Optical absorption in 3D topological insulator Bi2Te3 with applications to THz detectors (Presentation Recording)

SPIE NanoScience + Engineering Pub Date : 2015-10-05 DOI:10.1117/12.2190356

P. Sengupta, E. Bellotti

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Abstract

Topological insulators (TI) are a new class of materials that have an energy gap in bulk but possess gapless states bound to the sample surface or edge that have been theoretically predicted and experimentally observed [1]. The topological state in Bi2Te3 is characterized by a linear dispersion and a Dirac cone at the Γpoint. The optical absorption on the surface of a TI is given by the standard graphene-like απ/2 when a linear dispersion is assumed. Realistically, at k-points away from Γ, higher order cubic terms in k that represent the underlying hexagonal symmetry [2] of the crystal dominate and give rise to warping of bands. The optical absorption of a ferromagnetic coated gapped 3D TI film with warping terms considered is longer απ/2 but significantly modified. We demonstrate, by using wave functions from a continuum-Hamiltonian and Fermi-golden rule, the absorption spectrum on the surface of a TI as a function of the chemical potential, film-thickness and incident photon energy. A linear response theory based calculation is also performed using the Kubo formula to determine the longitudinal optical conductivity whose real part gives absorption as a function of photon frequency. The absorption in materials with Dirac fermions which is significantly higher than in normal THz detectors [3] can be further modulated in a TI by explicitly including the warping term making them highly efficient and tunable photodetectors. [1] M.Hasan and C.Kane, Rev.Mod.Phys. 82, 3045(2010) [2] L.Fu, Phys.Rev.Lett.103, 266801(2009) [3] X.Zhang et al., Phys. Rev B, 82, 245107(2010)

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三维拓扑绝缘体Bi2Te3的光吸收及其在太赫兹探测器上的应用(演讲记录)

拓扑绝缘体(Topological insulators, TI)是一类新的材料，它在体上具有能隙，但具有与样品表面或边缘相结合的无隙状态，这是理论预测和实验观察到的[1]。Bi2Te3的拓扑状态以线性色散和Γpoint处的狄拉克锥为特征。假设线性色散时，TI表面的光学吸收由标准类石墨烯απ/2给出。实际上，在远离Γ的k点处，k中的高阶立方项(表示晶体潜在的六边形对称性[2])占主导地位，并导致能带翘曲。考虑翘曲项的铁磁涂层三维TI薄膜的光学吸收απ/2更长，但有明显的改变。利用连续哈密顿和费米黄金法则中的波函数，我们证明了TI表面的吸收光谱是化学势、膜厚度和入射光子能量的函数。基于线性响应理论的计算也使用Kubo公式来确定纵向光学电导率，其实部给出吸收作为光子频率的函数。具有狄拉克费米子的材料的吸收明显高于普通太赫兹探测器[3]，通过明确地包括翘曲项，可以在TI中进一步调制，使其成为高效可调谐的光电探测器。[1]陈志强，陈志强。[2]傅立强，李志强，李志强，等。[3]张晓等，物理学报。Rev B, 82, 245107(2010)

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SPIE NanoScience + Engineering

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