5,453 research outputs found
Transitions to Nematic states in homogeneous suspensions of high aspect ratio magnetic rods
Isotropic-Nematic and Nematic-Nematic transitions from a homogeneous base
state of a suspension of high aspect ratio, rod-like magnetic particles are
studied for both Maier-Saupe and the Onsager excluded volume potentials. A
combination of classical linear stability and asymptotic analyses provides
insight into possible nematic states emanating from both the isotropic and
nematic non-polarized equilibrium states. Local analytical results close to
critical points in conjunction with global numerical results (Bhandar, 2002)
yields a unified picture of the bifurcation diagram and provides a convenient
base state to study effects of external orienting fields.Comment: 3 Figure
Percolation-induced exponential scaling in the large current tails of random resistor networks
There is a renewed surge in percolation-induced transport properties of
diverse nano-particle composites (cf. RSC Nanoscience & Nanotechnology Series,
Paul O'Brien Editor-in-Chief). We note in particular a broad interest in
nano-composites exhibiting sharp electrical property gains at and above
percolation threshold, which motivated us to revisit the classical setting of
percolation in random resistor networks but from a multiscale perspective. For
each realization of random resistor networks above threshold, we use network
graph representations and associated algorithms to identify and restrict to the
percolating component, thereby preconditioning the network both in size and
accuracy by filtering {\it a priori} zero current-carrying bonds. We then
simulate many realizations per bond density and analyze scaling behavior of the
complete current distribution supported on the percolating component. We first
confirm the celebrated power-law distribution of small currents at the
percolation threshold, and second we confirm results on scaling of the maximum
current in the network that is associated with the backbone of the percolating
cluster. These properties are then placed in context with global features of
the current distribution, and in particular the dominant role of the large
current tail that is most relevant for material science applications. We
identify a robust, exponential large current tail that: 1. persists above
threshold; 2. expands broadly over and dominates the current distribution at
the expense of the vanishing power law scaling in the small current tail; and
3. by taking second moments, reproduces the experimentally observed power law
scaling of bulk conductivity above threshold
Proteogenomic characterization of human colon and rectal cancer
Extensive genomic characterization of human cancers presents the problem of inference from genomic abnormalities to cancer phenotypes. To address this problem, we analysed proteomes of colon and rectal tumours characterized previously by The Cancer Genome Atlas (TCGA) and perform integrated proteogenomic analyses. Somatic variants displayed reduced protein abundance compared to germline variants. Messenger RNA transcript abundance did not reliably predict protein abundance differences between tumours. Proteomics identified five proteomic subtypes in the TCGA cohort, two of which overlapped with the TCGA ‘microsatellite instability/CpG island methylation phenotype’ transcriptomic subtype, but had distinct mutation, methylation and protein expression patterns associated with different clinical outcomes. Although copy number alterations showed strong cis- and trans-effects on mRNA abundance, relatively few of these extend to the protein level. Thus, proteomics data enabled prioritization of candidate driver genes. The chromosome 20q amplicon was associated with the largest global changes at both mRNA and protein levels; proteomics data highlighted potential 20q candidates, including HNF4A (hepatocyte nuclear factor 4, alpha), TOMM34 (translocase of outer mitochondrial membrane 34) and SRC (SRC proto-oncogene, non-receptor tyrosine kinase). Integrated proteogenomic analysis provides functional context to interpret genomic abnormalities and affords a new paradigm for understanding cancer biology.National Cancer Institute (U.S.). Clinical Proteomic Tumor Analysis Consortium (Award U24CA159988)National Cancer Institute (U.S.). Clinical Proteomic Tumor Analysis Consortium (Award U24CA160035)National Cancer Institute (U.S.). Clinical Proteomic Tumor Analysis Consortium (Award U24CA160034)National Cancer Institute (U.S.). Specialized Program of Research Excellence (Award P50CA095103)National Cancer Institute (U.S.) (Cancer Center Support Grant P30CA068485)National Institutes of Health (U.S.) (Grant GM088822)Leidos Biomedical Research, Inc. (Contract 13XS029
Alien Registration- Forest, Armeline M. (Portland, Cumberland County)
https://digitalmaine.com/alien_docs/23853/thumbnail.jp
Alien Registration- Forest, Armeline M. (Portland, Cumberland County)
https://digitalmaine.com/alien_docs/23853/thumbnail.jp
Alien Registration- Forest, Armeline M. (Portland, Cumberland County)
https://digitalmaine.com/alien_docs/23853/thumbnail.jp
Measurements of the magnetic field induced by a turbulent flow of liquid metal
Initial results from the Madison Dynamo Experiment provide details of the
inductive response of a turbulent flow of liquid sodium to an applied magnetic
field. The magnetic field structure is reconstructed from both internal and
external measurements. A mean toroidal magnetic field is induced by the flow
when an axial field is applied, thereby demonstrating the omega effect.
Poloidal magnetic flux is expelled from the fluid by the poloidal flow.
Small-scale magnetic field structures are generated by turbulence in the flow.
The resulting magnetic power spectrum exhibits a power-law scaling consistent
with the equipartition of the magnetic field with a turbulent velocity field.
The magnetic power spectrum has an apparent knee at the resistive dissipation
scale. Large-scale eddies in the flow cause significant changes to the
instantaneous flow profile resulting in intermittent bursts of non-axisymmetric
magnetic fields, demonstrating that the transition to a dynamo is not smooth
for a turbulent flow.Comment: 9 pages, 11 figures, invited talk by C. B. Forest at 2005 APS DPP
meeting, resubmitted to Physics of Plasma
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