First-principles study on the electronic structure and optical properties of Tl2Cd2(SO4)3 and Rb2Cd2(SO4)4

doi:10.1088/1009-1963/16/12/040

Abstract

Abstract With the help of ab initio full-potential linearized augmented plane wave (FPLAPW) method, calculating the electronic structure and linear optical properties is carried out for $X$Cd$_{2}$(SO$_4$)$_{3}$ ($X=$Tl, Rb). The results show that Tl$_{2}$Cd$_{2}$(SO$_4$)$_{3}$ (TlCdS) has a larger band gap than Rb$_{2}$Cd$_{2}$(SO$_4$)$_{3}$ (RbCdS) and the energy bands for RbCdS are more dispersive than those of TlCdS. From their partial densities of states (PDOS), we have observed that the hybridization between S ionic 2p and O atomic 2p orbitals forms SO$_{4}$ ionic groups. The remarkable difference between RbCdS and TlCdS is, however, the degree of hybridization between cation (Tl and Rb) and its surrounding oxygen atoms. In the view of quantum chemistry, the strong p-d hybridization indicates the existence of their cation ionic bonds (Cd-O, Rb-O, and Tl-O). The calculations of TlCdS and RbCdS show their optical properties to be less anisotropic. Their anisotropies in the optical properties mainly occur in a low photon energy region of 5--16 eV.

Keywords: langbeinite electronic structure band gap optical properties

Accepted manuscript online:

PACS:	71.20.Ps	(Other inorganic compounds)
	71.15.Ap	(Basis sets (LCAO, plane-wave, APW, etc.) and related methodology (scattering methods, ASA, linearized methods, etc.))
	78.20.Ci	(Optical constants (including refractive index, complex dielectric constant, absorption, reflection and transmission coefficients, emissivity))

Fund: Project supported by the National Science Foundation of China (Grant No~2006CB921605) and the National Natural Science Foundation of China (Grant Nos~10174024 and 10474025).

Cite this article:

Xu Bin(徐斌) Cheng Zheng--Ze(程正则), Yi Lin(易林), and Cheng Ze(成泽) First-principles study on the electronic structure and optical properties of Tl₂Cd₂(SO₄)₃ and Rb₂Cd₂(SO₄)₄ 2007 Chinese Physics 16 3798

