Marvin Schmidt, Savita Priya, Zhijie Huang, Mark Kartsovnik, Natalia Kushch, Martin Dressel
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引用次数: 0
摘要
二维分子导体$\kappa$-(BETS)$_2$Mn[N(CN)$_2$]$_3$在$T_{\rm MI}\approx$21K时发生了急剧的金属-绝缘体相变,多年来一直受到人们的关注。我们沿着低至 10 K 的温度函数的三个晶体学方向进行了全面的红外研究,并辅以电子自旋共振和直流传输研究。与其他 $\kappa$ 型 BEDT-TTF 或相关化合物相比,光导率的面内各向异性更为明显。由于与电子系统的耦合,金属-绝缘体转变会影响分子振动;此外,我们还观察到电荷敏感振动模式在 $T_{\rm MI}$ 以下有明显的分裂,这证明该化合物中存在两种不同的 BETS 二聚体。锰[N(CN)$_2$]$_3^-$层是由阴离子的链结构决定的,这导致了其各向异性的行为和振动特征的显著温度依赖性。在低温条件下,Mn$^{2+}$ 离子通过$\pi$-$d$耦合和$\pi$-spins 内的反铁磁排序影响 ESR 特性:随着温度的降低,面内各向异性会发生明显的翻转,从而使 g 因子发生巨大的变化;自旋线会显著变宽;冷却时自旋易感性会增加,并在相变处出现扭结。
Electronic properties of the dimerized organic conductor $κ$-(BETS)$_2$Mn[N(CN)$_2$]$_3$
The two-dimensional molecular conductor $\kappa$-(BETS)$_2$Mn[N(CN)$_2$]$_3$
undergoes a sharp metal-to-insulator phase transition at $T_{\rm MI}\approx$ 21
K, which has been under scrutiny for many years. We have performed
comprehensive infrared investigations along the three crystallographic
directions as a function of temperature down to 10 K, complemented by electron
spin resonance and dc-transport studies. The in-plane anisotropy of the optical
conductivity is more pronounced than in any other $\kappa$-type BEDT-TTF or
related compounds. The metal-insulator transitions affects the molecular
vibrations due to the coupling to the electronic system; in addition we observe
a clear splitting of the charge-sensitive vibrational modes below $T_{\rm MI}$
that evidences the presence of two distinct BETS dimers in this compound. The
Mn[N(CN)$_2$]$_3^-$ layers are determined by the chain structure of the anions
resulting in a rather anisotropic behavior and remarkable temperature
dependence of the vibronic features. At low temperatures the ESR properties are
affected by the Mn$^{2+}$ ions via $\pi$-$d$-coupling and antiferromagnetic
ordering within the $\pi$-spins: The $g$-factor shifts enormously with a
pronounced in-plane anisotropy that flips as the temperature decreases; the
lines broaden significantly; and the spin susceptibility increases upon cooling
with a kink at the phase transition.
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