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26 results on '"Nizinski, Cody A."'

1. Model editing for distribution shifts in uranium oxide morphological analysis

Author

Brown, Davis, Nizinski, Cody, Shapiro, Madelyn, Fallon, Corey, Yin, Tianzhixi, Kvinge, Henry, and Tu, Jonathan H.

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

Deep learning still struggles with certain kinds of scientific data. Notably, pretraining data may not provide coverage of relevant distribution shifts (e.g., shifts induced via the use of different measurement instruments). We consider deep learning models trained to classify the synthesis conditions of uranium ore concentrates (UOCs) and show that model editing is particularly effective for improving generalization to distribution shifts common in this domain. In particular, model editing outperforms finetuning on two curated datasets comprising of micrographs taken of U$_{3}$O$_{8}$ aged in humidity chambers and micrographs acquired with different scanning electron microscopes, respectively., Comment: Presented at CV4MS @ CVPR 2024

Published
2024

2. Edit at your own risk: evaluating the robustness of edited models to distribution shifts

Author

Brown, Davis, Godfrey, Charles, Nizinski, Cody, Tu, Jonathan, and Kvinge, Henry

Subjects
Computer Science - Machine Learning
Abstract

The current trend toward ever-larger models makes standard retraining procedures an ever-more expensive burden. For this reason, there is growing interest in model editing, which enables computationally inexpensive, interpretable, post-hoc model modifications. While many model editing techniques are promising, research on the properties of edited models is largely limited to evaluation of validation accuracy. The robustness of edited models is an important and yet mostly unexplored topic. In this paper, we employ recently developed techniques from the field of deep learning robustness to investigate both how model editing affects the general robustness of a model, as well as the robustness of the specific behavior targeted by the edit. We find that edits tend to reduce general robustness, but that the degree of degradation depends on the editing algorithm and layers chosen. Motivated by these observations we introduce a new model editing algorithm, 1-layer interpolation (1-LI), which uses weight-space interpolation to navigate the trade-off between editing task accuracy and general robustness., Comment: DB and CG contributed equally

Published
2023

3. Investigation of process history and phenomenology of plutonium oxides using vector quantizing variational autoencoder

Author

Hainje, Connor, Nizinski, Cody, Jackson, Shane, Clark, Richard, Heller, Forrest, Schwerdt, Ian, Buck, Edgar, Meier, David, and Hagen, Alexander

Subjects
Condensed Matter - Materials Science
Abstract

Accurate, high throughput, and unbiased analysis of plutonium oxide particles is needed for analysis of the phenomenology associated with process parameters in their synthesis. Compared to qualitative and taxonomic descriptors, quantitative descriptors of particle morphology through scanning electron microscopy (SEM) have shown success in analyzing process parameters of uranium oxides. We utilize a VQ-VAE to quantitatively describe plutonium dioxide (PuO2) particles created in a designed experiment and investigate their phenomenology and prediction of their process parameters. PuO2 was calcined from Pu(III) oxalates that were precipitated under varying synthetic conditions that related to concentrations, temperature, addition and digestion times, precipitant feed, and strike order; the surface morphology of the resulting PuO2 powders were analyzed by SEM. A pipeline was developed to extract and quantify useful image representations for individual particles with the VQ-VAE to perform multiple classification tasks simultaneously. The reduced feature space could predict process parameters with greater than 80% accuracies for some parameters with a single particle. They also showed utility for grouping particles with similar surface morphology characteristics together. Both the clustering and classification results reveal valuable information regarding which chemical process parameters chiefly influence the PuO2 particle morphologies: strike order and oxalic acid feedstock. Doing the same analysis with multiple particles was shown to improve the classification accuracy on each process parameter over the use of a single particle, with statistically significant results generally seen with as few as four particles in a sample., Comment: 23 pages, 13 figures

Published
2022

8. Chemical and spectroscopic characterization of plutonium tetrafluoride.

Author

Kinyon, Jared S., Villa-Aleman, Eliel, Ciprian, Elodia, Hixon, Amy E., Foley, Bryan J., Christian, Jonathan H., Darvin, Jason R., Dick, Don D., Casella, Amanda J., Sweet, Lucas E., Buck, Edgar C., Heller, Forrest D., Nicholas, Aaron D., Nizinski, Cody A., and Clark, Richard A.

Subjects
RAMAN spectroscopy, X-ray diffraction, FLUORESCENCE spectroscopy, SCANNING electron microscopy, THERMOGRAVIMETRY
Abstract

Anhydrous plutonium tetrafluoride is an important intermediate in the production of metallic Pu. This historically important compound is also known to exist in at least two distinct, yet understudied hydrate forms, PuF4·xH2O(s) (0.5 ≤ x ≤ 2) and PuF4·2.5H2O(s). X-ray diffraction (XRD), thermogravimetric analysis (TGA), and scanning electron microscopy (SEM) are the most common tools used to characterize these materials, often in a context for studying structural and morphological changes that arise from aging or calcination. However, fundamental electronic and vibrational spectroscopic information is rather scarce. Here, we measured the visible and shortwave infrared (SWIR) diffuse reflectance, Fourier transform infrared (FTIR), fluorescence and Raman spectra of PuF4(s) and PuF4·xH2O(s) to obtain a better electronic and vibrational fingerprint. Our work provides clear indication of the polymeric structure of anhydrous PuF4, consistent with the Raman spectrum of UF4(s) and its hydrates. This is supplemented with XRD, TGA and SEM analysis. Findings in this study indicate that the spectra are modified by particle size, which in turn is influenced by synthetic technique. [ABSTRACT FROM AUTHOR]

Published
2024
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10. Kinetic evaluation of the uranyl peroxide synthetic route on morphology.

