Lithium and sodium ion binding in nanostructured carbon composites

“…[78] A Lennard-Jones potential yielded an atomic interaction of Na and C as opposed to the more representative ionic interaction of Na + and C x − , which could be approximated using reactive potentials. [27][28][29][30] However, in light of other modeling of Na binding mechanisms in HC, its use was a straightforward approach which enabled the authors' detailed structural analysis in a dilute Na-C x model. [29] Although random, the initial position of the Na probe atom was restricted to being further than 1.0 Å from every carbon atom and <1.8 Å from the nearest carbon atom.…”

“…However, the same analysis shows it does not impact the Na binding mechanism. [27][28][29][30] The interaction between a model which has been appropriately decorated with heteroatoms and would afford an opportunity to study electrochemistry in HCs further and should be pursued.…”

“…procedures to understand electrochemical processes such as capacitance [24][25][26] and Li-ion binding, [27][28][29][30] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na-ion binding. [29,30] In this study, we synthesized dense, low porosity HC materials derived from sucrose in line with our previous work.…”

“…procedures to understand electrochemical processes such as capacitance [24][25][26] and Li-ion binding, [27][28][29][30] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na-ion binding. [29,30] In this study, we synthesized dense, low porosity HC materials derived from sucrose in line with our previous work. [31][32][33] These materials were characterized using X-ray diffraction (XRD), Raman, nitrogen sorption analysis, neutron total scattering and pair distribution function (PDF) analysis, various methods of density analysis, and galvanostatic charge/discharge (GCD) allowing for a differential look at how the structural, physical, and electrochemical properties evolve with increasing pyrolysis temperature.…”

“…[ 15–18 ] However, previous studies have heavily focused on modeling porosity and its impact on sorption properties due to HCs utility as a filter. [ 17–23 ] More recent studies use similar modeling procedures to understand electrochemical processes such as capacitance [ 24–26 ] and Li‐ion binding, [ 27–30 ] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na‐ion binding. [ 29,30 ]…”

Combining Experimental and Theoretical Techniques to Gain an Atomic Level Understanding of the Defect Binding Mechanism in Hard Carbon Anodes for Sodium Ion Batteries

“…[78] A Lennard-Jones potential yielded an atomic interaction of Na and C as opposed to the more representative ionic interaction of Na + and C x − , which could be approximated using reactive potentials. [27][28][29][30] However, in light of other modeling of Na binding mechanisms in HC, its use was a straightforward approach which enabled the authors' detailed structural analysis in a dilute Na-C x model. [29] Although random, the initial position of the Na probe atom was restricted to being further than 1.0 Å from every carbon atom and <1.8 Å from the nearest carbon atom.…”

“…However, the same analysis shows it does not impact the Na binding mechanism. [27][28][29][30] The interaction between a model which has been appropriately decorated with heteroatoms and would afford an opportunity to study electrochemistry in HCs further and should be pursued.…”

“…procedures to understand electrochemical processes such as capacitance [24][25][26] and Li-ion binding, [27][28][29][30] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na-ion binding. [29,30] In this study, we synthesized dense, low porosity HC materials derived from sucrose in line with our previous work.…”

“…procedures to understand electrochemical processes such as capacitance [24][25][26] and Li-ion binding, [27][28][29][30] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na-ion binding. [29,30] In this study, we synthesized dense, low porosity HC materials derived from sucrose in line with our previous work. [31][32][33] These materials were characterized using X-ray diffraction (XRD), Raman, nitrogen sorption analysis, neutron total scattering and pair distribution function (PDF) analysis, various methods of density analysis, and galvanostatic charge/discharge (GCD) allowing for a differential look at how the structural, physical, and electrochemical properties evolve with increasing pyrolysis temperature.…”

“…[ 15–18 ] However, previous studies have heavily focused on modeling porosity and its impact on sorption properties due to HCs utility as a filter. [ 17–23 ] More recent studies use similar modeling procedures to understand electrochemical processes such as capacitance [ 24–26 ] and Li‐ion binding, [ 27–30 ] but there are few studies that examine in sufficient detail, the structure of HC in relation to Na‐ion binding. [ 29,30 ]…”

Combining Experimental and Theoretical Techniques to Gain an Atomic Level Understanding of the Defect Binding Mechanism in Hard Carbon Anodes for Sodium Ion Batteries

Challenges and Breakthroughs in Enhancing Temperature Tolerance of Sodium‐Ion Batteries

Local Structure Analysis and Modelling of Lignin‐Based Carbon Composites through the Hierarchical Decomposition of the Radial Distribution Function