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Integrated computational materials design for high-performance alloys

Published online by Cambridge University Press:  27 November 2015

Wei Xiong
Affiliation:
Department of Materials Science and Engineering, Northwestern University, USA; [email protected] and [email protected]
Gregory B. Olson
Affiliation:
QuesTek Innovations LLC, USA; and Department of Materials Science and Engineering, Northwestern University, USA; [email protected]

Abstract

Major advances have been made over the past 30 years in the development of an integrated computational materials design (ICMD) technology. The hierarchical structure of its methods, tools, and supporting fundamental materials databases is reviewed here, with an emphasis on successful applications of CALPHAD (calculation of phase diagrams)-based tools as an example of ICMD, expressing mechanistic understanding in quantitative form to support science-based materials engineering. Opportunities are identified for rapid expansion of CALPHAD databases, as well as a major restructuring of materials education.

Type
Research Article
Copyright
Copyright © Materials Research Society 2015 

Introduction

In the past 25 years, many different programs have been launched to promote research in materials design, and several reports have been published regarding related activities in relevant research communities. An early report by the US National Research Council (NRC) in 1989 Reference Narath, Bement, Birely, Cohen, Kohn and Slichter1 placed great emphasis on the role of the universal relationship among processing, structure, properties, and performance (see Figure 1 Reference Olson2 ) for modern materials engineering and its impact on industrial applications. A 1999 NRC report Reference Stein, Allenby, Bucciarelli, Busch, Dieter, Doyle, Gjostein, Mackenzie, Manly, Paton, Pollock, Shaw, Shriver, Thomas and Wagoner3 presented a strong industry perspective with an emphasis on the materials needs of clients. Such an emphasis required innovations based on design in materials and mechanical engineering. The report highlighted the importance of performance during both manufacturing and service, as well as its connection to user needs and constraints, and explored the importance of potential approaches to the acceleration of the materials development cycle.

Figure 1. Three-link chain model of the central paradigm of materials science and engineering. Reproduced with permission from Reference Reference Olson2. © 1997 American Association for the Advancement of Science.

It should be especially noted that a 2004 report on accelerating technology transition released by the NRC Reference Apelian, Alleyne, Handwerker, Hopkins, Isaacs, Olson, Vaidyanathan and Wolf4 prioritized a materials fundamental database initiative in support of accelerated insertion of materials (AIM) technology. This report stated, “While the academic value system of the physical sciences has generally suppressed the creation of engineering databases, the life sciences have forged ahead with the Human Genome project representing the greatest engineering database in history. A parallel fundamental database initiative in support of computational materials engineering could build a physical science/engineering link as effective as the productive life science/medicine model.” The report recommended that “The Office of Science and Technology Policy should lead a national, multiagency initiative in computational materials engineering to address three broad areas: methods and tools, databases, and dissemination and infrastructure.” Reference Apelian, Alleyne, Handwerker, Hopkins, Isaacs, Olson, Vaidyanathan and Wolf4

In 2011, materials scientists were privileged to witness the unveiling of the Materials Genome Initiative (MGI) proposed by the US Office of Science and Technology Policy, further leveraging resources and capabilities of integrated computational materials engineering (ICME), Reference Pollock, Allison, Backman, Boyce, Gersh, Holm, LeSar, Long, Powell, Schirra, Whitis and Woodward5 which is a landmark for advancing computational materials modeling in practical engineering applications. The AIM technology is considered to be a major component of ICME techniques. Reference Pollock, Allison, Backman, Boyce, Gersh, Holm, LeSar, Long, Powell, Schirra, Whitis and Woodward5 As a result of the MGI, a complete integrated computational materials design (ICMD) hierarchical infrastructure for advanced materials development based on ICME and the materials genome is under construction as a global enterprise. Reference Olson6Reference Olson and Kuehmann11 One of the goals of this article is to review and clarify the different levels of this infrastructure.

Through a review of historical milestones and a discussion of promising research directions, this article takes a close look at state-of-the-art ICMD driven by engineering applications. The article starts with a history of alloy design. The framework of ICMD is then illustrated by reviewing representative integration efforts made through collaboration between research communities and industry. Finally, future research focuses for addressing remaining opportunities are recommended. It should be noted that, although the cases elucidated in this work are for metals and alloys, the thermodynamics-based methods of the ICMD infrastructure and the associated design philosophy should be applicable to polymers, ceramics, and biomaterials as well. Therefore, ICMD can be considered to be representative of the broader effort in computational materials science for engineering applications.

Milestones in alloy design

To be efficient, quantitative materials design needs informative databases from experiments or modeling. Without computational modeling, numerical solutions for theoretical equations are difficult to obtain, limiting the integration of theories for different phenomena. Therefore, design attempts made before the emergence of computational materials science were mainly based on trial-and-error experiments, which are time consuming and costly.

The earliest documented materials composition development was performed for the copper–tin-based alloy system in ancient China, generally known as the Bronze Age of China. Reference Mu, Nan, Wang, Song and Luo12,Reference Xing and Bunk13 In “Six Alloys” (or “Liu Qi”), optimal weight percentages of copper and tin were summarized to guide the casting of various civil and military tools (see Table I ). Reference Chang14 Certainly, this can be considered only as a purely empirical optimization of alloy compositions. It is remarkable that such an empirical development persisted for more than three millennia.

Table I. Compositions of copper–tin alloys for tool manufacturing.