Author

Abbott, Erik C., Gibb, Logan D., Nizinski, Cody A., Allen, Elijah W., O'Connor, Hiram E. E., and McDonald IV, Luther W.

Subjects
PRECIPITATION (Chemistry), X-ray powder diffraction, SCANNING electron microscopy, NUCLEAR fuels, ELECTRON microscopy
Abstract

An important challenge in utilizing particle morphology in nuclear forensic or fuel fabrication applications is understanding why differences in morphologies are observed following varying processing conditions. This is often due to competition and interplay between thermodynamic and kinetic influences. To that end, some of the kinetic influences in the uranyl peroxide precipitation reaction were evaluated and compared to thermodynamic influences studied previously. Metastudtite (UO2O2·2H2O) was synthesized from solutions of uranyl nitrate or chloride, and the reaction time was varied from 100 s to 230 min enabling an evaluation of kinetic and thermodynamic influences. The metastudtite was then calcined to U3O8, and all materials were analyzed by powder X-ray diffraction (p-XRD) and scanning electron microscopy (SEM). Analysis by p-XRD confirmed the sample purity of metastudtite and U3O8. SEM images were analyzed using the Morphological Analysis for Materials (MAMA) software to measure the size and shape of the nanoparticles for a statistical comparison between materials. Metastudtite produced at shorter reaction times exhibited a kinetically controlled shape by forming smaller and rounder particles than metastudtite produced at longer reaction times. Metastudtite produced at the longer reaction times exhibited differences between the uranyl nitrate and uranyl chloride routes with the nitrate exhibiting a more angular and faceted morphology than the chloride. Overall, the control of the supersaturation ratio (S) played a significant role in determining the morphology of the metastudtite. Morphological differences between the U3O8 confirmed the role of nanoparticle agglomeration in forming larger sintered particles. The results help demonstrate the importance of understanding particle formation mechanisms in the long-term development of morphology in nuclear forensics or in developing advanced fuels with specific characteristics. [ABSTRACT FROM AUTHOR]

Published
2024
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15. Review of Multi-Faceted Morphologic Signatures of Actinide Process Materials for Nuclear Forensic Science

Author

McDonald, Luther W., primary, Sentz, Kari, additional, Hagen, Alex, additional, Chung, Brandon W., additional, Nizinski, Cody A., additional, Schwerdt, Ian J., additional, Hanson, Alexa, additional, Donald, Scott, additional, Clark, Richard, additional, Sjoden, Glenn, additional, Porter, Reid, additional, Athon, Matthew T., additional, Tasdizen, Tolga, additional, Noel, Vincent, additional, Webb, Samuel M., additional, Van Veelen, Arjen, additional, Hickam, Sarah M., additional, and Ly, Cuong, additional

Published
2023
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18. Investigation of Process History and Phenomenology of Plutonium Oxides Using Vector Quantizing Variational Autoencoder

Author

Hainje, Connor, Nizinski, Cody, Jackson, Shane, Clark, Richard, Heller, Forrest, Schwerdt, Ian, Buck, Edgar, Meier, David, and Hagen, Alexander

Subjects
Condensed Matter - Materials Science, Materials Science (cond-mat.mtrl-sci), FOS: Physical sciences
Abstract

Accurate, high throughput, and unbiased analysis of plutonium oxide particles is needed for analysis of the phenomenology associated with process parameters in their synthesis. Compared to qualitative and taxonomic descriptors, quantitative descriptors of particle morphology through scanning electron microscopy (SEM) have shown success in analyzing process parameters of uranium oxides. We utilize a VQ-VAE to quantitatively describe plutonium dioxide (PuO2) particles created in a designed experiment and investigate their phenomenology and prediction of their process parameters. PuO2 was calcined from Pu(III) oxalates that were precipitated under varying synthetic conditions that related to concentrations, temperature, addition and digestion times, precipitant feed, and strike order; the surface morphology of the resulting PuO2 powders were analyzed by SEM. A pipeline was developed to extract and quantify useful image representations for individual particles with the VQ-VAE to perform multiple classification tasks simultaneously. The reduced feature space could predict process parameters with greater than 80% accuracies for some parameters with a single particle. They also showed utility for grouping particles with similar surface morphology characteristics together. Both the clustering and classification results reveal valuable information regarding which chemical process parameters chiefly influence the PuO2 particle morphologies: strike order and oxalic acid feedstock. Doing the same analysis with multiple particles was shown to improve the classification accuracy on each process parameter over the use of a single particle, with statistically significant results generally seen with as few as four particles in a sample., 23 pages, 13 figures

Published
2023
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23. Impact of Controlled Storage Conditions on the Hydrolysis and Surface Morphology of Amorphous-UO3

Author

Hanson, Alexa B., primary, Schwerdt, Ian J., additional, Nizinski, Cody A., additional, Lee, Rachel Nicholls, additional, Mecham, Nicholas J., additional, Abbott, Erik C., additional, Heffernan, Sean, additional, Olsen, Adam, additional, Klosterman, Michael R., additional, Martinson, Sean, additional, Brenkmann, Alexandria, additional, and McDonald, Luther W., additional

Published
2021
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