) and on "far from equilibrium material processing" (1995);
• Festschrifts in the honor of: Kirkendalll 1991, Balluffi 1993, de Fontaine 2002, Hillert 2004;
• Universities: USA (Urbana, Berkeley, ITP Santa Barbara, Brown à Rhodes Island, Northwestern, Perdue, Storrs); Germany (Göttingen, Mainz); Italy (Trento); Swiss (EPFL Lausanne); Belgium

(Free U. Bruxelles); Holland (Amsterdam, Groningen);

• Research Centers: USA (Argonne, Oak Ridge, NIST, IBM Yorktown Heights, LLNL); Germany (KFA Jülich, HMI Berlin, KF-Karlsruhe), India (BARC Bombay, ISS Bangalore), China (Pékin), Japon (Tokyo: NXO program).

Main international meetings, published: Name of the meeting, location, (Title of the speech^ref)]

Les Joints de Grains (Grain boundaries), Ecole Polytechnique de Montréal, Canada, 1973 (Grain boundary electromigration as a tool for studying GB core structure8);

Les joints de grains dans les métaux (Grain boundaries in metals), Colloque International CNRS, St Etienne, France, 1975 (Grain boundary diffusion¹²);

L'ordre et le désordre dans les solides (Order and disorder in solids), Colloque International CNRS, Paris, France, 1977 (Void lattices and other radiation induced periodic structures24)

Comportement sous irradiation des matériaux métalliques et des composants des coeurs des réacteurs rapides (Behavior under irradiation of metallic materials and core components of fast neutron reactors), Conférence internationale CEA, Ajaccio, France, 1979 (Alloy stability under irradiation29);

Int. Conf. on Radiation effects in breeder reactor structural materials, Scottsdale USA, 1977

(Fundamental aspects of the evolution of- and phase changes in metals and alloys under irradiation

23);

Workshop on Solute segregation and phase stability during irradiation, Gatlinburg USA, 1978

(Radiation induced homogeneous precipitation in undersaturated solid solutions²⁶);

Grain-boundary structure and kinetics, ASM seminar, Milwaukee USA, 1979 (Measurements of grain boundary diffusion30);

Phase stability during irradiation, Séminaire AIME, Pittsburgh 1980 (Dose-rates effects on solid solution stability37);

Int. Conf. on Solid-solid phase transformations, Pittsburg USA 1981(Effects of irradiation on phase stability and phase changes³⁹);

Yamada Conf. V, Point Defects and Defects Interactions in Metals, Kyoto Japon, 1981 (Irradiation induced solid solutions instability48);

Effects of radiation on materials, ASTM, Scottsdale USA, 1982 (Cooperative effects in microstructural evolutions under irradiation: fundamental aspects50);

Third International Conference on Ion Beam Modification of Materials, Grenoble 1982

(Implantation, ion beam mixing and solid state solubility⁵⁵);

Dimensional stability under irradiation, British Nuclear Energy Society Bristol 1983 (Synergistic effects during high temperature irradiation51);

Decomposition of alloys: the early stages, 2nd Acta-Scripta Metallurgica Conference 1983 (Phase stability under irradiation59);

Solute-defect interaction - Theory and experiments, International workshop, Kingston Canada,

1985 (Stability criteria for phases under irradiation⁶⁶);

The relation between mechanical properties and microstructure under fusion irradiation conditions, International workshop Danemark 1985 (Alloys evolution under irradiation67);

Atomic transport and defects in metals by neutron scattering, International workshop Jülich Allemagne, 1985 (Saturation of irradiation induced precipitation68);

Int. Conf. on Vacancies and interstitials in metals, Berlin 1986 (Theoretical approaches to phase stability criteria under irradiation75);

Pattern, defects and microstructures in non equilibrium systems, NATO workshop, Austin USA

1987 (Stability criteria for phases under irradiation⁷⁶);

Solid-state amorphizing transformations, Los Alamos USA, 1987 (Metastable phases formation under irradiation80);

Materials research society fall meeting, Boston USA, 1988 (Stochastic description of cascade size effects on phase stability under irradiation98);

First International Symposium on Swift Heavy Ions in Matter, Caen 1989 (Theoretical approaches of structural modifications induced by ion irradiation111);

Int. Symp. on Amorphization by Solid-State Reaction, Grenoble 1990 (Mechanical alloying : far from equilibrium phase transitions ?108);

Int. Conf. on the evolution of metals during irradiation, Muskoka Canada, 1992 (Phase stability and microstructural evolutions in concentrated alloys under irradiation133);

Statics and Dynamics of Alloy Phase Transformations, Séminaire OTAN, Rhodes Grèce1992

(Alloys under external forcing : steady states and microstructural evolutions¹³⁵);

Int. Conf. on Solid-Solid Phase Transformations in Inorganic Materials '94, ASM, Pittsburgh 1994

(Driven alloys : stability and kinetics¹⁵⁴);

Non-linear phenomena in materials science, Bangalor Inde, 1995 (Modeling diffusion controlled kinetics in equilibrium and driven alloys155);