These are documented in ancient China in Liu Qi, which presents six recipes for bronze and is the earliest known documentation of alloy compositions.

a One type of music instrument in the Shang Dynasty (ca. 1600–1046 BCE).

b Used for lighting fires by solar power.

A landmark in the field of predictive alloy design is the Hume-Rothery rules, Reference Massalski and Mizutani15 which have had a significant impact on research in physical metallurgy and materials science. These rules are for solid phases in metals and alloys and can be applied to both substitutional and interstitial solutions. Atomic size, electronegativity, valence, and crystal structure are considered to be the most important factors, based on experimental studies of numerous alloys performed by Hume-Rothery and colleagues. It should be noted that the Hume-Rothery rules are still used as component selection criteria. Tsai Reference Tsai16 showed that the Hume-Rothery rules are valid for all discovered stable quasicrystals with icosahedral structures by considering the characteristic range of valence concentrations in the quasicrystal alloys. Moreover, studies on the formation of high-entropy alloys also invoked size effects Reference Zhang, Zhou, Lin, Chen and Liaw17 and valence-electron concentration as criteria, Reference Guo, Ng, Lu and Liu18 in line with the Hume-Rothery rules.

Similarly to the Hume-Rothery rules based on single-phase attributes, another method focused on the deleterious topologically close-packed (TCP) phases, such as the σ phase, Reference Joubert19 in nickel superalloys. This method, called PHACOMP (from “phase computation”), was invented in 1964 Reference Boesch and Slaney20 based on the criterion of the average number of electron vacancies in the metal d band above the Fermi level. This method was later revised several times, and more refined models were proposed to cover more detrimental intermetallic phases in the model prediction. Reference Morinaga, Murata and Yukawa21Reference Murphy, Sims, Beltran and Donachie23 One of the pronounced disadvantages of this method is the temperature independence of the phase-stability criterion, which means that the model is valid for only a certain range of processing temperatures. As a consequence, it is quite limited in application to complex alloy processing. Despite many revised versions, Reference Morinaga, Murata and Yukawa21Reference Murphy, Sims, Beltran and Donachie23 PHACOMP is mainly used today for rough estimations to avoid the formation of TCP phases, rather than optimizations of composition and processing parameters. It should be mentioned that another improved method following the PHACOMP approach, called the d-electron method, Reference Matsugi, Murata, Morinaga, Yukawa, Antolovich, Stusrud, MacKay, Anton, Khan, Kissinger and Klarstrom24 was proposed that calculates the d-orbital energy level of the alloying transition element and the bond order as indicators for materials element selection. However, it also fails to optimize the alloy composition because of the very limitations inherited from PHACOMP. Reference Matsugi, Murata, Morinaga, Yukawa, Antolovich, Stusrud, MacKay, Anton, Khan, Kissinger and Klarstrom24,Reference Ikeda25 A principal limitation of such methods is their basis in attributes of a single phase rather than direct treatment of phase competition.

A true breakthrough in alloy design was initiated in 1956 Reference Kaufman and Cohen26 and developed throughout the 1970s, when Kaufman and co-workers formulated a methodology using thermodynamic models to compute phase diagrams of alloy and oxide systems based on experimental phase diagrams and thermochemical properties. This allowed for the evaluation of multiphase competition in multicomponent systems spanning wide composition and temperature ranges. Reference Spencer27 This method was named CALPHAD (from “calculation of phase diagrams”) and has become central to composition and process design. Reference Saunders and Miodownik28 After two decades of development since the 1970s, CALPHAD databases blossomed with the release of standard lattice stabilities by Scientific Group Thermodata Europe (SGTE) Reference Dinsdale29 in 1991.

Meanwhile, the development of software tools was correspondingly triggered to support thermodynamic database construction by the CALPHAD community. Because of the importance of diffusion phenomena in alloy design, the CALPHAD method was expanded to diffusion kinetics by researchers at the KTH Royal Institute of Technology in Stockholm, Sweden. Reference Borgenstam, Engstrom, Hoglund and Agren30 A landmark of this effort is the DICTRA (from “diffusional-controlled transformations”) multicomponent diffusion software released by the spinoff company Thermo-Calc Software, which was the first software developed for the simulation of kinetic diffusion in multicomponent alloy systems. CALPHAD databases now provide both Gibbs energies of alloy phases and atomic mobilities of different components in multicomponent systems, allowing for the modeling of both phase stability and phase transformations during alloy processing.

A comparison of CALPHAD with PHACOMP is shown in Figure 2 . In conjunction with a commercial thermodynamic database, Thermo-Calc provides a well-defined phase boundary for the face-centered cubic (fcc or γ) phase over a wide temperature range up to the melting point for each alloy composition. Because PHACOMP models for determining the σ-free phase boundary are applicable only in limited composition and temperature ranges, PHACOMP process designs address limited circumstances as compared to those obtained by the CALPHAD approach. Studies performed on nickel-based alloys* UDIMET 720 and UDIMET 720Li by Reed et al. Reference Reed, Jackson and Na31 demonstrated the strength of the CALPHAD method in superalloy design. In that work, a CALPHAD thermodynamic database was used to estimate σ-phase formation from the γ matrix phase. In addition, temperature–time–transformation diagrams were constructed for design purposes using the CALPHAD thermodynamic and kinetic databases.

Figure 2. Comparison of σ-phase boundary prediction between CALPHAD and PHACOMP for the (a) cobalt–nickel–chromium and (b) molybdenum–nickel–chromium systems. The red dashed line is the revised model proposed by Murphy et al. Reference Murphy, Sims, Beltran and Donachie23 Note: bcc, body-centered cubic; fcc, face-centered cubic. σ is the topologically close-packed embrittling phase.

