Density functional theory studies on theelectronic, structural, phonon dynamicaland thermo-stability properties of bicarbonates MHCO3, M D Li, Na, K

Duan, Yuhua; Zhang, Bo; Sorescu, Dan C; Johnson, Karl; Majzoub, Eric H; Luebke, David R

doi:10.1088/0953-8984/24/32/325501

Title: Density functional theory studies on theelectronic, structural, phonon dynamicaland thermo-stability properties of bicarbonates MHCO3, M D Li, Na, K

Journal Article · Sun Jul 01 00:00:00 EDT 2012 · JOURNAL OF PHYSICS: CONDENSED MATTER

DOI:https://doi.org/10.1088/0953-8984/24/32/325501· OSTI ID:1051616

Duan, Yuhua; Zhang, Bo; Sorescu, Dan C; Johnson, Karl; Majzoub, Eric H; Luebke, David R

The structural, electronic, phonon dispersion and thermodynamic properties of MHCO3 (M D Li, Na, K) solids were investigated using density functional theory. The calculated bulk properties for both their ambient and the high-pressure phases are in good agreement with available experimental measurements. Solid phase LiHCO3 has not yet been observed experimentally. We have predicted several possible crystal structures for LiHCO3 using crystallographic database searching and prototype electrostatic ground state modeling. Our total energy and phonon free energy .FPH/ calculations predict that LiHCO3 will be stable under suitable conditions of temperature and partial pressures of CO2 and H2O. Our calculations indicate that the HCO􀀀 3 groups in LiHCO3 and NaHCO3 form an infinite chain structure through O H O hydrogen bonds. In contrast, the HCO􀀀 3 anions form dimers, .HCO􀀀 3 /2, connected through double hydrogen bonds in all phases of KHCO3. Based on density functional perturbation theory, the Born effective charge tensor of each atom type was obtained for all phases of the bicarbonates. Their phonon dispersions with the longitudinal optical–transverse optical splitting were also investigated. Based on lattice phonon dynamics study, the infrared spectra and the thermodynamic properties of these bicarbonates were obtained. Over the temperature range 0–900 K, the FPH and the entropies (S) of MHCO3 (M D Li, Na, K) systems vary as FPH.LiHCO3/ > FPH.NaHCO3/ > FPH.KHCO3/ and S.KHCO3/ > S.NaHCO3/ > S.LiHCO3/, respectively, in agreement with the available experimental data. Analysis of the predicted thermodynamics of the CO2 capture reactions indicates that the carbonate/bicarbonate transition reactions for Na and K could be used for CO2 capture technology, in agreement with experiments.

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Research Organization:: National Energy Technology Lab. (NETL), Pittsburgh, PA, and Morgantown, WV (United States). In-house Research

Sponsoring Organization:: USDOE Office of Fossil Energy (FE)

OSTI ID:: 1051616

Report Number(s):: NETL-PUB-326

Journal Information:: JOURNAL OF PHYSICS: CONDENSED MATTER, Vol. 24, Issue 32; ISSN 0953--8984

Country of Publication:: United States

Language:: English

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