DIMAT'96 (Diffusion in Materials), Nordkirchen Allemagne, 1996 (Modeling diffusion controlled solid state kinetics in equilibrium and driven alloys171);

Modeling materials for fusion reactors, Davos Suisse, 1997 (Alloys under irradiation176);

Materials Research Society: session Diffusion in solids, San Francisco, 1998 (From solid state diffusion to configurational kinetics183);

Interfaces, Prague, 1998 (Modeling non equilibrium grain boundary segregations187);

Grand challenges in computer modeling of materials, MIT Boston, 1998 (Modeling materials driven far form equilibrium188);

Solid to solid phase transformations in materials, PTM'99, Kyoto 1999 (Solid state diffusion and configurational kinetics195).

Main published national meetings:

La diffusion dans les milieux condensés, 19th Colloque de Métallurgie, INSTN 1977 (La diffusion dans les milieux minces19 - Diffusion in thin media);

Fluage, fatigue-fluage, action de l'environnement, 23ème Colloque de Métallurgie, INSTN 1980

(Transformations de phases et plasticité34 - Phase transformations and plasticity);

Formation des défauts et effets d'irradiation, Colloque annuel de la société Française de Microscopie Electronique, Besançon 1981(Apports de la microscopie électronique à l'étude des changements de phase sous irradiation38 - Contribution of electron microscopy to the understanding of phase changes under irradiation);

Effets d'irradiation dans les matériaux, 26ème Colloque de Métallurgie, INSTN 1983 (Evolution microstructurale sous irradiation à hautes températures: aspects fondamentaux60 - Fundamental aspects of microstructural evolution under high temperature irradiation);

Les Super Alliages, Colloque SNECMA, Evry 1993 (Modélisation de la précipitation dans les superalliages polyconstitués : de l'échelle atomique à l'échelle macroscopiqueR2 - Modeling precipitation in multicomponent superalloys: from atomic scale up to macroscale);

Les Super Alliages, Colloque de synthèse du GdR, Toulouse 1995 (Cinétiques à l'état solide et mobilité atomique dans les superalliages 158 - Solid-state kinetics and atomic mobility in superalloys);

Ségrégation interfaciale dans les solides, 41ème Colloque de Métallurgie, INSTN 1998 (Les ségrégations interfaciales de non équilibre et leur modélisation189 - Non-equilibrium interface segregations and their modeling).

Published courses

Published courses [School (title ^ref)]

Surfaces et interfaces en métallurgie, Ecole d'été, Gassin 1973 (Stabilité morphologique des systèmes biphasés16 - Morphological stability of two-phases systems);

Solid-state phase transformations in metals and alloys, Ecole d'été, Aussois 1979 (The theories of unmixing kinetics of solid solutions32);

Diffusion in Materials, NATO workshop -E179, Aussois 1990 (Non linear effects in diffusion99);

Computer Simulation in Physical Metallurgy, ISPRA lectures, Italy 1984 (Basic aspects of microstructural evolution under high temperature irradiation61);

Materials under irradiation, Summer School, France (Cooperative processes in alloys under irradiation128; Radiation effects in metals and alloys136);

Overviews [Book (title^ref.)]

Metallurgical Science and Technology (Non equilibrium phase transitions in intermetallics116);

Materials Research Society Bulletin (Antisite defects and non equilibrium phase transitions in intermetallics119);

Solid State Physics (Driven alloys172);

Special issue J. Computer-Aided Materials Design (Modeling diffusion controlled kinetics in equilibrium and driven alloys175);

Mécanosynthèse (Transformation de phases sous broyage179 - phase transformations under ball milling);

In Handbook of Materials Modeling (2005) (Kinetic Monte Carlo method to model diffusion controlled phase transformations ²²⁰);

In Alloy Physics (2007) (Kinetics in non equilibrium alloys²²⁸).

Georges MARTIN’s peer reviewed publications

Georges MARTIN’s peer reviewed publications

(+Lecture or communications; *speaker)

1. Autodiffusion au joint de grains de bicristaux d'argent soumis à une pression hydrostatique

(Grain-boundary self-diffusion in silver bicrystals under hydrostatic pressure)

7. MARTIN, D.A. BLACKBURN, Y. ADDA, Phys. Stat. Sol. 23 (1967) 223.

2. Considérations sur la relation entre le fluage sous irradiation et les dommages créés par l'irradiation en l'absence de contrainte (Relationship between irradiation creep and zero stress irradiation damage) G. MARTIN, J.P. POIRIER, J. Nucl. Mater. 39 (1971) 93.

3. Comment on "Mass transport along grain boundary pipe lines in KBr" G. MARTIN, Scrip. Met. 6 (1972) 437.

4. Electromigration intergranulaire de l'antimoine dans l'argent : (Grain boundary electromigration of Antimony in Silver)

   8. MARTIN, Phys. Stat. Sol. 14 (1972) 183.

5. Observation d'un cristal bidimensionnel de lignes de dislocations dans le chlorure de sodium (Observation of a two-dimensional crystal of dislocation lines in sodium chloride) J.P. POIRIER, G. MARTIN, Phil. Mag. 27 (1973) 1455.