Over the past three decades, CALPHAD-based alloy design has been carried out in the Steel Research Group design consortium led by Northwestern University and its spin-off company QuesTek Innovations LLC, funded by government research agencies with supplemental industry support. This can be considered as the full ICMD process applied to different kinds of materials. It has directly driven materials development to the top technology readiness level (TRL), Reference Mankins32,33 as defined by the US National Aeronautics and Space Administration (NASA) for components in flight, and demonstrated the capability of computational materials design and accelerated qualification for brand-new alloy compositions on an industrial scale. Figure 3 shows the achievement of a total of seven component-level TRLs corresponding to specific achievement levels of materials properties and manufacturability for two computationally designed landing-gear steels.

Figure 3. Time evolution of component-level technology readiness levels (TRLs) and materials development milestones for the two computationally designed landing-gear steels Ferrium S53 and M54 developed by QuesTek Innovations LLC. Reference Olson and Kuehmann11 Application of Materials by Design and accelerated insertion of materials technology greatly accelerated the development of Ferrium S53 and M54. Note: MMPDS, Metallic Materials Properties Development and Standardization. Adapted with permission from Reference Reference Olson and Kuehmann11. © 2014 Elsevier.

The development of aerospace materials by the traditional approach requires more than 15 years from concept to final manufacturing for testing under real conditions. Reference Pollock, Allison, Backman, Boyce, Gersh, Holm, LeSar, Long, Powell, Schirra, Whitis and Woodward5 In contrast, using the ICMD technique, this development cycle can be shortened significantly. The development of ultrahigh-strength steels Ferrium S53 and M54 took only 8.5 years and 6 years, respectively, to reach materials flight qualification. Both steels are now replacing current landing-gear steels. Prototype hook-shank arresting gear components manufactured from Ferrium M54 steel are flying in US Navy T-45 aircraft, and Ferrium S53 steel landing gears have been flying on T-38 supersonic training jets since December 2010. Development of the ICMD approach approved for designing Ferrium S53 and M54 is discussed in the next section.

Development of the iCMD infrastructure

Strategy of iCMD application

The hierarchical infrastructure of the ICMD process developed by QuesTek, denoted as iCMD, is sketched in Figure 4 . Reference Olson and Kuehmann11 It is built on two primary methods, namely, Materials by Design and AIM, which are both grounded in mechanistic models. The underlying materials genome corresponds to the fundamental databases supporting mechanistic modeling to reach a higher level of quantitative model accuracy. The current discussion examines each structural component of the iCMD system.

Figure 4. Overall hierarchical architecture of QuesTek’s iCMD methods, tools (green), and databases (yellow) for next-generation computational materials design and accelerated qualification. Reference Olson and Kuehmann11 Note that iCMD is a toolkit used during application of ICME methods based on the materials genome. Reproduced with permission from Reference Reference Olson and Kuehmann11. © 2014 Elsevier.

In Figure 4, the top-level iCMD framework summarizes the complete materials design and development cycle, as a new material is moved through its sequence of TRLs, culminating in statistically validated minimum property “design allowables” for the materials user at the component level. Successful materials development driven by engineering applications needs to be scaled up from laboratory processing to industrial manufacturing. Technology readiness assessment 33 quantifies materials development from concept generation to practical process specification, ending with qualification, as shown in Figure 4. Development of an engineering-applicable alloy before industrial commercialization requires a minimum level of TRL6, which is a demonstration of a system/subsystem model or prototype in a relevant end-to-end environment.

Development of a completely new alloy goes through three phases, as shown in Figure 4. Phase I requires a broad understanding of materials performance and cost impacts of manufacturing and processing; product installation and use; operations, repair, and maintenance; recycling/reuse; and other factors encountered along the manufacturing and application chains. Therefore, a project kickoff meeting is conducted to discuss the initial property design goals between materials designers and clients, who can be producers, original equipment manufacturers, and sometimes end users and key stakeholders. Preliminary computations are then launched using Materials by Design. An initial TRL roadmap, such as that in Figure 3, is outlined at this stage, assisted by initial feasibility calculations. This roadmap includes defining tests to demonstrate key material properties, manufacturability from initial prototype to industrial scale, and processing requirements.

Evaluation of the concept with preliminary design ideas is the final outcome of phase I. Using iCMD, the toolkit developed for systems design (see Figure 4), materials designers can perform preliminary modeling of alternative concepts. Thus, the whole process is expedited compared to traditional concept evaluation without design tools.

After the options for a design concept have been narrowed, detailed design, modeling, and invention activities are performed iteratively in concert with prototype material evaluation. Laboratory-scale alloys are processed following the conceptual design. Preliminary results on these alloys are utilized reciprocally to calibrate iCMD models and extend databases. Two or three design iterations are typically required, with refinement not only for composition and processing of the prototype alloys, but also for design models and databases. The fidelity of the design models and databases is thus constantly improved through this feedback loop.

The cause-and-effect logic of processing–structure–property model refinement with iterative feedback is summarized in Figure 5 . Production of the prototype material provides an important feedback mechanism for the iterative approach of Materials by Design. Through the analysis of prototypes, initial design qualities can be evaluated to further validate and refine computational mechanistic models and design tools and to optimize designed composition and processing paths. Complete microstructural characterization and property analysis using combined experimental techniques is essential for full optimization.