[1]	Predicting novel atomic structure of the lowest-energy Fe_nP_13-n(n=0-13) clusters: A new parameter for characterizing chemical stability Yuanqi Jiang(蒋元祺), Ping Peng(彭平). Chin. Phys. B, 2023, 32(4): 047102.
[2]	High-temperature ferromagnetism and strong π-conjugation feature in two-dimensional manganese tetranitride Ming Yan(闫明), Zhi-Yuan Xie(谢志远), and Miao Gao(高淼). Chin. Phys. B, 2023, 32(3): 037104.
[3]	First-principles study of a new BP₂ two-dimensional material Zhizheng Gu(顾志政), Shuang Yu(于爽), Zhirong Xu(徐知荣), Qi Wang(王琪), Tianxiang Duan(段天祥), Xinxin Wang(王鑫鑫), Shijie Liu(刘世杰), Hui Wang(王辉), and Hui Du(杜慧). Chin. Phys. B, 2022, 31(8): 086107.
[4]	Bandgap evolution of Mg₃N₂ under pressure: Experimental and theoretical studies Gang Wu(吴刚), Lu Wang(王璐), Kuo Bao(包括), Xianli Li(李贤丽), Sheng Wang(王升), and Chunhong Xu(徐春红). Chin. Phys. B, 2022, 31(6): 066205.
[5]	Temperature dependence of bismuth structures under high pressure Xiaobing Fan(范小兵), Shikai Xiang(向士凯), and Lingcang Cai(蔡灵仓). Chin. Phys. B, 2022, 31(5): 056101.
[6]	Erratum to “ Accurate GW₀ band gaps and their phonon-induced renormalization in solids” Tong Shen(申彤), Xiao-Wei Zhang(张小伟), Min-Ye Zhang(张旻烨), Hong Jiang(蒋鸿), and Xin-Zheng Li(李新征). Chin. Phys. B, 2022, 31(5): 059901.
[7]	Analysis on vibration characteristics of large-size rectangular piezoelectric composite plate based on quasi-periodic phononic crystal structure Li-Qing Hu(胡理情), Sha Wang(王莎), and Shu-Yu Lin(林书玉). Chin. Phys. B, 2022, 31(5): 054302.
[8]	First principles investigation on Li or Sn codoped hexagonal tungsten bronzes as the near-infrared shielding material Bo-Shen Zhou(周博深), Hao-Ran Gao(高浩然), Yu-Chen Liu(刘雨辰), Zi-Mu Li(李子木),Yang-Yang Huang(黄阳阳), Fu-Chun Liu(刘福春), and Xiao-Chun Wang(王晓春). Chin. Phys. B, 2022, 31(5): 057804.
[9]	Measurement of electronic structure in van der Waals ferromagnet Fe_5-xGeTe₂ Kui Huang(黄逵), Zhenxian Li(李政贤), Deping Guo(郭的坪), Haifeng Yang(杨海峰), Yiwei Li(李一苇),Aiji Liang(梁爱基), Fan Wu(吴凡), Lixuan Xu(徐丽璇), Lexian Yang(杨乐仙), Wei Ji(季威),Yanfeng Guo(郭艳峰), Yulin Chen(陈宇林), and Zhongkai Liu(柳仲楷). Chin. Phys. B, 2022, 31(5): 057404.
[10]	Nonlinear optical properties in n-type quadruple δ-doped GaAs quantum wells Humberto Noverola-Gamas, Luis Manuel Gaggero-Sager, and Outmane Oubram. Chin. Phys. B, 2022, 31(4): 044203.
[11]	High-throughput computational material screening of the cycloalkane-based two-dimensional Dion—Jacobson halide perovskites for optoelectronics Guoqi Zhao(赵国琪), Jiahao Xie(颉家豪), Kun Zhou(周琨), Bangyu Xing(邢邦昱), Xinjiang Wang(王新江), Fuyu Tian(田伏钰), Xin He(贺欣), and Lijun Zhang(张立军). Chin. Phys. B, 2022, 31(3): 037104.
[12]	Electronic structure and spin–orbit coupling in ternary transition metal chalcogenides Cu₂TlX₂ (X = Se, Te) Na Qin(秦娜), Xian Du(杜宪), Yangyang Lv(吕洋洋), Lu Kang(康璐), Zhongxu Yin(尹中旭), Jingsong Zhou(周景松), Xu Gu(顾旭), Qinqin Zhang(张琴琴), Runzhe Xu(许润哲), Wenxuan Zhao(赵文轩), Yidian Li(李义典), Shuhua Yao(姚淑华), Yanfeng Chen(陈延峰), Zhongkai Liu(柳仲楷), Lexian Yang(杨乐仙), and Yulin Chen(陈宇林). Chin. Phys. B, 2022, 31(3): 037101.
[13]	Transition metal anchored on C₉N₄ as a single-atom catalyst for CO₂ hydrogenation: A first-principles study Jia-Liang Chen(陈嘉亮), Hui-Jia Hu(胡慧佳), and Shi-Hao Wei(韦世豪). Chin. Phys. B, 2022, 31(10): 107306.
[14]	Spin and spin-orbit coupling effects in nickel-based superalloys: A first-principles study on Ni₃Al doped with Ta/W/Re Liping Liu(刘立平), Jin Cao(曹晋), Wei Guo(郭伟), and Chongyu Wang(王崇愚). Chin. Phys. B, 2022, 31(1): 016105.
[15]	First-principles study of structural and opto-electronic characteristics of ultra-thin amorphous carbon films Xiao-Yan Liu(刘晓艳), Lei Wang(王磊), and Yi Tong(童祎). Chin. Phys. B, 2022, 31(1): 016102.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

First-principles study on the electronic structure and optical properties of Tl2Cd2(SO4)3 and Rb2Cd2(SO4)4

Cite this article:

Online attention

First-principles study on the electronic structure and optical properties of Tl₂Cd₂(SO₄)₃ and Rb₂Cd₂(SO₄)₄