6. Pressure dependence of self-diffusion of Na²² in NaCl :

   9. MARTIN, D. LAZARUS, J.L. MITCHELL, Phys. Rev. B8 (1973) 1726.

7. Mise en évidence par effet Mössbauer de rassemblements de Cobalt dans les joints de grains du Beryllium (Mössbauer effect evidence for Cobalt clustering at grains-boundaries in Beryllium) G. MARTIN, Phys. Stat. Sol. a18 (1973) 683.

8+ L'électromigration intergranulaire : outil d'étude de la structure de coeur des joints de grains

(Grain-boundary electromigration as a tool to study grain-boundary core structure) G. MARTIN*, P. TRUCHOT, Can. Met. Quartely 13 (1974) 111.

9. Atomic model for grain boundary and surface diffusion :

   16. BENOIST, G. MARTIN, Thin Solid Films 25 (1975) 181.

10. Mesure des coefficients de diffusion interfaciale (Measuring interface diffusion coefficients) G. MARTIN, Acta Met. 23 (1975) 697.

11+ Modèle atomique de diffusion intergranulaire : II Généralisation (Atomic model for grain-boundary diffusion : II general case)

17. BENOIST*, G. MARTIN, J. de Physique, Colloque 36 (1975) C4-213.

12+ La diffusion intergranulaire (Grain-boundary diffusion)

G. MARTIN*, B. PERRAILLON, J. de Physique, Colloques 36 (1975) C4-166.

13 Instabilité des solides cristallins sous irradiation (Instability of crystalline solids under irradiation)

G. MARTIN, Phil. Mag. 32 (1975) 615.

14+ Stability of void lattices under irradiation: a kinetic model

P. BENOIST*, G. MARTIN: in "Fundamental aspects of radiation damage in metals" USERDA CONF-751006-P2 (1975) II-1236.

47 Modèle simple d'évolution de la microstructure des solides sous irradiation (Simple model for microstructural evolution under irradiation)

P. VALENTIN, G. MARTIN, Phil. Mag. A 46 (1982) 971.

48+ Irradiation induced solid solutions instability

G. MARTIN*, R. CAUVIN, J.L. BOCQUET, A. BARBU, Ref. 45, p. 923.

49 Monte-Carlo computation of clusters free energies in the Ising model: a test for the validity of the capillarity approximation

G. JACUCCI, A. PERINI, G. MARTIN, J. Phys. A : Math. Gen. 16 (1983) 369.

50+ Cooperative effects in microstructural evolutions under irradiation: fundamental aspects P. VALENTIN*, G. MARTIN: in "Effects of radiation on materials" ASTM STP782, Brager, Perrin Eds., ASTM (1982) 1103.

51+ Synergistic effects during high temperature irradiation

P. VALENTIN, G. MARTIN*: in "Dimensional stability under irradiation", BNES 2 (1983) 17.

52. Les changements de phase sous irradiation (Phase changes under irradiation)

    7. MARTIN, R. CAUVIN, J.L. BOCQUET, A. BARBU Echos du C.E.A., Science et Recherche (1982) 59.

53. Solid solution stability under irradiation

    8. MARTIN, R. CAUVIN, A. BARBU, in "Phase transformation during irradiation",

F. Nolfi Ed., Appl. Sci. London (1983) 42.

54. Long range periodic decomposition of irradiated solid solutions G. MARTIN, Phys. Rev. Letters 50 (1983) 250.

55+ Implantation, ion beam mixing and solid state solubility

9. MARTIN*, A. BARBU, J. Nucl. Inst. Meth. 209-210 (1983) 203.

56. Phase stability under irradiation : Ballistic effects G. MARTIN, Phys. Rev. B30 (1984) 1424.

57. Clusters free energy in the simple cubic Ising Model

A. PERINI, G. JACUCCI, G. MARTIN, Phys. Rev. B29 (1984) 2689.

58+ Interfacial contribution to clusters free energy

A. PERINI, G. JACUCCI, G. MARTIN*, Surf. Sci. 144 (1984) 53.

59+ Phase stability under irradiation

G. MARTIN*, A. BARBU, Acta-Scripta Met. Proc. Series 2 , "Early stages of decomposition" Pr. Haasen Ed. 1984 (Pergamon, Paris) 70.

60+ Evolution microstructurale sous irradiation à hautes températures : aspects fondamentaux

(Fundamental aspects of microstructural evolution under high temperature irradiation) G. MARTIN*, P. VALENTIN, Ann. Chim. Fr. 9 (1984) 193.

61+ Basic aspects of microstructural evolution under high temperature irradiation

G. MARTIN*, P. VALENTIN

in "Computer Simulation in Physical Metallurgy" G. Jacucci Editor, 1986, ECSC, EEC, Brussels, p. 183.

