Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

Molecular Structures, Dipole Moments, and Electronic Properties of β‑HMX under External Electric Field from First-Principles Calculations by Yu-Shi Liu (6647582)

“…When the external electric field is increasing along the [100], [010], and [001] crystallographic directions of β-HMX, the calculation results indicate that an increase in the bond length (N1–N3/N1′–N3′) of the triggering bond, an increase in the main <i>Q</i>_nitro (N3, N3′) value, an increase in the minimum surface electrostatic potential, and a decrease in band gap all contribute to a reduction in its stability. …”

<i>Ezh2^fl/fl:Nkx2.5-cre+</i> mice exhibited hypoplastic endocardial cushions. by Li Chen (5749)

“…<p>(<b>A–B′</b>) H&E staining revealed a decrease in the cell population in the EC region of <i>Ezh2</i> null hearts compared with that of control (arrows) at E10.5. …”

<i>Camellia sinensis</i> L. alleviates OVA-induced allergic asthma through NF-κB and MMP-9 pathways by So-Won Pak (13235457)

“…Treatment with CSE remarkably decreased the airway hyperresponsiveness, OVA-specific immunoglobulin E level, and inflammatory cell and cytokine levels of mice, with a decrease in inflammatory cell infiltration and mucus production in lung tissue. …”

The effects of sulphur poisoning on the microstructure, composition and oxygen transport properties of perovskite membranes coated with nanoscale alumina layers by Ian Metcalfe (9575525)

“…Here we aim to delay or prevent this process by coating La_0.6Sr_0.4Co_0.2Fe_0.8O_3-_d membranes with <a>Alumina (Al₂O₃) </a>layers of 1 to 100 nm thickness by using atomic layer deposition. …”

FOXL2 recruitment to PML Bodies enhances its transactivation ability. by Adrien Georges (201474)

“…SP100-HSV was expressed alone (lane 1) or co-expressed with V5-tagged FOXL2-WT (lane 2) or KFULL (lane 3). …”

Competitive Regulation of E-Cadherin JuxtaMembrane Domain Degradation by p120-Catenin Binding and Hakai-Mediated Ubiquitination by Andrea Hartsock (160855)

“…We found WT-JMD was ubiquitinated, and arginine substitution of lysines at position 5 (K5R) and 83 (K83R) resulted in the stable accumulation of mutant JMD at mitochondria. p120-Catenin did not localize, or bind to WT-JMD even upon proteasome inhibition, whereas the K5,83R-JMD mutant bound and localized p120-catenin to mitochondria. …”

Hv1 increases colorectal cell migration and invasion. by Yifan Wang (380120)

“…<p>A, B and C, migration kinetics of SW620 (A), SW480 (B) and HT29 (C) assayed by wounded monolayer model. nc, cells transfected with the negative control (a, b, c, d and e in left panels); si, cells transfected with siRNA (f, g, h, i and j in left panels); and Zn²⁺, cells cultured at a final concentration of 100 µM ZnCl₂ (k, l, m, n and o in left panels). …”