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Single wire laser ’ #5 C‘ Optical characterization

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1 Single wire laser ’3-30-01.1 #5 C‘ Optical characterization
’05 10/25 For Akiyama Group members Single wire laser ’ #5 C‘ Optical characterization Toshiyuki Ihara For a further investigation of single wire laser, I measured optical features such as PL, PLE and absorption/gain spectra by Haaki & Paoli method. 4 : Sample structure and experimental setup 5 : Perpendicular PL scan 6-7 : PLE by reflection geometry and waveguide emission 8-12 : Point excitation Hakki and Paoli ~ excitation energy and spot position dependence 13-16 : Stripe excitation lasing / gain spectra

2 Sample structure of single wire laser
Calculation results Wire hw = meV (1st e/h meV) core Arm hw = meV (1st e/h meV) clad Arm hw = meV Stem hw = meV (1st e/h meV) waveguide hw = meV (1st e/h meV)

3 Reflection / perpendicular geometory for low power excitation (micro-PL / PLE)

4 Waveguide emission detection geometry for high power excitation (Lasing / Image)

5 Perpendicular PL scan from cap to substrate
- Emission from the stem well is strongly polarized to [001] direction ⊥det //det

6 PL and PLE by reflection geometry
- Clear : Wireex./cont. & clad/coreArmHH & Waveguide (drift into Wire!) - Unclear : clad/coreArmLH & StemLH/HH (drift into Wire?) ⊥ex //ex

7 PLE ~ Wire Waveguide emission probe
- Clear peaks of wire Ground / excited / continuum state is observed. - Absorption intensity is not correct (due to the Fabry-Perot Fringe?). ⊥ex //ex

8 Point excitation Haaki & Paoli
excitation energy Eex = 1.639eV (stem resonance) - At the excitation energy of 1.639eV (stem resonance), a clear absorption spectrum is obtained !!

9 Point excitation Hakki & Paoli ~ low energy excitation case
- Scattered laser leads to excess carriers on whole region of the wire !!

10 Point excitation Hakki & Paoli ~ high energy excitation case
- Waveguide absorption results in the formation of trion state on the whole wire region !!

11 Point excitation Hakki & Paoli ~ spot position dependence
- Although the waveguide emission depends on the excitation spot position, the obtained absorption spectra by Hakki and Paoli method are almost same ! ※S/N ratio depends on the position largely !

12 Point excitation Hakki & Paoli ~ detection polarizer importance

13 Waveguide emission (& lasing) by Stripe excitation
spectrum -L2 and L3 lasing are observed Image Select Arm polarization by polarizer Image of L2 and L3 lasing Image of L1,2 lasing

14 Carrier density dependence of gain spectra (Parm detection)
-Evolution from excitonic absorptions to L1 / L2 gain was observed !!

15 Carrier density dependence of gain spectra (Pstem detection)
-It is hard to observe the absorption feature of stem polarization on single wire laser.

16 Various L2 lasing energy (Excitation energy dependence)
-The energy of L2 lasing changes gradually with the excitation energy (carrier density ?) !!

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