62 Biais des dislocations dans les alliages dilués (Dislocations bias in dilute alloys)

C. ABROMEIT*, G. MARTIN

in "Non Linear Phenomena in Materials Science", L. Kubin, G. Martin Eds. (Trans. Tech., Suisse 1988) p. 321.

90 Cascade effects in a non-equilibrium phase transition with metallurgical relevance P. BELLON, G. MARTIN, Phys. Rev. B 39 (1989) 2403.

91+ Bulk and surface defects in implanted and annealed GaAs

P. BELLON*, J.P. CHEVALIER, G. MARTIN, P. DECONINCK, J. MALUENDA

in "Microscopy of semiconducting materials 1987", A.G. Cullis, P.D. Augustus Eds., Inst. Phys. Conf. Ser. 87, (Bristol, UK, 1987) 309.

92+ Cascade effect on respective stability of ordered phases in Ni4Mo under irradiation P. BELLON*, G. MARTIN, J. of the Less Com. Metals 145 (1988) 465-475.

93 Quantitative description of mixing with light ions

A. TRAVERSE, M.G. LE BOITE, G. MARTIN, Europhys. Lett. 8 (1989) 633-637.

94+ Ball milling amorphization mechanism of NiZr alloys

E. GAFFET*, N. MERK, G. MARTIN, J. BIGOT

J. of the Less Comm. Metals : 145 (1988) 251-260.

95. Chemical ordering in GaxIn1-xP semiconductor alloys grown by metallorganic vapor phase epitaxy

P. BELLON, J.P. CHEVALIER, G. MARTIN, E. DUPONT NIVET, C. THIEBAUT,

J.P. ANDRE, Appl. Phys. Letters 52 (1988) 567.

96. Substrate driven ordering microstructure in GaxIn1-xP alloys :

P. BELLON, J.P. CHEVALIER, E. AUGARDE, J.P. ANDRE, G.P. MARTIN

J. Appl. Phys. 66 (1989) 2388.

97. Chemical disorder induced amorphization in NiZr2 : a constant temperature - constant pressure molecular dynamics study combined with the tight binding approach

C. MASSOBRIO, V. PONTIKIS, G. MARTIN, Phys.Rev.Letters 62 (1989) 1142.

98+ Stochastic description of cascade size effects on phase stability under irradiation

G. MARTIN*, P. BELLON

Mat. Res. Soc. Symp. Proc. 88 Symposium Q, Boston, 138 (1989) 15.

99+ Defects in recrystallized Se+ implanted GaAs : influence of electrical activity

P. BELLON*, J.P. CHEVALIER, L. AISSAOUI, J. MALUENDA, G. MARTIN

Inst. of Phys. Conf. Series "Microscopy of semiconducting Materials" 100 (1989) 415.

100+ Ordering in GaInP alloys on GaAs : effects of substrate orientation

E. AUGARDE, M. MPASKOUTAS, P. BELLON*, J.P. CHEVALIER, G. MARTIN

Inst. of Phys. Conf. Series "Microscopy of semiconducting Materials" 100 (1989) 155.

101+ Non linear effects in diffusion

G. MARTIN*

"Diffusion in Materials": A.L. Laskar, J.L. Bocquet, G. Brébec, C. Monty Eds, NATO ASI, E179, 1990, 129.

102 A calorimetric study of mechanically induced phase transformations in Ni Zr alloys : N. MERK, E. GAFFET, G. MARTIN, J. Less Common Metals, 153 (1989) 299.

115. Molecular dynamics study of amorphization by introduction of chemical disorder in crystalline

NiZr2

C. MASSOBRIO, V. PONTIKIS, G. MARTIN, Phys. Rev. B41 (1990-II) 10486.

116. Non equilibrium phase transitions in intermetallics

G. MARTIN, P. BELLON, Metallurgical Science and Technology 9 (1991) 61-74.

117+ Cascade size effects in phase transformations under irradiation

P. BELLON*, G. MARTIN, Ann. Soc. Fr. Chim. Min. 16 (1991) 365-371.

118+ Amorphization in a vibrating frame grinder : an example of phase transition in driven systems Y. CHEN*, R. LE HAZIF, G. MARTIN, Mat. Sci. Forum 88-90 (1992) 35.

119 Antisite defects and non-equilibrium phase transitions in intermetallics G. MARTIN, P. BELLON, MRS Bulletin, 16 (1991) 33.

120+ Interface stability in driven compounds

F. SOISSON*, P. BELLON, G. MARTIN

"Ordering and Disordering in alloys", Yavari ed., Elsevier (Londres) 1992, p. 207.

121 Dynamical lattice model for binary alloys under radiation : mean field solutions and Monte Carlo simulations

E. SALOMONS, P. BELLON, F. SOISSON, G. MARTIN, Phys. Rev. B 45 (1992) 4582.

122+ Stochastic description of ordering in driven compounds

P. BELLON*, G. MARTIN

"Ordering and Disordering in alloys", Yavari ed., Elsevier (Londres) 1992, p. 172.

