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BeyondFingerprinting: AI-guided discovery of robust materials & processes

Boyce, Brad L.; Dingreville, Remi P.M.; Adams, David P.; Martinez, Carianne; Fowler, James E.; Pillars, Jamin R.; Wixom, Ryan R.; Moffat, Harry K.; Davis, Warren L.; Ackerman, Sarah; Speed, Ann E.; Garland, Anthony; Roberts, Scott A.; Coleman, Jonathan J.; Delrio, Frank W.; Cillessen, Dale E.; Carroll, J.D.; Najm, Habib N.; Curry, John F.; Johnson, Kyle L.; Dudley, Sarah K.; Addamane, Sadhvikas J.; Henriksen, Amelia; Custer, Joyce O.; Bays, Nathan R.; Desai, Saaketh; Bassett, Kimberly L.; Shilt, Troy; Walker, Elise; Kalaswad, Matias; Shrivastava, Ankit; Babuska, Tomas F.; Kottwitz, Matthew; Fitzgerald, Kaitlynn; Actor, Jonas A.; Das, Niladri; Bianco, Nathan R.; Watkins, Tylan; Dorman, Kyle R.; Jones, Reese E.; Khalil, Mohammad

BeyondFingerprinting was a 2021-2024 Sandia Grand Challenge LDRD exploring the potential to develop new resilient materials and manufacturing processes by taking an artificial-intelligence (AI)-guided approach that integrates human-subject-matter expertise with algorithms enriched with physics-based constraints to unearth process-structure-property correlations. Such algorithms, trained on high-throughput experiments and simulations, are shown to serve as surrogate models that efficiently detect key “fingerprints” in materials data, prognose material performance, and guide effective process improvements. To accelerate broader adoption across mission areas, this AI-guided approach was demonstrated with three complex process-centric exemplars: electroplating, physical vapor deposition, and laser powder bed fusion. Together, these exemplars impact nearly every hardware component relevant to DOE and NNSA national security missions.

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Electrodeposition of Tungsten using Hydrotropic Agents

Pillars, Jamin R.

The current work sought to electrodeposit tungsten from water-based solutions. The work’s initial hypothesis was that methoxide reducing agents could be used to generate urea anions that could enable tungsten electrodeposition. Unfortunately, this hypothesis was found to be incorrect. However, the work led to the understanding that chemical reducing agents not only enable the electrodeposition of refractory metals like rhenium from water-based solutions, but that the key to plating tungsten in the future involves chemical reduction followed by stabilization with proper ligands. The work resulted in a manuscript under review at Inorganic Chemistry Communications on the discovered of L-histidine as a suitable reducing agent from rhenium electrodeposition. Rhenium-tungsten alloys with 4% tungsten were deposited. A technical advance was filed for the rhenium chemistry and parts were delivered to an internal Sandia customer that used the chemistry.

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A Workflow for Accelerating Multimodal Data Collection for Electrodeposited Films

Integrating Materials and Manufacturing Innovation

Bassett, Kimberly L.; Watkins, Tylan; Coleman, Jonathan J.; Bianco, Nathan R.; Bailey, Lauren S.; Pillars, Jamin R.; Williams, Samuel G.; Babuska, Tomas F.; Curry, John F.; Delrio, Frank W.; Henriksen, Amelia; Garland, Anthony; Hall, Justin; Boyce, Brad L.; Krick, Brandon A.

Future machine learning strategies for materials process optimization will likely replace human capital-intensive artisan research with autonomous and/or accelerated approaches. Such automation enables accelerated multimodal characterization that simultaneously minimizes human errors, lowers costs, enhances statistical sampling, and allows scientists to allocate their time to critical thinking instead of repetitive manual tasks. Previous acceleration efforts to synthesize and evaluate materials have often employed elaborate robotic self-driving laboratories or used specialized strategies that are difficult to generalize. Herein we describe an implemented workflow for accelerating the multimodal characterization of a combinatorial set of 915 electroplated Ni and Ni–Fe thin films resulting in a data cube with over 160,000 individual data files. Our acceleration strategies do not require manufacturing-scale resources and are thus amenable to typical materials research facilities in academic, government, or commercial laboratories. The workflow demonstrated the acceleration of six characterization modalities: optical microscopy, laser profilometry, X-ray diffraction, X-ray fluorescence, nanoindentation, and tribological (friction and wear) testing, each with speedup factors ranging from 13–46x. In addition, automated data upload to a repository using FAIR data principles was accelerated by 64x.

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Results 1–25 of 68
Results 1–25 of 68
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