Sean Heffernan scite author profile

SUMMARYIn this paper we discuss three scientific computing problem solving environments: SCIRun, BioPSE, and Uintah. We begin with an overview of the systems, describe their underlying software architectures, discuss implementation issues, and give examples of their use in computational science and engineering applications. We conclude by discussing future research and development plans for the three problem solving environments.

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Quantifying Morphological Features of α-U₃O₈ with Image Analysis for Nuclear Forensics

Olsen

Richards

Schwerdt

et al. 2017

Anal. Chem.

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Morphological changes in UO based on calcination temperature have been quantified enabling a morphological feature to serve as a signature of processing history in nuclear forensics. Five separate calcination temperatures were used to synthesize α-UO, and each sample was characterized using powder X-ray diffraction (p-XRD) and scanning electron microscopy (SEM). The p-XRD spectra were used to evaluate the purity of the synthesized U-oxide; the morphological analysis for materials (MAMA) software was utilized to quantitatively characterize the particle shape and size as indicated by the SEM images. Analysis comparing the particle attributes, such as particle area at each of the temperatures, was completed using the Kolmogorov-Smirnov two sample test (K-S test). These results illustrate a distinct statistical difference between each calcination temperature. To provide a framework for forensic analysis of an unknown sample, the sample distributions at each temperature were compared to randomly selected distributions (100, 250, 500, and 750 particles) from each synthesized temperature to determine if they were statistically different. It was found that 750 particles were required to differentiate between all of the synthesized temperatures with a confidence interval of 99.0%. Results from this study provide the first quantitative morphological study of U-oxides, and reveals the potential strength of morphological particle analysis in nuclear forensics by providing a framework for a more rapid characterization of interdicted uranium oxide samples.

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Nuclear forensics investigation of morphological signatures in the thermal decomposition of uranyl peroxide

Schwerdt

Olsen

Lusk

et al. 2018

Talanta

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The analytical techniques typically utilized in a nuclear forensic investigation often provide limited information regarding the process history and production conditions of interdicted nuclear material. In this study, scanning electron microscopy (SEM) analysis of the surface morphology of amorphous-UO samples calcined at 250, 300, 350, 400, and 450°C from uranyl peroxide was performed to determine if the morphology was indicative of the synthesis route and thermal history for the samples. Thermogravimetic analysis-mass spectrometry (TGA-MS) and differential scanning calorimetry (DSC) were used to correlate transitions in the calcined material to morphological transformations. The high-resolution SEM images were processed using the Morphological Analysis for Material Attribution (MAMA) software. Morphological attributes, particle area and circularity, indicated significant trends as a result of calcination temperature. The quantitative morphological analysis was able to track the process of particle fragmentation and subsequent sintering as calcination temperature was increased. At the 90% confidence interval, with 1000 segmented particles, the use of Kolmogorov-Smirnov statistical comparisons allowed discernment between all calcination temperatures for the uranyl peroxide route.

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JAM-A is both essential and inhibitory to development of hepatic polarity in WIF-B cells

Braiterman¹,

Heffernan²,

Nyasae³

et al. 2008

American Journal of Physiology-Gastrointestinal and Liver Physi

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Junctional adhesion molecule (JAM) is involved in tight junction (TJ) formation in epithelial cells. Three JAMs (A, B, and C) are expressed in rat hepatocytes, but only rat JAM-A is present in polarized WIF-B cells, a rat-human hepatic line. We used knockdown (KD) and overexpression in WIF-B cells to determine the role of JAM-A in the development of hepatic polarity. Expression of rat JAM-A short hairpin RNA resulted in ϳ50% KD of JAM-A and substantial loss of hepatic polarity, as measured by the absence of apical cysts formed by adjacent cells and sealed by TJ belts. When inhibitory RNA-resistant human JAM-A (huWT) was expressed in KD cells, hepatic polarity was restored. In contrast, expression of JAM-A that either lacked its PDZ-binding motif (hu⌬C-term) or harbored a point mutation (T273A) did not complement, indicating that multiple sites within JAM-A's cytoplasmic tail are required for the development of hepatic polarity. Overexpression of huWT in normal WIF-B cells unexpectedly blocked WIF-B maturation to the hepatic phenotype, as did expression of three huJAM-A constructs with single point mutations in putative phosphorylation sites. In contrast, hu⌬C-term was without effect, and the T273A mutant only partially blocked maturation. Our results show that JAM-A is essential for the development of polarity in cultured hepatic cells via its possible phosphorylation and recruitment of relevant PDZ proteins and that hepatic polarity is achieved within a narrow range of JAM-A expression levels. Importantly, formation/ maintenance of TJs and the apical domain in hepatic cells are linked, unlike simple epithelia.partitioning-defective polarity protein/atypical protein kinase C complex

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Nuclear proliferomics: A new field of study to identify signatures of nuclear materials as demonstrated on alpha-UO3

Schwerdt

Brenkmann

Martinson

et al. 2018

Talanta

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Sean Heffernan

Component‐based, problem‐solving environments for large‐scale scientific computing

Quantifying Morphological Features of α-U₃O₈ with Image Analysis for Nuclear Forensics

Nuclear forensics investigation of morphological signatures in the thermal decomposition of uranyl peroxide

JAM-A is both essential and inhibitory to development of hepatic polarity in WIF-B cells

Nuclear proliferomics: A new field of study to identify signatures of nuclear materials as demonstrated on alpha-UO3

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Sean Heffernan

Component‐based, problem‐solving environments for large‐scale scientific computing

Quantifying Morphological Features of α-U3O8 with Image Analysis for Nuclear Forensics

Nuclear forensics investigation of morphological signatures in the thermal decomposition of uranyl peroxide

JAM-A is both essential and inhibitory to development of hepatic polarity in WIF-B cells

Nuclear proliferomics: A new field of study to identify signatures of nuclear materials as demonstrated on alpha-UO3

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Quantifying Morphological Features of α-U₃O₈ with Image Analysis for Nuclear Forensics