Figure 5. Working flowchart for revealing process–microstructure–property relations.

As the next step, iCMD can be utilized to optimize alloy processing and composition specifications and thus achieve the best possible balance of microstructural features (including at the nanoscale) and properties. When optimal process conditions for a prototype alloy have been determined, the materials properties are validated according to the TRL roadmap show in Figure 3. Through processability constraints derived from macroscopic process simulations of final production-scale requirements, parametric design constraints applied during phase I ensure the scalability of material production.

Modeling efforts during phase II include the refinement and implementation of mechanistic models to address critical factors in the design of the down-selected concepts. Materials designers continue to refine key parameters in fundamental property databases and estimate database accuracy within the targeted design range. The whole process is performed by applying the iCMD toolkit, which includes an application program interface that allows extra implementation of project-specific design models. The iCMD platform allows materials designers to exploit specific microstructural features and search for design optima across length scales from atomistic to component level. This stage typically culminates in the detailed design of one or more materials for subscale prototype production and evaluation. Review meetings between materials designers and clients are helpful to update the risk map, predict values of critical design factors, and clarify design tradeoffs and materials specifications. This generates a prototyping plan that recommends suppliers or service providers for each production step, evaluates process sequences, and plans characterization and testing efforts to validate model predictions and materials properties at the prototype scale.

In robust materials design, the lowest bounds of mechanical properties need to be predicted with the highest level of confidence. Therefore, probabilistic models are implemented in iCMD. To minimize intrinsic variations in parametric design, Monte Carlo simulations are performed in which parameters are varied within the allowed tolerances of input parameters, such as alloy composition, processing time, and temperature. Figure 6 shows an example of Monte Carlo sensitivity analysis based on a variation of alloy composition for the uncertainty analysis of the scale-up of Ferrium S53 steels. Reference Kuehmann35

Figure 6. Sensitivity analysis with composition variations for Ferrium S53 alloys. Reference Kuehmann35 Results were generated by 1000 runs on a Pentium IV 2.2-GHz CPU for 12 min. Precipitation phases include the M2C carbide phase and intermetallics. Reproduced with permission from Reference Reference Kuehmann35. © 2006 C. Kuehmann.

In phase III (Figure 4), AIM qualification and uncertainty management directly influence the timeline for commercializing newly designed alloys. Under the US Defense Advanced Research Projects Agency (DARPA) AIM program of 2001–2003, Reference Apelian, Alleyne, Handwerker, Hopkins, Isaacs, Olson, Vaidyanathan and Wolf4 QuesTek’s PrecipiCalc microstructural simulator was integrated with finite-element heat-transfer simulations to accelerate thermal process optimization of nickel-based superalloy aeroturbine disks. The CALPHAD-based PrecipiCalc mean-field precipitation code Reference Jou, Voorhees, Olson, Green, Pollock, Harada, Howson, Reed, Schirra and Walston36 was optimized to balance accuracy and efficiency in the prediction of the phase compositions and size distributions of trimodal γ′ precipitate populations, alloy carbides, and associated Zener-pinned grain size, for the accurate prediction of alloy strength using calibrated analytical structure–property models. Predictive process optimization of a subscale IN100 alloy disk was validated by overspin burst tests, with companion disk forgings sectioned to validate the predicted spatial distribution of microstructure and strength, the latter validated to within 1 ksi (7 MPa). A large-scale Monte Carlo simulation of manufacturing variation was then performed using recorded process-variable distributions over six stages of thermomechanical and thermal disk processing, for a legacy turbine disk application with a well-established final property distribution. Using the science-based prediction of the shape of the strength probability density function (PDF), a final data fusion strategy was devised whereby small randomly selected strength datasets were used to recalibrate the PDF by linear transformation Reference Gary Harlow37 to account for additional epistemic variation. It was demonstrated that as few as 15 random data points could be fused with the calculated PDF to predict the 1% minimum strength value within 1 ksi (7 MPa), corresponding to the experimental error of the strength measurement.

The first application of the AIM method to forecast minimum strength properties during qualification of a new material was demonstrated for the aforementioned Ferrium S53 landing-gear steel. The exercise used limited data from three production-scale heats (as required for aerospace material specification S-basis allowables 38 ) to forecast the final 1% minimum strength as ultimately validated by 10 full production heats (as required for Metallic Materials Properties Development and Standardization [MMPDS] A-basis allowables 38 ), within 1 ksi (7 MPa).

As summarized in the time evolution of component-level TRLs and corresponding material qualification milestones shown in Figure 3, Reference Olson and Kuehmann11 recent AIM-accelerated qualification of a second aircraft landing-gear steel (Ferrium M54) compressed the full materials design and qualification cycle from a clean sheet to MMPDS materials qualification to under six years. Reference Olson and Kuehmann11 This early success attested to the feasibility of the acceleration goals of the US Materials Genome Initiative. Reference Holdren34

