Controlling the Temperature and Speed of the Phase Transition of VO₂ Microcrystals by Joonseok Yoon (1419355)

“…The phase transition speed increases from 4.6 × 10² to 1.7 × 10⁴ μm/s as the width decreases from ∼50 to ∼2 μm. While the statistical description for a heterogeneous nucleation process explains the size dependence on phase transition temperature of VO₂, the increase of effective thermal exchange process is responsible for the enhancement of phase transition speed of small VO₂ microcrystals. …”

Sporulation is decreased in a Δ<i>mas</i> mutant. by Sarah Fremgen (102742)

Microfluidic Device for Automated Synchronization of Bacterial Cells by Seth M. Madren (2033833)

Microfluidic Device for Automated Synchronization of Bacterial Cells by Seth M. Madren (2033833)

Ketamine decreases NSC viability in a dose-dependent manner. by Shiva Mansouri (2838086)

Multivariable analyses for hospital outcomes by logistic regression models among patients with normal LVEF (EF ≥ 50%) ^a. by Kyu Jin Lee (18143946)

Subnetwork of core DE genes with ≥5.0 degree and a fold change of ≥2.0 (50 nodes and 97 edges). by Reena Arora (1464781)

HPD 1466 decreases empty capsid accumulation in cells replicating HBV. by Daniel P. Bradley (10306893)

Phenethyl isothiocyanate activates leptin signaling and decreases food intake by Miho Yagi (5921252)

“…Moreover, we found that PEITC causes the ligand-independent phosphorylation of Ob-Rb, JAK2, and STAT3 by inhibiting cellular PTP1B in differentiated human SH-SY5Y neuronal cells. …”

Effects of spatial management strategies (<i>s</i>) on the relative decrease in maximum metapopulation abundance in model networks when an obligate resource (K) is reduced in 50% o... by Miguel Lurgi (3144567)

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”

Recombination of Autodissociated Water Ions in a Nanoscale Pure Water Droplet by Soonho Kwon (1402972)

“…Using a classical RexPoN force-field, we found that the ions in 1000 H₂O’s spend almost 50% of the time on the surface and 0.5 nm beneath it with a slight preference for OH^– ion to reside longer on the surface. …”