Hydrogen-Bonding-Assisted Substituent Engineering for Modulating Magnetic Spin Couplings and Switching in m-Phenylene Nitroxide Diradicals

IF 2.7 2区 化学 Q3 CHEMISTRY, PHYSICAL
Xiangyun Zheng,  and , Yuxiang Bu*, 
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Abstract

Rational modification of the coupler for the theoretical design of molecular magnets has attracted extensive interest. Substituent insertion is a widely used strategy for adjusting molecular properties, but its effect and modulation on magnetic spin couplings have been less investigated. In this work, we predict the magnetic properties of the design m-phenylene nitroxide (NO) diradicals regulated by introducing substituents. The calculated results for those two pairs of diradicals indicate that the signs of their magnetic coupling constants J do not change, but the magnitudes remarkably change after substituent regulation in the range from 253 to 730 cm–1. Such noticeable magnetic changes induced by introducing subsituents are mainly attributed to different electronic effects of substituents, assisted by the proximity of two NO groups, good planarity, conjugation, and an intramolecular hydrogen bond. In particular, the insertion of intramolecular H-bonds not only indicates an electronic effect but also has greatly changed the spin density distribution. Further aromaticity of the coupler ring, spin densities, and molecular orbitals and energetics was evaluated to gain a better understanding of magnetic regulation. Interestingly, further protonation of some substituents (e.g., −NO2 and −CO2) can noticeably turn the spin coupling from ferromagnetic to antiferromagnetic, showing manipulable magnetic switching. This work provides a promising strategy based on substituent engineering for magnetic spin coupling modulation, not only turning the coupling magnitude but also enabling the magnetic switching, thus providing insights into molecular magnetic manipulation for spintronics applications.

Abstract Image

氢键辅助取代基工程调制间苯基氮氧化物双自由基的磁自旋耦合和开关
分子磁体理论设计中对耦合器的合理修改引起了广泛的关注。取代基插入是一种广泛使用的调节分子性质的策略,但其对磁自旋耦合的影响和调制研究较少。在这项工作中,我们预测了通过引入取代基调节的间苯基氮氧化物(NO)二自由基的磁性能。对这两对双基的计算结果表明,它们的磁偶联常数J在253 ~ 730 cm-1范围内经过取代基调控后,其数值变化不大。引入取代基引起的这种明显的磁性变化主要是由于取代基的不同电子效应,两个NO基团的接近,良好的平面性,共轭性和分子内氢键的辅助。特别是分子内氢键的插入不仅表明了电子效应,而且极大地改变了自旋密度分布。进一步评估了耦合环的芳构性、自旋密度、分子轨道和能量学,以更好地理解磁调节。有趣的是,一些取代基(如- NO2和- CO2)的进一步质子化可以明显地将自旋耦合从铁磁性转变为反铁磁性,显示出可操纵的磁开关。这项工作为磁自旋耦合调制提供了一种基于取代基工程的有前途的策略,不仅改变了耦合幅度,而且实现了磁开关,从而为自旋电子学应用中的分子磁操纵提供了见解。
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来源期刊
The Journal of Physical Chemistry A
The Journal of Physical Chemistry A 化学-物理:原子、分子和化学物理
CiteScore
5.20
自引率
10.30%
发文量
922
审稿时长
1.3 months
期刊介绍: The Journal of Physical Chemistry A is devoted to reporting new and original experimental and theoretical basic research of interest to physical chemists, biophysical chemists, and chemical physicists.
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