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Revisiting alloy design of low-modulus biomedical β-Ti alloys using an artificial neural network

Chun-Te Wu, Po‐Hsun Lin, Sih-Ying Huang, Yu-Jen Tseng, Hsiao-Tzu Chang, Sheng-Yen Li, Hung‐Wei Yen

2022Materialia22 citationsDOIOpen Access PDF

Abstract

An ensemble neural networks model is developed to detangle the complex effects of alloying elements on phase stability and Young's modulus, enabling design guidelines for low-modulus Ti alloy. This computational framework, which is named βLow 2.0, is validated and examined to understand the sensitivity of the modulus to the alloy composition for material selections. The exercise provides design guidelines for future material designs considering metastability of β phase and effects of Nb, Zr, Mo, Sn, and Ta. To evaluate this data-driven model, a basic uncertainty quantification function is applied to understand the model in the present data space. The results of the model validation are also presented with experimental data different from that of the calibration dataset. This work enables comprehensive metallurgical principles for alloy design by using neural network-based machine learning.

Topics & Concepts

Materials scienceArtificial neural networkAlloyModulusExperimental dataWork (physics)MetastabilitySensitivity (control systems)Stability (learning theory)CalibrationFunction (biology)Elastic modulusMechanical engineeringMachine learningComputer scienceMetallurgyComposite materialEngineeringStatisticsBiologyElectronic engineeringPhysicsQuantum mechanicsEvolutionary biologyMathematicsTitanium Alloys Microstructure and PropertiesOrthopaedic implants and arthroplastyHydrogen embrittlement and corrosion behaviors in metals