Materials with magneto-optic (MO) properties have enabled critical fiber-optic applications and highly sensitive magnetic field sensors. While traditional MO materials are inorganic in nature, new generations of MO materials based on organic semi-conducting polymers could allow increased versatility for device architectures, manufacturing options, and flexible mechanics. However, the origin of MO activity in semiconducting polymers is far from understood. In this paper, we report high MO activity observed in a chiral helical poly-3-(alkylsulfone)thiophene (>P3AST), which confirms a new design for the creation of giant Faraday effect with Verdet constants up to (7.63±0.78)×104 deg T−1 m−1 at 532 nm. We have determined that the sign of the Verdet constant and its magnitude are related to the helicity of the polymer at the measured wavelength. The Faraday rotation and the helical conformation of >P3AST are modulated by thermal annealing, which is further supported by DFT and MD simulations. Our results demonstrate that helical polymers exhibit enhanced Verdet constants, and expand the previous design space for polythiophene MO materials that was thought to be limited to highly regular lamellar structures. The structure property studies herein provide insights for the design of next generation MO materials based upon semiconducting organic polymers.
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机译:具有磁光(MO)特性的材料已使关键的光纤应用和高度灵敏的磁场传感器成为可能。尽管传统的MO材料本质上是无机材料,但是基于有机半导体聚合物的新一代MO材料可以提高设备架构,制造选择和灵活机械的通用性。但是,尚不了解半导体聚合物中MO活性的起源。在本文中,我们报道了在手性螺旋聚-3-(烷基砜)噻吩(> P3AST )中观察到的高MO活性,这证实了一种新的设计,该设计可用于创建Verdet常数高达1的巨型法拉第效应。在532 nm处为(7.63±0.78)×10 4 deg T -1 m -1 。我们已经确定,Verdet常数的符号及其幅度与所测波长下聚合物的螺旋度有关。法拉第旋转和> P3AST 的螺旋构象通过热退火进行调节,DFT和MD模拟进一步支持了这一点。我们的结果表明,螺旋聚合物表现出增强的Verdet常数,并扩大了以前被认为仅限于高度规则的层状结构的聚噻吩MO材料的设计空间。本文的结构特性研究为基于半导体有机聚合物的下一代MO材料的设计提供了见识。
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