Byungryul Jang scite author profile

Using the first-principles calculations, we explored the feasibility of using graphdiyne, a 2D layer of sp and sp2 hybrid carbon networks, as lithium ion battery anodes. We found that the composite of the Li-intercalated multilayer α-graphdiyne was C6Li7.31 and that the calculated voltage was suitable for the anode. The practical specific/volumetric capacities can reach up to 2719 mAh g−1/2032 mAh cm−3, much greater than the values of ∼372 mAh g−1/∼818 mAh cm−3, ∼1117 mAh g−1/∼1589 mAh cm−3, and ∼744 mAh g−1 for graphite, graphynes, and γ-graphdiyne, respectively. Our calculations suggest that multilayer α-graphdiyne can serve as a promising high-capacity lithium ion battery anode.

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Widely tunable band gaps of graphdiyne: an ab initio study

Koo

Park

Hwang

et al. 2014

Phys. Chem. Chem. Phys.

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Functionalization of graphdiyne, a two-dimensional atomic layer of sp-sp(2) hybrid carbon networks, was investigated through first-principles calculations. Hydrogen or halogen atoms preferentially adsorb on sp-bonded carbon atoms rather than on sp(2)-bonded carbon atoms, forming sp(2)- or sp(3)-hybridization. The energy band gap of graphdiyne is increased from ~0.5 eV to ~5.2 eV through the hydrogenation or halogenation. Unlike graphene, segregation of adsorbing atoms is energetically unfavourable. Our results show that hydrogenation or halogenation can be utilized for modifying the electronic properties of graphdiyne for applications to nano-electronics and -photonics.

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High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide

Bae

Park

Jang

et al. 2016

Sci Rep

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Nanostructured materials, such as zeolites and metal-organic frameworks, have been considered to capture CO2. However, their application has been limited largely because they exhibit poor selectivity for flue gases and low capture capacity under low pressures. We perform a high-throughput screening for selective CO2 capture from flue gases by using first principles thermodynamics. We find that elements with empty d orbitals selectively attract CO2 from gaseous mixtures under low CO2 pressures (~10−3 bar) at 300 K and release it at ~450 K. CO2 binding to elements involves hybridization of the metal d orbitals with the CO2 π orbitals and CO2-transition metal complexes were observed in experiments. This result allows us to perform high-throughput screening to discover novel promising CO2 capture materials with empty d orbitals (e.g., Sc– or V–porphyrin-like graphene) and predict their capture performance under various conditions. Moreover, these findings provide physical insights into selective CO2 capture and open a new path to explore CO2 capture materials.

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High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide

Bae

Park

Jang

et al. 2016

Preprint

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Byungryul Jang

Graphdiyne as a high-capacity lithium ion battery anode material

Widely tunable band gaps of graphdiyne: an ab initio study

High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide

High-throughput screening of metal-porphyrin-like graphenes for selective capture of carbon dioxide

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