DFT-based Study of Electric Field Effect on the Polarizability of Three Ringed Nematic Liquid Crystal Molecules

IF 0.8 Q3 MULTIDISCIPLINARY SCIENCES
P. Upadhyay, Mirtunjai Mishra, Ankur Trivedi, J. Kumar, Asheesh Kumar, Devesh Kumar
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引用次数: 0

Abstract

Owing to its successful application to complex molecular systems, computational density functional theory (DFT) has been used to study the effect of an electric field on the molecular polarizability and HOMO–LUMO gap of 1-phenyl-4-{2[(1s,4r)-4-pentylcyclohexyl]ethyl}benzene (1) and its fluoro-, chloro-, and cyanoderivatives, namely, 1-fluoro-4-(4-{2[(1s,4r)-4-pentylcyclohexyl]ethyl}phenyl)benzene (2), 1-chloro-4-(4-{2-[(1s,4r)-4-pentylcyclohexyl]ethyl}phenyl)benzene (3), and 4-(4-{2-[(1s,4r)-4-pentylcyclohexyl]ethyl}phenyl)benzonitrile (4). These molecules belong to the family of nematic liquid crystals with three rings: two benzene and one cyclohexane. Furthermore, two DFT approaches, namely, B3LYP and M062X, have been used to examine the results obtained. This study reveals a remarkable feature: the polarizability of these molecules follows nearly a step function when varied with respect to the electric field. The 4-(4-{2[(1s,4r)-4-pentylcyclohexyl]ethyl}phenyl)benzonitrile (4) polarizes more than all other derivatives, whereas 1-fluoro-4-(4{2-[(1s,4r)-4-pentylcyclohexyl]ethyl}phenyl) benzene (2) has the widest stability region of them all. With the increase in the electric field, polarizability increases in a smooth manner until a point called here the shoot-up point at which polarizability switches to a higher value and remains nearly constant as the field increases further. However, beyond a certain value of the electric field, polarizability undergoes a steep fall. It is also found that the effective length (long molecular axis) of the molecule has a direct effect on its polarizability.
基于dft的电场对三环向列液晶分子极化率的影响研究
由于计算密度泛函理论(DFT)在复杂分子体系中的成功应用,研究了电场对1-苯基-4-{2[(1s,4r)-4-戊基环己基]乙基苯(1)及其氟衍生物、氯衍生物和氰基衍生物,即1-氟-4-(4-{2[(1s,4r)-4-戊基环己基]乙基苯基)苯(2)、1-氯-4-(4-{2-[(1s,4r)-4-戊基环己基]乙基苯基)苯(3)分子极化率和HOMO-LUMO间隙的影响。和4-(4-{2-[(1,4r)-4-戊基环己基]乙基苯基)苯腈(4)。这些分子属于具有三个环的向列液晶家族:两个苯和一个环己烷。此外,还使用了两种DFT方法,即B3LYP和M062X来检验所获得的结果。这项研究揭示了一个显著的特征:当这些分子的极化率随电场变化时,几乎遵循一个阶跃函数。4-(4-{2[(1s,4r)-4-戊基环己基]乙基苯基)苯腈(4)比所有其他衍生物更容易极化,而1-氟-4-(4{2-[(1s,4r)-4-戊基环己基]乙基苯基)苯(2)具有最宽的稳定区。随着电场的增加,极化率以平稳的方式增加,直到一个点,这里称为爆发点,在这个点上,极化率切换到一个更高的值,并随着电场的进一步增加而保持几乎不变。然而,超过一定的电场值,极化率急剧下降。分子的有效长度(长分子轴)对其极化率有直接影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Makara Journal of Science
Makara Journal of Science MULTIDISCIPLINARY SCIENCES-
CiteScore
1.30
自引率
20.00%
发文量
24
审稿时长
24 weeks
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