Response kinetics and relationship to Weber’s law in the m8 controller (Fig 10). by Jonas V. Grini (15374504)

“…<p>The set-point of <i>A</i> is <i>A</i>_<i>set</i>=3.0. (a) Step-wise increase of <i>k</i>₁ from 1.0 to 5.0 at time <i>t</i>=100 at different and constant background perturbations <i>k</i>₃ (0–80). …”

In Situ Mechanochemical Modulation of Carbon Nanotube Forest Growth by Nicholas T. Dee (6172670)

“…By correlating in situ kinetics measurements with spatial mapping of CNT orientation and density by X-ray scattering, we find that the average growth rate of individual CNTs is also mechanically modulated; specifically, a 100-fold increase in force causes a 4-fold decrease in average CNT lengthening rate. …”

In Situ Mechanochemical Modulation of Carbon Nanotube Forest Growth by Nicholas T. Dee (6172670)

“…By correlating in situ kinetics measurements with spatial mapping of CNT orientation and density by X-ray scattering, we find that the average growth rate of individual CNTs is also mechanically modulated; specifically, a 100-fold increase in force causes a 4-fold decrease in average CNT lengthening rate. …”

In Situ Mechanochemical Modulation of Carbon Nanotube Forest Growth by Nicholas T. Dee (6172670)

“…By correlating in situ kinetics measurements with spatial mapping of CNT orientation and density by X-ray scattering, we find that the average growth rate of individual CNTs is also mechanically modulated; specifically, a 100-fold increase in force causes a 4-fold decrease in average CNT lengthening rate. …”

In Situ Mechanochemical Modulation of Carbon Nanotube Forest Growth by Nicholas T. Dee (6172670)

“…By correlating in situ kinetics measurements with spatial mapping of CNT orientation and density by X-ray scattering, we find that the average growth rate of individual CNTs is also mechanically modulated; specifically, a 100-fold increase in force causes a 4-fold decrease in average CNT lengthening rate. …”

In Situ Mechanochemical Modulation of Carbon Nanotube Forest Growth by Nicholas T. Dee (6172670)

“…By correlating in situ kinetics measurements with spatial mapping of CNT orientation and density by X-ray scattering, we find that the average growth rate of individual CNTs is also mechanically modulated; specifically, a 100-fold increase in force causes a 4-fold decrease in average CNT lengthening rate. …”

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. …”