123. Driving force and mobility for microstructural evolutions: the rate of grains rotation across a grain boundary

G. MARTIN, Phys. Stat. Sol.b172 (1992) 121.

124. Stability of driven compounds : stochastic and deterministic descriptions

     16. BELLON, F. SOISSON, G. MARTIN, F. HAIDER

"Non linear Phenomena in Materials Science" II, G. Martin and L. Kubin eds, (Trans. Tech. Publ. Suisse 1992) p. 169.

125. Influence of milling conditions on the formation of metastable phases : the crystal to amorphous transition

Y. CHEN, R. LE HAZIF, G. MARTIN

"Non linear Phenomena in Materials Science" II, G. Martin and L. Kubin eds, (Trans. Tech. Publ. Suisse 1992) p. 271.

126+ Influence of the cascade size on the amorphization of phosphide in Ni base filler metals

L. BOULANGER*, P. BELLON, Y. SERRUYS, N.V. DOAN, G. MARTIN

J. Nucl. Mater. 191-194 (1992) 473- 477.

127+ Sintering of crystalline solids: a new modelization technique

A. PAVLOVITCH*, G. MARTIN

1st Tohwa Utr Int. Symp. on Slow dynamics in condensed matter; Fukuoka, Nov. 1991.

128+ Cooperative Processes in Alloys under Irradiation

17. BELLON*, G. MARTIN, Solid State Phenomena 30-31 (1993) 107.

129 On the interface transfer coefficient in second phase growth models

P. MAUGIS, G. MARTIN, Phys. Rev. B49, 11580 (1994).

130+ On the interface transfer coefficient in second phase growth models

144 On the relaxation rate of conserved and non conserved order parameters in systems with metallurgical relevance

G. MARTIN, Phys. Rev. B50 (1994) 12362.

145+ Modélisation de composés ordonnés sous irradiation : diagrammes d'équilibre dynamique et évolutions microstructurales

F. SOISSON*, P. BELLON, G. MARTIN

J. de Physique IV, Colloque C3, Suppl. au J. de Phys. III, 4 (1994) C-183.

146+ Monte Carlo simulations of precipitation of L12 ordered phase

156. Order-disorder transformation in Fe-Al under ball milling

P. POCHET, E. TOMINEZ, L. CHAFFRON, G. MARTIN, Phys. Rev., B52 (1995) 4006-4016.

157. Effects of the Interaction between Order Parameter and Concentration on the Kinetics of Alloy Ordering

V.YU. DOBRETSOV, G. MARTIN, F. SOISSON, V.G. VAKS Europhysics Letters, 31 (1995) 417-422.

158+ Cinétiques à l'état solide et mobilité atomique dans les superalliages (Solid-state kinetics and atomic mobility in superalloys)

O. DIMITROV* and G. MARTIN*, Colloque Superalliages, CNRS Toulouse, 1995.

159+ Phase transformations involving ordering and phase separation : a Monte-Carlo study

T.A. ABINANDANAN*, F. HAIDER, G. MARTIN

"Non Linear Phenomena in Materials Science III", G. Ananthakrishna, L.P. Kubin and G. Martin eds, Solid State Phenomena 42-43 (1995) 87.

160. Monte Carlo Simulations of Copper Precipitation in Dilute iron-copper Alloys during

Thermal Ageing and under Electron Irradiation

F. SOISSON, A. BARBU, G. MARTIN, Acta Metal. and Mater. 44 (1996) 3789.

161. Diffusion in crystals with non-conservative defects

     7. MARTIN, C. DESGRANGES, Europhysics. Lett. 44 (1998) 150-155.

162. Amorphization mechanism of NiZr2 by ball-milling

D. GALY, L. CHAFFRON, G. MARTIN, J. of Materials Research, 12 (1997) 688.

163. Order-disorder transition under shearing : application to ball milling

P. POCHET, P. BELLON, L. CHAFFRON, G. MARTIN, MRS Symposium, 400 (1996) p. 13.

164. A Monte Carlo study of B2 ordering and precipitation via vacancy mechanism in BCC lattice M. ATHENES, P. BELLON, G. MARTIN, F. HAIDER, Acta Mater., 44 (1996) 4739.

165. Kinetic features of phase separation under alloy ordering

V.YU. DOBRETSOV, V.G. VAKS, G. MARTIN, Phys. Rev., B54 (1996-I) 3227.

166. Driven Alloys

     8. MARTIN and P. BELLON, Solid State Physics 50 (1996) 189.

167. Atomistic Modeling of Kinetics in Intermetallics

P. BELLON*, Y. GRANDJEAN, G. MARTIN, R. AVERBACK

J. de Physique IV, Col., 6 (1996) C2-11.

168. Monte Carlo Simulation of Simultaneous Ordering and Precipitation in BCC Lattice

M. ATHENES, P. BELLON*, G. MARTIN, F. HAIDER

J. de Physique IV, Col., 6 (1996) C2-53.

169. Monte Carlo Simulation for BCC Alloys under Irradiation : Phase Stability and

Microstructural Evolutions

F. SOISSON*, P. BELLON, A. BARBU, G. MARTIN Mat. Res. Soc. Symp. Proc. 373 (1995) 89.

170. Identification of novel diffusion cycles in B2 ordered phases by Monte Carlo simulation M. ATHENES, P. BELLON, G. MARTIN, Phil. Mag. A 76 (1997) 565.

