Calcium Poly(Heptazine Imide): A Covalent Heptazine Framework for Selective CO2 Adsorption.

Potassium poly(heptazine imide) (KPHI) has recently garnered attention as a crystalline carbon nitride framework with considerable photoelectrochemical activity. Here, we report a Ca2+-complexed analogue of PHI: calcium poly(heptazine imide) (CaPHI). Despite similar polymer backbone, CaPHI and KPHI exhibit markedly different crystal structures. Spectroscopic, crystallographic, and physisorptive characterization reveal that Ca2+ acts as a structure-directing agent to transform melon-based carbon nitride to crystalline CaPHI with ordered pore channels, extended visible light absorption, and altered band structure as compared to KPHI. Upon acid washing, protons replace Ca2+ atoms in CaPHI to yield H+/CaPHI and enhance porosity without disrupting crystal structure. Further, these proton-exchanged PHI frameworks exhibit large adsorption affinity for CO2 and exceptional performance for selective carbon capture from dilute streams. Compared to a state-of-the-art metal organic framework, UTSA-16, H+/CaPHI exhibits more than twice the selectivity (∼300 vs ∼120) and working capacity (∼1.2 mmol g-1 vs ∼0.5 mmol g-1) for a feed of 4% CO2 (1 bar, 30 °C).

Embedded atom method potential for hydrogen on palladium surfaces.

The development of transferable interatomic potentials for the diffusion of hydrogen on palladium surfaces can be of significant value for performing molecular simulations. These molecular simulations can, in turn, lead to a better understanding of palladium-hydrogen interactions at the atomic scale. Here, we have built upon previous work to develop an analytical palladium-hydrogen-embedded atom method (EAM) potential to better describe the potential energy surface for hydrogen on palladium surfaces. This EAM potential reproduces minima and transition states calculated with density functional theory for hydrogen on Pd(111) and Pd(110) surfaces. Additionally, this potential was tested by simulating the long timescale dynamics of hydrogen adsorbed on Pd(111). Our simulations show a barrier of ca. 0.49 eV for hydrogen diffusion into the bulk of Pd(111), which is consistent with experimental results.

Hydrogen desorption from the surface and subsurface of cobalt.

The influence of coverage on the diffusion of hydrogen into the subsurface of cobalt was studied using density functional theory (DFT) and temperature programmed desorption (TPD). DFT calculations show that as the hydrogen coverage on Co(0001) increases, the barrier for hydrogen diffusion into the bulk decreases by 20%. Additionally, subsurface hydrogen on a hydrogen covered surface was found to be more stable when compared to a clean cobalt surface. To test these theoretical findings experimentally, excited hydrogen was used in an ultra-high vacuum environment to access higher hydrogen coverages. Our TPD studies showed that at high hydrogen coverages, a sharp low temperature feature appeared, indicating the stabilization of subsurface hydrogen. Further DFT calculations indicate that this sharp low temperature feature results from associative hydrogen desorption from a hydrogen saturated surface with a population of subsurface hydrogen. Microkinetic modelling was used to model the TPD spectra for hydrogen desporption from cobalt with and without subsurface hydrogen, showing reasonable agreement with experiment.

Low temperature dissociation of CO on manganese promoted cobalt(poly).

We observe that metallic manganese alloyed with polycrystalline cobalt promotes the dissociation of CO. Increasing coverages of Mn on Co facillitate stronger molecular CO binding energies and stronger C(ad) + O(ad) binding energies. These findings show the role of metallic manganese in promoting model Co Fischer-Tropsch catalysis.

Carbon Nitride Transforms into a High Lithium Storage Capacity Nitrogen-Rich Carbon.

We describe here the metal-templated transformation of carbon nitride (C3N4) into nitrogen-containing carbons as anodes for Li-ion batteries (LIBs). Changing the template from the carbon- and nitrogen-immiscible Cu powder to the carbon- and nitrogen-miscible Fe powder yields different carbons; while Fe templating produces graphitized carbons of low (<10%) nitrogen content and moderate pore volume, Cu templating yields high defect-density carbons of high (32-24%) nitrogen content and larger pore volume. The Li+ storage capacity of the high nitrogen content and larger pore volume Cu-templated carbons exceeds that of the more graphitic Fe-templated carbons due to added contribution from Li+ insertion/extraction from pores and defects and to reversible faradaic Li+ reaction with nitrogen atoms. The Cu-templated carbon annealed at 750 °C delivers the highest specific capacity of 900 mAh g-1 at 0.1 A g-1 and 275 mAh g-1 at 20 A g-1, while also achieving a 96% capacity retention after 2000 cycles at 2 A g-1. The fabrication of higher mass loading electrodes (4.5 mg cm-2) provided a maximum areal capacity of 2.6 mAh cm-2 at 0.45 mA cm-2 (0.1 A g-1), comparable to the capacities of commercial LIB cells and favorable compared to other reported carbon materials.