Ground state of spin chain system by Density Functional Theory
The Cu–O based spin chain system A2CuO3 (A = Sr, Ca) has attracted considerable attention of scientists
during the last decades due to its unique electronic structure. This paper presents a ground state optimization
for the periodic structure of Ca2CuO3 using the Density Functional Theory (DFT). The electronic
structure analysis was carried out on the basis of cell optimization using the PBE functional with DNP
basis set. Until now, the numerical results were obtained only with exclusion of CaO bilayers from full
ab initio treatment. We demonstrate here that the correct covalent insulating ground state may be
obtained if the antiferromagnetic interaction along the spin chain is included. The best estimated band
gap is 0.79 eV. We also show that the CaO bilayers sufficiently contributed to the distribution of d-states
above Fermi level.
Title:
Ground state of spin chain system by Density Functional Theory | |
Authors: | Hoang, Nam Nhat Nguyen, Thuy Trang |
Keywords: | Ab initio Spin chain Antiferromagnet Ground state |
Issue Date: | 2010 |
Publisher: | ELSEVIER SCIENCE BV, PO BOX 211, 1000 AE AMSTERDAM, NETHERLANDS |
Citation: | ISIKNOWLEDGE |
Abstract: | The Cu–O based spin chain system A2CuO3 (A = Sr, Ca) has attracted considerable attention of scientists during the last decades due to its unique electronic structure. This paper presents a ground state optimization for the periodic structure of Ca2CuO3 using the Density Functional Theory (DFT). The electronic structure analysis was carried out on the basis of cell optimization using the PBE functional with DNP basis set. Until now, the numerical results were obtained only with exclusion of CaO bilayers from full ab initio treatment. We demonstrate here that the correct covalent insulating ground state may be obtained if the antiferromagnetic interaction along the spin chain is included. The best estimated band gap is 0.79 eV. We also show that the CaO bilayers sufficiently contributed to the distribution of d-states above Fermi level. |
Description: | TNS06126 ; COMPUTATIONAL MATERIALS SCIENCE Volume: 49 Issue: 4 Supplement: 1 Pages: S348-S354 |
URI: | http://repository.vnu.edu.vn/handle/VNU_123/29000 |
ISSN: | 0927-0256 |
Appears in Collections: | Bài báo của ĐHQGHN trong Web of Science |
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