176+ Alloys under irradiation.

9. MARTIN*, P. BELLON, F. SOISSON, J. Nucl. Mater. 251 (1997) 86-88.

177+ Microstructural kinetics in alloys undergoing transmutations : application to AIC neutron absorbers.

186 Computer simulation of diffusional phase transformations: Monte Carlo algorithm and application to precipitation of ordered phases.

T.A. ABINANDANAN, F. HAIDER, G. MARTIN, Acta Mater. 46 (1998) 4243-4255.

187+ Modelling non-equilibrium grain boundary segregations

M. NASTAR and G. MARTIN*, Materials Science Forum 294-296 (1999) 83-90.

188 Modelling materials driven far from equilibrium

G. MARTIN, Current Opinion in Solid State & Materials Science 3 (1998) 552-557.

189+ Les ségrégations interfaciales de non-équilibre et leur modélisation (Non-equilibrium interfacial segregations and their modeling)

G. MARTIN* and M. NASTAR, J. Phys. IV France 9 (1999) Pr 4-59.

190. Dislocation pinning by small interstitial loops : a molecular dynamics study D. RODNEY, G. MARTIN, Phys. Rev. Lett. 82 (1999) 3272.

191. Ordering and phase separation in Ni-Cr-Al: Monte Carlo simulation vs three dimensional atom probe

     3. PAREIGE, F. SOISSON, G. MARTIN, D. BLAVETTE, Acta mater 47 (1999) 1889-1899.

192. Rôle de l'interstitiel et de l'interaction interstitiel-impureté sur la ségrégation induite par l'irradiation dans les aciers austénitiques (role of interstitials and solute-interstitial interaction on irradiation induced segfregations in austenitic steels)

M. NASTAR*, P. BELLON, G. MARTIN, J. Phys. IV France 9 (1999) Pr 4-69.

193+ Kinetics of decomposition of metastable solid solutions : comparison between Monte Carlo simulations and classical theories

F. SOISSON*, G. MARTIN

Jap. Inst. Of Metals Proc. 12 (JIMIC-3), 1999, 757, M. Koiwa, K. Otsuka and T. Miyazaki eds.

194+ Ordering and phase separation in model superalloys : 3D Atom Probe versus

Monte Carlo simulation

4. BLAVETTE*, F. SOISSON, G. MARTIN, C. PAREIGE

Jap. Inst. Of Metals Proc. 12 (JIMIC-3), 1999, 63, M. Koiwa, K. Otsuka and T. Miyazaki eds.

195+ Solid state diffusion and configurational kinetics

M. ATHENES, F. SOISSON, P. BELLON, G. MARTIN*

Jap. Inst. Of Metals Proc. 12 (JIMIC-3), 1999, 433, M. Koiwa, K. Otsuka and T. Miyazaki eds.

196. Reactive solid state dewetting

L. SCHMIERGELD-MIGNOT, P.J.A. MOLINÀS-MATA, S. POISSONNET, G. MARTIN Phil. Mag. Letters, 80 (2000) 33-40.

197. Effects of atomic mobilities on phase separation kinetics : a Monte Carlo study M. ATHÉNES, P. BELLON, G. MARTIN, Acta mater. 48 (2000) 2675.

198. Phase transformations under ball milling

L. CHAFFRON, P. POCHET, P. BELLON, G. MARTIN

International Journal of Non Equilibrium Prcocessing, 11 (2002) 347-361.

199. Dislocation pinning by glissile interstitial loops in a nickel crystal : a molecular-dynamics study D. RODNEY, G. MARTIN, Phys. Rev. B 61 (2000) 8714.

200. Les matériaux du nucléaire et l’irradiation (nuclear materials and irradiation effects)

G. MARTIN, D. LESUEUR

« Les matériaux du nucléaire», rapport édité par A. Zaoui et col., pour l’Académie des Sciences, rst n°5 (éditions TEC & DOC Paris, 2000), Chapter 1.

201. Monte Carlo simulations of the decomposition of metastable solid solutions : transient and steadystate nucleation kinetics

F. SOISSON, G. MARTIN, Phys. Rev.B 62 (2000-I) 203-214.

202. Kinetics and mechanisms of reactive solid state dewetting in the system Ag-Ni-O

H. de MONESTROL, L. SCHMIRGELD-MIGNOT, Patrici MOLINÀS-MATA, S. POISSONNET,

G. MARTIN, Acta mater, 49 (2001) 1655-1660.

203. Relationship between the electronic structure and the precipitaion of FeTiP in interstitial-free ferritic steels

R.P. GUPTA, G. MARTIN, S. LANTERI, P. MAUGIS and M. GUTTMANN Phil. Mag. A 80 (2000) 2393-2403.

