Slow and non-equilibrium dynamics due to electronic ferroelectricity in a strongly-correlated molecular conductor

Tatjana Thomas, Yassine Agarmani, Steffi Hartmann, Mark Kartsovnik, Natalia Kushch, Stephen M. Winter, Sebastian Schmid, Peter Lunkenheimer, Michael Lang, Jens Müller
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Abstract

Ferroelectricity, where electronic degrees of freedom determine the polar order—thereby enabling fast switching and phase control—is an important research field in current condensed-matter physics. Using a combination of resistance noise and dielectric spectroscopy we investigate the nature of relaxor-type electronic ferroelectricity in the organic conductor κ-(BETS)2Mn[N(CN)2]3, a system that represents a wider class of materials of correlated electron systems for which functionalities for organic spintronics recently have been discussed. The two complementary spectroscopies reveal a distinct low-frequency dynamics on different length scales, namely (i) an intrinsic relaxation that is typical for relaxor ferroelectrics which classifies the system as a possible new multiferroic, and (ii) two-level processes which we identify as fluctuating polar nanoregions (PNR), i.e., clusters of quantum electric dipoles that fluctuate collectively. The PNR preform above the metal insulator (MI) transition. Upon cooling through TMI, a drastic increase of the low-frequency 1/f-type fluctuations and slowing down of the charge carrier dynamics is accompanied by the onset of strong non-equilibrium dynamics indicating a glassy transition of interacting dipolar clusters. The freezing of PNR and non-equilibrium dynamics is suggested to be a common feature of organic relaxor-type electronic ferroelectrics.

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强相关分子导体中电子铁电引起的慢速非平衡动力学
铁电性是当前凝聚态物理学的一个重要研究领域,在铁电性中,电子自由度决定极序,从而实现快速开关和相位控制。我们结合电阻噪声和介电光谱,研究了有机导体κ-(BETS)2Mn[N(CN)2]3 中弛豫型电子铁电的性质。两种互补光谱揭示了不同长度尺度上的独特低频动力学,即(i)弛豫铁电典型的本征弛豫,它将该系统归类为一种可能的新型多铁电体,以及(ii)两级过程,我们将其确定为波动极性纳米区域(PNR),即集体波动的量子电偶极子簇。PNR 预形成于金属绝缘体(MI)转变之上。冷却至 TMI 时,低频 1/f 型波动急剧增加,电荷载流子动力学放缓,同时出现了强烈的非平衡动力学,表明相互作用的偶极簇发生了玻璃化转变。PNR 和非平衡动力学的冻结被认为是有机弛豫型电子铁电的一个共同特征。
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