The current frontier of AIM methodology development is uncertainty management in the prediction of microstructures and properties. A follow-up project addressed protocols for management of quantified uncertainty in all aspects of PrecipiCalc-based AIM process–structure modeling, using a series of third-generation alloys for aeroengine turbine disks, in preparation for accelerated process optimization of dual-microstructure heat treatment for enhanced hybrid-disk performance. Reference Jou, Voorhees, Olson, Green, Pollock, Harada, Howson, Reed, Schirra and Walston36 The standard error of each model prediction was characterized experimentally by standard practices. A hierarchical uncertainty-management strategy was adopted, balancing final structure–property model sensitivity against the intrinsic accuracy of the fundamental databases employed in process–structure predictions. For fixed alloy compositions, high-temperature equilibration experiments were used to assess the error in the predicted phase fraction from the CALPHAD genomic databases. Because of the dominant role of phase fraction in strength models, the phase-fraction error was efficiently reduced (to the level of experimental error) by applying rigid shifts to the second-phase free-energy functions in the thermodynamic database. With the recalibrated volume thermodynamics fixed, high-temperature diffusion couples were then run against pure nickel for each alloy and compared with DICTRA diffusion simulations combining the thermodynamic database with atomic-mobility databases for diffusivity prediction. Improved accuracy of the diffusivity predictions was then achieved by small adjustments (on the order of 20%) in the mobility prefactors of some of the alloy components.

With the thermodynamic and mobility databases thus recalibrated for the specific alloys, important surface thermodynamic quantities were then calculated. In view of the high sensitivity of nucleation to interfacial energy, the γ/γ′ coherent interfacial energy was efficiently measured using a cost-effective single-sensor differential thermal analysis technique to directly measure the critical nucleation undercooling in each alloy in rapidly quenched 3-mm-diameter pins. Using the precisely measured thermal history of each pin, the interfacial energy was calibrated in PrecipiCalc simulations to match the observed critical undercooling. Validation of the PrecipiCalc-predicted final microstructure in the pins by atom-probe microanalysis then demonstrated high accuracy in a far-from-equilibrium microstructure. The high precision of microstructural predictions employed in AIM process optimization motivated the Office of Naval Research/DARPA “D3D” (digital three-dimensional) structure consortium program from 2005 to 2010 to assemble a suite of 3D tomographic characterization tools addressing phase distributions at multiple length scales, to bring experimental microstructural characterization to a new level of fidelity to support this technology. Reference Olson and Kuehmann11

Materials genome: The database foundation

As the foundation of ICME, materials genome fundamental databases are the cornerstone of the iCMD infrastructure. Developing reliable protodata and processed data in repositories with sustainable maintenance is a prior requirement. As indicated in Figure 4, ICME models of multiphase dynamic microstructural evolution are structured to be quantitative by the materials genome foundation, consisting of fundamental genomic databases describing thermochemical, physical, and kinetic attributes as functions of the chemical composition and temperature at the phase level. In addition, application of iCMD is aided by an effective selection search system, allowing for exhaustive research to assist decision making during phase and component selection in early stages of materials design.

Figure 4 shows research activities that contribute to accelerated genomic database development. In alloy design, atomistic modeling based on density functional theory (DFT) provides helpful fundamental values to many other modeling techniques. CALPHAD database development based on DFT digital input has already made significant progress. Related studies have further extended the integrated DFT and CALPHAD methodology from thermodynamics to diffusion. The CALPHAD approach also necessitates experimental data as primary input. Hence, further development of efficient experimental techniques to support integration of DFT atomistic modeling and CALPHAD is one of the major focuses in the Materials Genome Initiative. Reference Holdren34 Important contributions have been made in the field of high-throughput experimental techniques. Reference Zhao, Jackson, Peluso and Brewer39Reference Wei, Zheng, Cahill and Zhao43

Opportunities and outlook

Opportunities for further enhancement of the ICMD approach can be found in four areas: (1) performance of fundamental genomic research, (2) enhancement of databases and repositories, (3) development of linkage models for ICME research, and (4) teaching of ICME approaches in materials science and engineering programs.

On the foundational level of the materials genome, substantial improvement of its methods could have a broad impact. For example, evaluating magnetic effects on phase stability using quantum mechanical DFT models, such as for fcc iron, is still a challenge. Reference Sánchez-Barriga, Fink, Boni, Di Marco, Braun, Minár, Varykhalov, Rader, Bellini, Manghi, Ebert, Katsnelson, Lichtenstein, Eriksson, Eberhardt and Durr44Reference Ruban and Abrikosov47 The current physical model is not sufficient for magnetic substances with itinerant spin orbitals, such as iron and chromium. In fact, similar issues limit the CALPHAD approach as well. Reference Massalski and Laughlin46,Reference Xiong, Chen, Korzhavyi and Selleby48,Reference Xiong, Hedstrom, Selleby, Odqvist, Thuvander and Chen49

A recent workshop on phase transformations highlighted several future directions for atomistic modeling and the CALPHAD approach in alloy development. The reports from this workshop Reference Becker, Ågren, Baricco, Chen, Decterov, Kattner, Perepezko, Pottlacher and Selleby50Reference Rogal, Divinski, Finnis, Glensk, Neugebauer, Perepezko, Schuwalow, Sluiter and Sundman54 cover thermodynamic modeling of crystalline and liquid-amorphous phases, high-pressure systems, magnetic transitions, and defects and provide guidance for the next generation of database development for the materials genome. As a consequence, more effort is needed to transfer these models into materials genomic tools, such as Thermo-Calc and DICTRA, that can facilitate the development of more accurate databases. It is noteworthy that, as one of the components in the materials innovation infrastructure, Reference Holdren34 improvement of experimental tools for high-throughput purposes is also valuable. A convincing example is the high-throughput experimental diffusion multiple for large-scale determinations of diffusivities and thermophysical quantities for database construction. Reference Zhao, Jackson, Peluso and Brewer39,Reference Wei, Zheng, Cahill and Zhao43

Secondly, model predictions using ICMD rely heavily on the quality of genomic databases. Therefore, database development should be the highest-priority research topic to support ICMD. Database sharing and development also demand standards. Taking CALPHAD as an example, if lattice stability had not been standardized by SGTE, Reference Dinsdale29 CALPHAD would not have been broadly adopted in practical materials design. Fortunately, the US National Institute of Standards and Technology is creating data repositories and setting up standards for materials genomic databases. Reference Campbell, Kattner and Liu8 Such efforts call for greater involvement of different scientific communities across different disciplines.