204+ Le vieillissement des matériaux sous irradiation (Materials aging under irradiation) G. MARTIN*, F. SOISSON, J. de Physique IV 11 (2001) Pr1-177.

205+ Near surface transformations : an example of driven phase transformations

L.CHAFFRON, G.MARTIN*

Tribology Research: from Model Experiment to Industrial Problems, G. Dalmaz et al. Editors, in Tribology series, (Elsevier Science B) 39 (2001) 429-438.

206. Reactive solid state dewetting of Ag films on Ni substrates : kinetics and mechanisms H. de MONESTROL, L. SCHMIRGELD-MIGNOT, Patrici MOLINÀS-MATA, S. POISSONNET,

L. GAY, G. MARTIN, Defect and Diffusion Forum 194-199 (2001) 1349-1354.

207. Driven phase transformations : a useful concept for wear studies ?

L.CHAFFRON, Y. LE BOUAR, G.MARTIN

3. R. Acad. Sci. Paris, t. 2, Série IV (2001) 749-759.

208+ Interstitial cluster motion in nickel : a Molecular Dynamics study

N. V. DOAN, D. RODNEY*, G. MARTIN, Defect and Diffusion Forum, 194-199 (2001) 43-48.

209+ Effect of dislocation pinning by glissile interstitial loops on the plasticity of an irradiated nickel crystal : a molecular-dynamics based model.

4. RODNEY*, G. MARTIN, Y. BRECHET, J. de Phys. IV 10 (2000) 156-163.

210 Irradiation hardening by interstitial loops : atomistic study and micromechanical model

D. RODNEY, G. MARTIN, Y. BRECHET, Mat. Sci. Eng. A 309-310 (2001) 198-202.

211+ Monte Carlo Simulation of NbC Precipitation Kinetics in aFe D. GENDT*, P. MAUGIS, G. MARTIN, M. NASTAR, F. SOISSON Defect and Diffusion Forum, 194-199 (2001) 1779-1786.

212+ Driven phase transformations: example of forced alloys

L. CHAFFRON, Y. LE BOUAR, G. SAINT AYES, G. MARTIN* Revue de Métallurgie (Février 2003) 183-192.

213. Study of self-limiting oxidation of silicon nanoclusters by atomistic simulations

J. DALLA TORRE, J.L. BOCQUET, Y. LIMOGE, J.P. CROCOMBETTE, E. ADAM, G. MARTIN,

T. BARON, P. RIVALLIN, P. MUR, J. Appl. Phys. 92 (2002) 1084-1094.

214. Coupled relaxation of concentration and order fields in the linear regime P.BELLON, G.MARTIN, Phys. Rev. B66 (2002) 184208.

215. Reactive solid state dewetting: interfacial cavitation in the system Ag Ni O

H. de MONESTROL, L. SCHMIRGELD-MIGNOT, S. POISSONNET, C. LEBOURGEOIS, G. MARTIN, Interface Science, 11 (2003) 379-390.

216. The elimination of irradiation point defects in crystalline solids: sink strengths N.V. DOAN, G. MARTIN, Phys. Rev. B67 (2003) 134107.

217. Taking advantage of the concept of Driven Alloys to study the wear of swift train wheels Y. LE BOUAR, L. CHAFFRON, G. SAINT-AYES and G. MARTIN, Scripta Mater, 49 (2003) 985.

218. Sinks strengths revisited

N.V. DOAN, J.L. BOCQUET, G. MARTIN, Nucl. Inst. Meth. Phys. Res. B202 (2003) 8-12.

219. Dislocation glide in model Ni(Al) solid solutions by molecular dynamics

E. RODARY, D. RODNEY, L. PROVILLE, Y. BRECHET, G. MARTIN Phys.Rev. B 70, 054111 (2004).

220. Kinetic Monte Carlo Method to Model Diffusion Controlled Phase Transformations in the Solid State

G. MARTIN, F. SOISSON in Handbook of Materials Modeling (Sidney Yip ed., Springer Netherland, 2005) 2223-2248.

221. A diffuse interface model for the interfacial transfer coefficient G. MARTIN, Acta Materialia, 53 (2005) 2629-2632.

222+ Diffuse Interface Model for the Interfacial Transfer Coefficient

G. MARTIN*

Second International Conference on Multiscale Materials Modeling, N.M Ghoniem editor, (UCLA 2004), p. 291.

223 Precipitation kinetics of Al3Zr and Al3Sc in aluminum alloys modeled with cluster dynamics E.CLOUET, A. BARBU, L. LAE, G. MARTIN, Acta Materialia, 53 (2005) 2313-2325.

224+ Reconciling the Classical Theory of Nucleation and Atomic Scale Observations and Modeling

G. MARTIN*

in Solid-Solid Phase Transformations in Inorganic Materials 2005, Edited by Howe et al, TMS , pp 291-299.

