Interatomic pair potentials from DFT and molecular dynamics for Ca, Ba, and Sr hexaborides

Schmidt, Kevin M.; Buettner, Alex B.; Graeve, Olivia A.; Vásquez, Victor R.

doi:10.1039/c5tc01398d

Cited by 17 publications

(12 citation statements)

References 62 publications

(98 reference statements)

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“…5 In addition to the stability of these materials, many electronic properties can be affected by the particular choice of metal. [6][7][8][9] Resulting properties can generally be inferred from the valence and polarization of the host cation along with the required electron donation-hexaborides having di-valent metals tend to produce semiconductors, while inclusion of a tri-valent metal allows for metallic conductivity. Electronic properties near the surface are also affected by the type of metal; however, additional degrees of freedom such as the atomic configuration will also affect observed properties, e.g., catalysis, adsorption, and emission.…”

Section: Introductionmentioning

confidence: 99%

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Schmidt

Misture

Graeve

et al. 2018

Adv Elect Materials

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Section: Introductionmentioning

confidence: 99%

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Schmidt

Misture

Graeve

et al. 2018

Adv Elect Materials

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“…Strain effects have also been explored as parameters for morphological modification of copper and nickel particles, and doping has been applied for obtaining nanorods of magnesium . In addition, modeling − and experimental techniques − have been applied for exploring the behavior of borides of cubic and other morphologies. Moreover, experimental efforts have investigated shape change in cubic carbides as a function of carbon stoichiometry, which influences the relative growth rate of the dominant {111} and {100} facets. − …”

Section: Introductionmentioning

confidence: 99%

Morphology Control of Tantalum Carbide Nanoparticles through Dopant Additions

et al. 2021

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The control of powder morphology in metals and ceramics is of critical importance in applications such as catalysis and chemical sensing whereby specific crystal facets better facilitate chemical reactions. In response to this challenge, we present a combined experimental and computational approach that examines the principles behind dopant-induced crystallographic faceting in nanoparticles. We base our study on nanoparticles of tantalum carbide doped with nickel, iron, cobalt, niobium, and titanium and observe a very significant transition from round/irregular particle shapes to cubes and cuboctahedrons upon the addition of transition metal dopants. The presence of the dopants, which segregate toward the surface of the particles, results in atomic orbital hybridization, causing a significant decrease of up to 0.13 eV•Å −2 in the surface energy of the (100) facets, thus providing the driving force for the formation of nanocubes with exposed (100) surfaces. These principles can be generalized to other ceramics and serve as guidance for the optimized control of shape in powders. For example, if one seeks to produce highly faceted V-, Hf-, or Zr-carbide nanoparticles, doping strategies reported here can be applied. Other elements may also be effective in changing the growth habits of crystals based on surface segregation and dopant−host atomic orbital hybridization.

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“…Experimental and theoretical studies investigating adsorption on MB 6 surfaces have mainly focused on determining the poisoning effects on the emitter planes caused by common environmental gases such as CO, O 2 , and H 2 O. − Although hydrogen is considered a background gas in ultrahigh vacuum conditions, only a handful of studies consider the interaction of hydrogen with MB 6 surfaces and theoretical investigations are absent from the literature to the best of our knowledge. Most experimental, modeling, and theoretical efforts are focused on electronic behavior and thermophysical properties for bulk MB 6 materials. − …”

Section: Introductionmentioning

confidence: 99%

Interaction of Hydrogen with MB₆ (M = Ba, Ca, La, and Sr) Surfaces from First Principles

et al. 2019

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We show results of basic energetics and interacting behavior of hydrogen with metal hexaboride surfaces using a combination of self-consistent density functional calculations and dynamics based on the Car–Parrinello method. Our results show that hydrogen is strongly attracted to localized exposed boron atoms and interactions with the terminal cations are strictly repulsive. From these, preliminary local adsorption energy calculations suggest that a single hydrogen molecule per surface unit-cell is possible (one ML). Strongest bonds are found when hydrogen is above the terminal boron atoms affected by reduced coordination and dangling bonds. This location serves to restore the hexaboride unit to a more stable structure by providing electronic density to the deficient surface octahedra. Additionally, trajectories from dynamic simulations provide insight into how hydrogen recombination reactions occur on the surface through dissociative adsorption and the method of travel prior to recombination to be along the octahedral face and bridging sites connecting separate unit cells on the surface. Upon adsorption, a single hydrogen atom becomes localized at the dangling bond site while the second interacts with the surface along a weaker potential energy path. Desorption at lower temperatures occurs when migrating atoms from separate adsorption sites intersect to form a new pair.

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Interatomic pair potentials from DFT and molecular dynamics for Ca, Ba, and Sr hexaborides

Cited by 17 publications

References 62 publications

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Morphology Control of Tantalum Carbide Nanoparticles through Dopant Additions

Interaction of Hydrogen with MB₆ (M = Ba, Ca, La, and Sr) Surfaces from First Principles

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Interatomic pair potentials from DFT and molecular dynamics for Ca, Ba, and Sr hexaborides

Cited by 17 publications

References 62 publications

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Metal Hexaboride Work Functions: Surface Configurations and the Electrical Double Layer from First‐Principles

Morphology Control of Tantalum Carbide Nanoparticles through Dopant Additions

Interaction of Hydrogen with MB6 (M = Ba, Ca, La, and Sr) Surfaces from First Principles

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Interaction of Hydrogen with MB₆ (M = Ba, Ca, La, and Sr) Surfaces from First Principles