Regarding enhancement of the ICME framework, systems design can benefit from further advances in linkage models of process–structure and structure–property relations. Here, advances in continuum modeling methods have more to contribute. It should be noted that precipitation modeling based on classical theory, such as the Kampmann–Wagner numerical model, Reference Wagner, Kampmann, Voorhees and Kostorz55 has been used in industrial process optimization, fostering several revised models. Reference Chen, Jeppsson and Agren56Reference Robson58 Similarly, structure–property linkage models for mechanical behavior are rapidly advancing through new methods of micromechanical simulation and, in particular, are being investigated to provide empirical correlations prior to mechanistic understanding, such as the neural network method. Reference Bhadeshia59 We note that, although significant research has been performed using these techniques separately, limited work has been reported so far that integrates mechanistic models and materials genomic databases using neural network modeling and data-mining techniques.

Because the ICMD infrastructure is a hierarchical architecture integrating different engineering approaches of materials and mechanical engineering, educational program design becomes more challenging, requiring engineering design courses at different levels in a multiyear curriculum. However, a survey on computational materials science and engineering education summarized in Table II Reference Thornton, Nola, Garcia, Asta and Olson60 found that the present education in materials genomic methods and ICME tools is generally lacking. The results are based on responses from 43 survey participants, including 29 US universities, one Canadian university, nine materials-related industrial companies, and four materials research laboratories. Reference Thornton, Nola, Garcia, Asta and Olson60 The index column in Table II indicates the adequacy of education programs and faculty numbers in related teaching fields, where lower values reflect insufficient programs. Surprisingly, although CALPHAD appears to be one of the most useful computational techniques in industry (see the employer column in Table II), the importance of teaching CALPHAD and computational diffusion knowledge is underestimated in academic institutions. Therefore, related curricula should be considered in the course design for materials and processing education. A leading example of multiyear design education at Northwestern University is described in the recent Materials Genome Institute Strategic Plan. 61

Table II. Computational materials modeling methods and tools. a

These are cited by employers, categorized and ranked by the normalized frequency of citations, along with corresponding results from a survey of computational faculty. a

a Adapted with permission from Reference Reference Thornton, Nola, Garcia, Asta and Olson60. © 2009 Springer.

b Some of the responses did not provide software or categories, and, therefore, one expects some degree of undercounting in these data.

c Index = Faculty/Employer.

Acknowledgments

This work was performed within the CHiMaD Center for Hierarchical Materials Design at the Northwestern University, funded by the National Institute of Standards and Technology. Materials by Design, Ferrium, ICMD, and iCMD are trademarks of QuesTek Innovations LLC.

Footnotes

* Compositions (wt%): UDIMET 720, Ni–2.49Al–0.032B–0.02C–14.8Co–18Cr–0.03Fe–3.04Mo–0.003N–4.98Ti–1.25W; UDIMET 720Li, Ni–2.57Al–0.015B–0.011C–14.7Co–16.3Cr–0.01Fe–3.00Mo–0.002N–5.02Ti–1.31W.

