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Atilla Ozgur Cakmak, PhD

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Presentation on theme: "Atilla Ozgur Cakmak, PhD"— Presentation transcript:

1 Atilla Ozgur Cakmak, PhD
Nanophotonics Atilla Ozgur Cakmak, PhD

2 Lecture 15: Tight Binding Model-Part2
Unit 2 Lecture 15: Tight Binding Model-Part2

3 Outline The Transfer Matrix Impurities Tying up to Kronig-Penney
Single Impurity N Identical Impurity 2N Alternating Impurity Tying up to Kronig-Penney

4 A couple of words… There is another model effectively used for periodic wave propagation, which will be very useful for our understanding. It is called the tight binding approach and it is based on the wave functions which are very much localized at their sites. The wave propagation is in a way akin to hopping from site to site. There are studies which treat periodic configurations within the perspective of tight binding approach as we will see in the upcoming lectures. Suggested reading: Peter Markos, Costas M. Soukoulis Wave Propagation From Electrons to Photonic Crystals and Left-Handed Materials, 5th Chapter.

5 The Transfer Matrix

6 The Transfer Matrix (problem)
Find the explicit formula for K, the transfer matrix for tight binding problem given in the previous slide.

7 The Transfer Matrix (solution)
Find the explicit formula for T, the transfer matrix for tight binding problem given in the previous slide.

8 The Transfer Matrix

9 The Transfer Matrix

10 Impurities: Single Impurity

11 Impurities: N-identical Impurity

12 Impurities (problem) How many perfect transmission (T=1) peaks do appear for N=26 impurities? εA=0.5 a) 20 b) 25 c) 19 d) 23

13 Impurities (solution)
How many perfect transmission (T=1) peaks do appear for N=26 impurities? εA=0.5

14 Impurities (solution)
How many perfect transmission (T=1) peaks do appear for N=26 impurities? εA=0.5 We have to decrease E spacing to see T=1 bands clearly. The first band becomes T=1 when the spacings are small enough.

15 Impurities: 2N Alternating Impurity

16 Impurities: 2N Alternating Impurity

17 Impurities: 2N Alternating Impurity

18 Impurities (problem) How many perfect transmission (T=1) peaks do appear for 2N=26 impurities? εA=0.5 a) 20 b) 25 c) 19 d) 23

19 Impurities (solution)
How many perfect transmission (T=1) peaks do appear for 2N=26 impurities? εA=0.5

20 Impurities (solution)
How many perfect transmission (T=1) peaks do appear for 2N=26 impurities? εA=0.5 2N=26

21 Tying up to Kronig-Penney

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