Topological Quantization in Units of the Fine Structure Constant. Tianhe Li, Thomas Johnson, Matthaios Karydas, Davneet Kaur

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Transcription:

Topological Quantization in Units of the Fine Structure Constant Tianhe Li, Thomas Johnson, Matthaios Karydas, Davneet Kaur

Outline Introduction and Background Proposed Experiment Critique Citation Analysis

Topological Quantization in Condensed Matter Systems Superconductor(SC): magnetic flux is quantized in the units of flux quantum Quantum Hall effect(qhe): Hall conductance is quantized in the units of conductance quantum Topological magnetoelectric effect(tme): a quantized coefficient in the units of fine structure constant described by topological field theories in the low-energy limit with quantized coefficients provide the most precise measurement of fundamental physical constants e, h and c

Topological Magnetoelectric Effect (TME) For the time-reversal (T) invariant topological insulator (TI), the effective Lagrangian is Under T: B -B E E Described the topological magnetoelectric effect The system is invariant under shifts of θ by any multiple of 2π The only allowed value of θ by time reversal symmetry is 0 or π For topological insulators, θ=π; trivial insulators, θ=0.

Faraday Effect vs. Kerr Effect Look! My name is ahead of yours The polarization of light is rotated when light is transmitted through (Faraday) or reflected from (Kerr) magnetized materials

Purpose of the Paper Provide an optical experiment to measure the topological magnetoelectric effect How? Exploit the Faraday & Kerr effects Measure Kerr and Faraday Angles (easy) Deduce the quantization of the parameter from the measured angles

Experimental Setup 1. A film of TI (topological insulator) of thickness and parameter 2. A topologically trivial substrate with parameter 3. A magnetic field is applied in the z direction in order to have the Faraday-Kerr effects

Kerr and Faraday Angles what we can measure! Incident Monochromatic Light : Reflected Light : Kerr Angle : Transmitted Light : Faraday Angle :

What parameters determine the rotation of the light polarization? Generally the Kerr and Faraday angles will depend on many parameters (dielectric constants of materials, length, frequency of light, multiple reflections,, ) It seems dubious that we could extract the exact quantization of the TME from just the Kerr/Faraday angles But the paper suggests a trick that simplifies the expressions - Measure the angles at reflectivity minima and maxima (simplifies the expressions significantly)

Reflectivity minima Find specific frequency so that we have minimum reflectivity Equation between Faraday and Kerr angles: ( Independent on other properties of the materials )

Reflectivity maxima ω is now tuned to a reflectivity maxima Kerr and Faraday angles - more compicated formulas

Universal Function Use previous formulas to find an equation of the form: does not depend explicitly on any material parameter We can find the zero crossing Hence find the parameter Demonstrate the quantization of the TME effect in the TI bulk by verifying it is always 0 or π!

Summary Authors propose an optical experiment to directly measure the topological quantization phenomenon. By considering both the Kerr and Faraday effects, the authors derive the universal function f, which is independent of material parameters and can be used to determine

Critique Is the experiment feasible? Theory only applies when. To achieve maximum or minimum reflectivity ω or the thickness of the TI film must be changed continuously. Samples do not yet have sufficient quality to yield strongly developed Quantum Hall effects. This paper neglects reflection from the substratevacuum boundary.

Impact of the paper This paper has been cited 88 times. The TME effect has yet to be observed. Yuanpei Lan, Shaolong Wan,and Shou-Cheng Zhang. Generalized quantization condition for topological insulators. Phys. Rev. B 83, 205109 (2011). Considers light at oblique incidence Wang-Kong Tse and A. H. MacDonald. Magneto-optical Faraday and Kerr effects in topological insulator films and in other layered quantized Hall systems. Phys. Rev. B 84, 205327 (2011) Considers both thin and thick films Examines possible experimental difficulties

Thank you!

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