References

Narath, A., Bement, A.L., Birely, J.H., Cohen, M., Kohn, W., Slichter, W.P., Materials Science and Engineering for the 1990s: Maintaining Competitiveness in the Age of Materials (National Academies Press, Washington, DC, 1989).Google Scholar
Olson, G.B., Science 277, 1237 (1997).Google Scholar
Stein, D., Allenby, B.R., Bucciarelli, L.L., Busch, J.V., Dieter, G.E., Doyle, W.D., Gjostein, N.A., Mackenzie, H.R., Manly, W.D., Paton, N.E., Pollock, T.M., Shaw, J.M., Shriver, R.D., Thomas, M.C., Wagoner, R.H., Materials Science and Engineering: Forging Stronger Links to Users (National Academies Press, Washington, DC, 1999).Google Scholar
Apelian, D., Alleyne, A., Handwerker, C.A., Hopkins, D., Isaacs, J.A., Olson, G.B., Vaidyanathan, R., Wolf, S.D., Accelerating Techology Transition: Bridge the Valley of Death for Materials and Processes in Defense Systems (National Academies Press, Washington, DC, 2004).Google Scholar
Pollock, T.M., Allison, J.E., Backman, D.G., Boyce, M.C., Gersh, M., Holm, E.A., LeSar, R., Long, M., Powell, A.C. IV, Schirra, J.J., Whitis, D.D., Woodward, C., Integrated Computational Materials Engineering: A Transformational Discipline for Improved Competitiveness and National Security (National Academies Press, Washington, DC, 2008).Google Scholar
Olson, G.B., Scr. Mater. 70, 1 (2014).Google Scholar
Kaufman, L., Ågren, J., Scr. Mater. 70, 3 (2014).Google Scholar
Campbell, C.E., Kattner, U.R., Liu, Z.K., Scr. Mater. 70, 7 (2014).Google Scholar
Bhadeshia, H.K.D.H., Scr. Mater. 70, 12 (2014).Google Scholar
Christensen, S., D’Oyen, R., Scr. Mater. 70, 18 (2014).CrossRefGoogle Scholar
Olson, G.B., Kuehmann, C.J., Scr. Mater. 70, 25 (2014).CrossRefGoogle Scholar
Mu, D., Nan, P.H., Wang, J.Y., Song, G.D., Luo, W.G., JOM 67, 1659 (2015).CrossRefGoogle Scholar
Xing, L.Q., Bunk, W.G., Giesserei 84, 20 (1997) (in German).Google Scholar
Chang, T.-K., J. Tsinghua Univ. 4, 159 (1958).Google Scholar
Massalski, T.B., Mizutani, U., Prog. Mater. Sci. 22, 151 (1978).Google Scholar
Tsai, A.P., MRS Bull. 22, 43 (1997).CrossRefGoogle Scholar
Zhang, Y., Zhou, Y.J., Lin, J.P., Chen, G.L., Liaw, P.K., Adv. Eng. Mater. 10, 534 (2008).CrossRefGoogle Scholar
Guo, S., Ng, C., Lu, J., Liu, C.T., J. Appl. Phys. 109, 103505 (2011).Google Scholar
Joubert, J.M., Prog. Mater. Sci. 53, 528 (2008).Google Scholar
Boesch, W.J., Slaney, J.S., Met. Prog. 86, 109 (1964).Google Scholar
Morinaga, M., Murata, Y., Yukawa, H., J. Mater. Sci. Technol. 19, 73 (2003).Google Scholar
Morinaga, M., Yukawa, N., Adachi, H., Ezaki, H., “New PHACOMP and Its Applications to Alloy Design,” Proc. Fifth Int. Symp. Superalloys, Gell, M., Kortovich, M.C.S., Bricknell, R.H., Kent, W.B., Radavich, J.F., Eds. (TMS, Warrendale, PA, 1984), pp. 523532.Google Scholar
Murphy, H.J., Sims, C.T., Beltran, A.M., “PHACOMP Revisited,” Proceedings of the International Symposium on Structural Stability in Superalloys, Donachie, M., Ed. (TMS, Warrendale, PA, 1968), pp. 4766.Google Scholar
Matsugi, K., Murata, Y., Morinaga, M., Yukawa, N., “Realistic Advancement for Nickel-Based Single Crystal Superalloys by the d-Electrons Concept,” Proceedings Seventh Int. Symp. Superalloys, Antolovich, S.D., Stusrud, R.W., MacKay, R.A., Anton, D.L., Khan, T., Kissinger, R.D., Klarstrom, D.L., Eds. (TMS, Warrendale, PA, 1992), pp. 307316.Google Scholar
Ikeda, Y., Mater. Trans. JIM 38, 771 (1997).Google Scholar
Kaufman, L., Cohen, M., J. Met. 8, 1393 (1956).Google Scholar
Spencer, P.J., Calphad 32, 1 (2008).Google Scholar
Saunders, N., Miodownik, P., CALPHAD (Calculation of Phase Diagrams): A Comprehensive Guide, 1st ed. (Elsevier Science, New York, 1998).Google Scholar
Dinsdale, A.T., Calphad 15, 317 (1991).Google Scholar
Borgenstam, A., Engstrom, A., Hoglund, L., Agren, J., J. Phase Equilib. 21, 269 (2000).Google Scholar
Reed, R.C., Jackson, M.P., Na, Y.S., Metall. Mater. Trans. A 30, 521 (1999).Google Scholar
Mankins, J.C., Technology Readiness Levels: A White Paper (NASA, Washington, DC, 1995).Google Scholar
Technology Readiness Assessment (TRA) Guidance (US Department of Defense, Washington, DC, 2011).Google Scholar
Holdren, J.P., Materials Genome Initiative for Global Competitiveness (National Science and Technology Council, Washington, DC, 2011).Google Scholar
Kuehmann, C., “Development and Qualification of S53 Ultrahigh-Strength Corrosion Resistant Steel for Cadmium Replacement,” presented at the 26th Replacement of Hard Chrome and Cadmium Plating Program Review Meeting, San Diego, January 24–26, 2006.Google Scholar
Jou, H.-J., Voorhees, P.W., Olson, G.B., “Computer Simulations for the Prediction of Microstructure/Property Variation in Aeroturbine Disks,” Proc. Tenth Inter. Symp. on Superalloys, Green, K.A., Pollock, T.M., Harada, H., Howson, T.E., Reed, R.C., Schirra, J.J., Walston, S., Eds. (TMS, Warrendale, PA, 2004), pp. 877886.Google Scholar
Gary Harlow, D., Eng. Fract. Mech. 74, 2943 (2007).CrossRefGoogle Scholar
Metallic Materials Properties Development and Standardization (MMPDS) Handbook: MMPDS-09 (Battelle Memorial Institute, Columbus, OH, 2014).Google Scholar
Zhao, J.-C., Jackson, M.R., Peluso, L.A., Brewer, L.N., MRS Bull. 27, 324 (2002).Google Scholar
Zhao, J.-C., Annu. Rev. Mater. Res. 35, 51 (2005).CrossRefGoogle Scholar
Zhao, J.C., J. Mater. Sci. 39, 3913 (2004).Google Scholar
Zhao, J.C., Zheng, X., Cahill, D.G., Mater. Today 8, 28 (2005).Google Scholar
Wei, C., Zheng, X., Cahill, D.G., Zhao, J.-C., Rev. Sci. Instrum. 84, 071301 (2013).Google Scholar
Sánchez-Barriga, J., Fink, J., Boni, V., Di Marco, I., Braun, J., Minár, J., Varykhalov, A., Rader, O., Bellini, V., Manghi, F., Ebert, H., Katsnelson, M.I., Lichtenstein, A.I., Eriksson, O., Eberhardt, W., Durr, H.A., Phys. Rev. Lett. 103, 267203 (2009).Google Scholar
Lichtenstein, A.I., Katsnelson, M.I., Kotliar, G., Phys. Rev. Lett. 87, 672051 (2001).CrossRefGoogle Scholar
Massalski, T.B., Laughlin, D.E., Calphad 33, 3 (2009).Google Scholar
Ruban, A.V., Abrikosov, I.A., Rep. Prog. Phys. 71, 046501 (2008).Google Scholar
Xiong, W., Chen, Q., Korzhavyi, P.A., Selleby, M., Calphad 39, 11 (2012).Google Scholar
Xiong, W., Hedstrom, P., Selleby, M., Odqvist, J., Thuvander, M., Chen, Q., Calphad 35, 355 (2011).Google Scholar
Becker, C.A., Ågren, J., Baricco, M., Chen, Q., Decterov, S.A., Kattner, U.R., Perepezko, J.H., Pottlacher, G.R., Selleby, M., Phys. Status Solidi B 251, 33 (2014).CrossRefGoogle Scholar
Hammerschmidt, T., Abrikosov, I.A., Alfè, D., Fries, S.G., Höglund, L., Jacobs, M.H.G., Koßmann, J., Lu, X.G., Paul, G., Phys. Status Solidi B 251, 81 (2014).Google Scholar
Körmann, F., Breidi, A.A.H., Dudarev, S.L., Dupin, N., Ghosh, G., Hickel, T., Korzhavyi, P., Muñoz, J.A., Ohnuma, I., Phys. Status Solidi B 251, 53 (2014).Google Scholar
Palumbo, M., Burton, B., Costa e Silva, A., Fultz, B., Grabowski, B., Grimvall, G., Hallstedt, B., Hellman, O., Lindahl, B., Schneider, A., Turchi, P.E.A., Xiong, W., Phys. Status Solidi B 251, 14 (2014).Google Scholar
Rogal, J., Divinski, S.V., Finnis, M.W., Glensk, A., Neugebauer, J., Perepezko, J.H., Schuwalow, S., Sluiter, M.H.F., Sundman, B., Phys. Status Solidi B 251, 97 (2014).CrossRefGoogle Scholar
Wagner, R., Kampmann, R., Voorhees, P.W., in Phase Transformations in Materials, Kostorz, G., Ed. (Wiley-VCH, Weinheim, Germany, 2005), chap. 5, pp. 309407.Google Scholar
Chen, Q., Jeppsson, J., Agren, J., Acta Mater. 56, 1890 (2008).Google Scholar
Jeppsson, J., Agren, J., Hillert, M., Acta Mater. 56, 5188 (2008).Google Scholar
Robson, J.D., Mater. Sci. Technol. 20, 441 (2004).CrossRefGoogle Scholar
Bhadeshia, H.K.D.H., ISIJ Int. 39, 966 (1999).Google Scholar
Thornton, K., Nola, S., Garcia, R.E., Asta, M., Olson, G.B., JOM 61, 12 (2009).Google Scholar
“Fostering Education in MGI Techniques,” in Materials Genome Initiative Strategic Plan (National Science and Technology Council, Washington, DC, June 2014), p. 24.Google Scholar
Figure 0