225. Atomic-scale study of dislocation glide in a model solid solution

L. PROVILLE, D. RODNEY, Y. BRECHET, G. MARTIN Phil. Mag. 86, 25-26 (2006), 3893-3920.

226. Nucleation problems in metallurgy of the solid state: recent developments and open question Y. BRÉCHET, G. MARTIN, Comptes Rendus Physique/ *7*(9-10) (2006), 959--976.

227. CONTRIBUTION TO : “LA FUSION NUCLÉAIRE: DE LA RECHERCHE FONDAMENTALE À LA

PRODUCTION D’ÉNERGIE?”. ACADÉMIE DES SCIENCES, GUY LAVAL EDITOR, (EDP

SCIENCES, 2007, ISBN 978-2-86883-862-9)

228. The mechanism of morphogenesis in a phase-separating concentrated multicomponent alloy

ZUGANG MAO, C.K. SUDBRACK, K.E. YOON, G. MARTIN, D. SEIDMAN

Nature Materials, 6, 3 (2007), 210-216.

229. Kinetics in non-equilibrium alloys

P. BELLON, G. MARTIN

In Alloy Physics, Edited by W. Pfeiler, Wiley-VCH, Germany, 2007, pp 423-489.

230. Radiation effects in concentrated alloys and compounds: equilibrium and kinetics of driven systems

G. MARTIN, P. BELLON, Comptes Rendus PHYSIQUE 9, 3-4 (2008), 323-334.

231. Contribution to: ”La Métallurgie”, RST Nº 31, Académie des Sciences, Yves Quéré et André Pineau Editors, EDP, France, 2011.

232. Enhanced Annealing of the Dislocation Network under Irradiation D. MORDEHAI, G. MARTIN, Phys. Rev. B in the press.

233. Kinetic pathways for phase separation: An atomic-scale study in Ni-Al-Cr alloys

ZUGANG MAO, C. BOOTH-MORRISON, C. K. SUDBRACK, G. MARTIN, D. N. SEIDMAN^, Acta Materialia 60 (2012) 1871–1888

234. A correlative four-dimensional study of phase-separation at the subnanoscale to nanoscale of a Ni-Al alloy, Elizaveta Y. Plotnikov, Zugang Mao, Sung-Il Baik, Mehmet Yildirim, Yongsheng Li , Daniel

Cecchetti, Ronald D. Noebe, Georges Martin, David N. Seidman

Acta Materialia 171 (2019) 306-333

Technical reports:

Technical reports:

R1 Tables de valeurs numériques pour les études de diffusion intergranulaire (Numerical tables for grain-boundary diffusion studies)

G. MARTIN, Report C.E.A. - R - 4363 (1972).

R2+ Modélisation de la précipitation dans les superalliages polyconstitués : de l'échelle atomique à l'échelle macroscopique (Modelling precipitation in multicomponent superalloys: from atomic scale up to macroscale)

T.A. ABINANDANAN, P. BELLON, G. MARTIN*, Colloque SNECMA, Evry 1993. 389.

R3 Pre and post irradiation properties of brazed joinings: microstructural stability of BNi7 under irradiation and modelling under NET conditions (Final report PSM4-2)

L. BOULANGER, P. BELLON, Y. SERRUYS, G. MARTIN, Note technique SRMP-93/51 (1993).

R4 Pre- and post-irradiation properties of brazed joinings: microstructural stability of copper/CFC and TZM/CFC under irradiations and modelling under NET conditions (Final report PPM5-7)

L. BOULANGER, P. BELLON, Y. SERRUYS, G. MARTIN, Note technique SRMP-93/51 (1993).

R5 Dose, Flux, Fluence

G. MARTIN, CEA- Note technique SRMP - 97.83

R6 Structure électronique des matériaux : CEA civil (Electronic structure of materials)

J.P. CROCOMBETTE, R. GUPTA, Y. LIMOGE, G. MARTIN Note Technique SRMP 97-84 (1997).

R7 Section de Recherches de Métallurgie Physique : Résultats (1990-1998) et perspectives.

(Physical metallurgy section : results and prospects )

G. MARTIN and coworkers, CEA-Note technique SRMP- 98-93.

R8 Relations entre la SRMP et la Technologie, en particulier à SRMA et SCECF

(connections between SRMP and technological laboratories) G. MARTIN and coworkers CEA-Note SRMP- 99-01.

R9 Phénomènes activés thermiquement et processus à seuil: application au cyclage thermique

(Thermally activated processes and thresholds: application to thermal cycling)

G. MARTIN, CEA-Note SRMP-99-06.

R10 Commentaires sur l'effet du rayon d'une sphère sur sa vitesse d'oxydation : cas du silicium

(Comments on the effect of the radius of a spherical body on its oxydation rate)

G. MARTIN, J.L. BOCQUET, Y. LIMOGE, Y. Le BOUAR, CEA-Note SRMP-00-01.