OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

科学通报 2015

水和重水红外吸收光谱的Car-Parrinello分子动力学模拟

DOI: 10.1360/N972014-01243, PP. 3014-3020

王程超,谭建宇,杨家跃,刘林华

Keywords: 红外吸收光谱,光学常数,CPMD,第一性原理

Full-Text Cite this paper Add to My Lib

Abstract:

红外吸收光谱在水的热力学及动力学特性研究中起到了关键作用.本文采用基于密度泛函理论的Car-Parrinello分子动力学(CPMD)方法研究了水和重水的红外吸收性质及介电和光学特性.以能量最小化构型为输入结构,运用该方法计算室温下水和重水的分子电偶极矩总和,进而通过傅里叶变换得到红外吸收光谱.数值分析表明室温下水和重水红外吸收光谱的理论计算值与文献中实验结果相吻合,表征OH键拉伸模式的光谱峰值位置略有红移,验证了CPMD方法的可行性,为高温高压等极端工况下水的基础物性参数研究提供了参考.

References

[1]	1 Tan H P, Liu L H, Yi H L, et al. Recent progress in computational thermal radiative transfer (in Chinese). Chin Sci Bull, 2009, 54: 2627-2637 [谈和平, 刘林华, 易红亮, 等. 计算热辐射学的进展. 科学通报, 2009, 54: 2627-
[2]	2 Ueno S, Tanimura Y, Tenno S. Molecular dynamics simulation for infrared spectroscopy with intramolecular forces from electronic properties of on-the-fly quantum chemical calculations. Int J Quant Chem, 2013, 113: 330-335
[3]	3 Wang Z P, Zhang F S, Wang J. TDDFT studies of water molecule in laser field (in Chinese). Chin Sci Bull, 2013, 58: 1407-1413 [王志萍, 张丰收, 王菁. 水分子在激光场中的密度泛函理论研究. 科学通报, 2013, 58: 1407-
[4]	4 Zhai L J, Zheng Y J. Ro-vibrational molecular quantum computing and ro-vibartional entanglement (in Chinese). Chin Sci Bull, 2013, 58: 891-900 [翟良君, 郑雨军. 分子振转动量子计算及分子振转动纠缠. 科学通报, 2013, 58: 891-
[5]	5 Lee H, Tuckerman M E. Dynamical properties of liquid water from ab initio molecular dynamics performed in the complete basis set limit. J Chem Phys, 2007, 126: 164501
[6]	6 Hura G, Sorenson J M, Glaeser R M, et al. A high-quality x-ray scattering experiment on liquid water at ambient conditions. J Chem Phys, 2000, 113: 9140
[7]	7 Bertie J E, Lan Z D. Infrared intensities of liquids XX: The intensity of the OH stretching band revisited, and the best current values of the optical constants H2O at 25℃ between 15000 and 1 cm-1. Appl Spectrosc, 1996, 50: 1047-1057
[8]	8 Bertie J E, Ahmed M K, Eysel H H. Infrared intensities of liquids. 5. Optical and dielectric constants, integrated intensities, and dipole moment derivatives of H2O and D2O at 22℃. J Chem Phys, 1989, 93: 2210-2218
[9]	9 Allesch M, Schwegler E, Gygi F, et al. A first principles simulation of rigid water. J Chem Phys, 2004, 120: 5192-5198
[10]	10 Imoto S, Xantheas S S, Saito S. Molecular origin of the difference in the HOH bend of the IR spectra between liquid water and ice. J Chem Phys, 2013, 138: 054506
[11]	11 Guillot B. A molecular dynamics study of the far infrared spectrum of liquid water. J Chem Phys, 1991, 95: 1543-1551
[12]	12 Soper A K. The radial distribution functions of water and ice from 220 to 673 K and at pressures up to 400 MPa. Chem Phys, 2000, 258: 121-137
[13]	13 Silvestrelli P L, Bernasconi M, Parrinello M. Ab initio infrared spectrum of liquid water. Chem Phys Lett, 1997, 277: 478-482
[14]	14 Car R, Parrinello M. Unified approach for molecular dynamics and density-functional theory. Phys Rev Lett, 1985, 55: 2471-2474
[15]	15 Zhang C, Donadio D, Gygi F, et al. First principles simulations of the infrared spectrum of liquid water using hybrid density functionals. J Chem Theory Comput, 2011, 7: 1443-1449
[16]	16 Lin C, Seitsonen A P, Tavernelli I, et al. Structure and dynamics of liquid water from ab initio molecular dynamics comparison of BLYP, PBE, and revPBE density functionals with and without van der Waals corrections. J Chem Theory Comput, 2012, 8: 3902-3910
[17]	17 Bader J S, Berne B J. Quantum and classical relaxation rates from classical simulations. J Chem Phys, 1994, 100: 8359-8266
[18]	18 Becke A D. Density-functional exchange-energy approximation with correct asymptotic behavior. Phys Rev A, 1988, 38: 3098-3100
[19]	19 Goedecker S, Teter M, Hutter J. Separable dual-space Gaussian pseudopotentials. Phys Rev B, 1996, 54: 1703-1710
[20]	20 Iftimie R, Tuckerman M E. Decomposing total IR spectra of aqueous systems into solute and solvent contributions: A computational approach using maximally localized Wannier orbitals. J Chem Phys, 2005, 122: 214508
[21]	21 Zeng Y P, Zhu X M, Yang Z Y. Car-Parrinello molecular dynamics simulations of microstructure properties of liquid water, methanol and ethanol (in Chinese). Acta Phys-Chim Sin, 2011, 27: 2779-2785 [曾勇平, 朱晓敏, 杨正华. 水、甲醇和乙醇液体微结构性质的Car-Parrinello分子动力学模拟. 物理化学学报, 2011, 27: 2779-
[22]	22 Tangney P, Scandolo S. How well do Car-Parrinello simulations reproduce the Born-Oppenheimer surface? Theory and examples. J Chem Phys, 2002, 116: 14
[23]	23 Sprik M, Hutter J, Parrinello M. Ab initio molecular dynamics simulation of liquid water: Comparison of three gradient-corrected density functional. J Chem Phys, 1996, 105: 1142-1152
[24]	24 Gajdo？ M, Hummer K, Kresse G. Linear optical properties in the projector-augmented wave methodology. Phys Rev B, 2006, 73: 045112
[25]	25 Zelsmann H R. Temperature dependence of the optical constants for liquid H2O and D2O in the far IR region. J Mol Struct, 1995, 350: 95-114
[26]	26 Maréchal Y. Infrared spectra of water. I. Effect of temperature and of H/D isotopic dilution. J Chem Phys, 1991, 95: 5565-5573

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133