Figure 1. Three-link chain model of the central paradigm of materials science and engineering. Reproduced with permission from Reference 2. © 1997 American Association for the Advancement of Science.

Figure 1

Table I. Compositions of copper–tin alloys for tool manufacturing.

Figure 2

Figure 2. Comparison of σ-phase boundary prediction between CALPHAD and PHACOMP for the (a) cobalt–nickel–chromium and (b) molybdenum–nickel–chromium systems. The red dashed line is the revised model proposed by Murphy et al.23 Note: bcc, body-centered cubic; fcc, face-centered cubic. σ is the topologically close-packed embrittling phase.

Figure 3

Figure 3. Time evolution of component-level technology readiness levels (TRLs) and materials development milestones for the two computationally designed landing-gear steels Ferrium S53 and M54 developed by QuesTek Innovations LLC.11 Application of Materials by Design and accelerated insertion of materials technology greatly accelerated the development of Ferrium S53 and M54. Note: MMPDS, Metallic Materials Properties Development and Standardization. Adapted with permission from Reference 11. © 2014 Elsevier.

Figure 4

Figure 4. Overall hierarchical architecture of QuesTek’s iCMD methods, tools (green), and databases (yellow) for next-generation computational materials design and accelerated qualification.11 Note that iCMD is a toolkit used during application of ICME methods based on the materials genome. Reproduced with permission from Reference 11. © 2014 Elsevier.

Figure 5

Figure 5. Working flowchart for revealing process–microstructure–property relations.

Figure 6

Figure 6. Sensitivity analysis with composition variations for Ferrium S53 alloys.35 Results were generated by 1000 runs on a Pentium IV 2.2-GHz CPU for 12 min. Precipitation phases include the M2C carbide phase and intermetallics. Reproduced with permission from Reference 35. © 2006 C. Kuehmann.

Figure 7

Table II. Computational materials modeling methods and tools.a