The peak energies of the fits of individual measured V Kβ spectra by C T Chantler (557430)

“…The peak energy of the titanium Kβ spectral profile is found to be 4931.966 ± 0.022 eV prior to instrumental broadening. This 4.5 ppm result decreases the uncertainty over the past literature by a factor of 2.6 and is 2.4 standard deviations from the previous standard. …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

From 2D to 1D Electronic Dimensionality in Halide Perovskites with Stepped and Flat Layers Using Propylammonium as a Spacer by Justin M. Hoffman (6890504)

“…The RP structures show a blue-shift in bandgap for decreasing <i>n</i> (1.90 eV for <i>n</i> = 4 and 2.03 eV for <i>n</i> = 3), while the SL structures have an even greater blue-shift (2.53 eV for <i>m</i> = 4, 2.74 eV for <i>m</i> = 3, and 2.93 eV for <i>m</i> = 2). …”

Downregulation of LGR4 decreases ARPE-19 cell migration. by Qiang Hou (495704)

Pretreatment with SDG prevents iron induced decrease in H9c2 cell size. by Stephanie Puukila (568109)

Inhibition of Rab5 Activity Decreases Fluid-Phase Uptake by Carsten Schnatwinkel (48)

Weight related parameters of subjects carrying (heterozygote) <i>NR5A1</i> mutations. by Jana Malikova (615672)

Subjects:

Promoter reporter studies for reported <i>NR5A1</i> mutations by Jana Malikova (615672)

Subjects:

Promoter reporter studies for SF-1 regulating the human <i>BDNF</i> promoter I and comparative studies of specific <i>NR5A1</i> mutations on <i>BDNF</i> promoter activity. by Jana Malikova (615672)

Subjects:

mGluR5 receptor decreased glycinergic currents. by Zi-Yang Zhang (4988555)

“…<p>(<b>A–B</b>) Bath perfusion of DHPG for 3 min reduced GlyR-IPSCs (<b>A</b>; 70.2 ± 4.2% of baseline at 15–20 min post-DHPG, <i>t</i>[16] = 6.707, <i>p</i> < 0.001, paired Student <i>t</i> test), but not GABA_A-receptor–mediated IPSCs (<b>B</b>; 102.9 ± 3.3% of baseline at 15–20 min post-DHPG, <i>t</i>[5] = 0.347, <i>p</i> = 0.743) in spinal slices of mice. …”

AQP5 expression is decreased in lung of mice exposed to hypoxia. by Jitesh D. Kawedia (384551)

Decreased expression of V-ATPase upon the siRNA transfection. by Manisha Naskar (2613763)

Decreased expression of ATG5 upon the siRNA transfection. by Manisha Naskar (2613763)