Main test parameters. by Decang Lou (21439960)

“…The results reveal that the large deviation in the manufactured vane (up to 0.5 mm at the leading edge) alters the direction of the coolant flowing out from the leading-edge film-cooling holes, affects the film coverage along the surface, and in consequence, causes the temperature near the stagnation point increasing by approximately 40 K. …”

3-D printed NGV specimen. by Decang Lou (21439960)

“…The results reveal that the large deviation in the manufactured vane (up to 0.5 mm at the leading edge) alters the direction of the coolant flowing out from the leading-edge film-cooling holes, affects the film coverage along the surface, and in consequence, causes the temperature near the stagnation point increasing by approximately 40 K. …”

Relative error bar of surface temperature. by Decang Lou (21439960)

“…The results reveal that the large deviation in the manufactured vane (up to 0.5 mm at the leading edge) alters the direction of the coolant flowing out from the leading-edge film-cooling holes, affects the film coverage along the surface, and in consequence, causes the temperature near the stagnation point increasing by approximately 40 K. …”

Effect on the NGV leading edge temperature. by Decang Lou (21439960)

“…The results reveal that the large deviation in the manufactured vane (up to 0.5 mm at the leading edge) alters the direction of the coolant flowing out from the leading-edge film-cooling holes, affects the film coverage along the surface, and in consequence, causes the temperature near the stagnation point increasing by approximately 40 K. …”

Schematic of the test equipment. by Decang Lou (21439960)

“…The results reveal that the large deviation in the manufactured vane (up to 0.5 mm at the leading edge) alters the direction of the coolant flowing out from the leading-edge film-cooling holes, affects the film coverage along the surface, and in consequence, causes the temperature near the stagnation point increasing by approximately 40 K. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

Dissipative Self-Assembly of Patchy Particles under Nonequilibrium Drive: A Computational Study by Shubhadeep Nag (18888287)

“…We also validated our key findings by simulating a larger system of 100 patchy particles. …”

TIP60 inhibition reduces stress granule formation in mammalian cells. by Meaghen Rollins (3776008)

“…<p><b>A</b>) Decreased acetylation level of histone H4 was detected by Western Blot analysis upon treatment with NU9056. …”

γHV68-IκBαM–Infected Mice Have Decreased Splenic Latency at Later Timepoints after Intranasal Infection that Is Not Altered by Inhibiting Lytic Replication by Laurie T Krug (68237)

Scaling exponents <i>α</i> and <i>β</i> for 100,000 stride walking with <i>θ</i>₀ = <i>π</i>/12. by Jooeun Ahn (299192)

“…In B, the exponents are evaluated with window sizes larger than 1,000 strides (1,000≤<i>n</i>≤100,000/2, and 2/100,000≤<i>f</i>≤0.01); the exponents are not significantly different from those of white noise. …”