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Coherent spectroscopy Kevin Crampton Alex Fast Alba Alfonso-Garcia Christopher Syme Ara Apkarian Eric O. Potma in the single molecule limit.

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Presentation on theme: "Coherent spectroscopy Kevin Crampton Alex Fast Alba Alfonso-Garcia Christopher Syme Ara Apkarian Eric O. Potma in the single molecule limit."— Presentation transcript:

1 Coherent spectroscopy Kevin Crampton Alex Fast Alba Alfonso-Garcia Christopher Syme Ara Apkarian Eric O. Potma in the single molecule limit

2 1. plasmonics2. EM force Talking optically to a single molecule

3 Confinement in 1 dimension: Surface plasmon polariton 30 nm Au film 11 22 33 44

4 Confinement in 1 dimension: Surface plasmon polariton Coherent FWM process can be driven by surface plasmon mode Liu et al., Opt. Lett. 36, 2348-2350 (2011).

5 Wide-field SE-CARS ON 2880 cm -1 OFF 2762 cm -1 11 22 Au glass angle = 42.8 o Au glass angle = 42.0 o Au

6 Confinement in 3D: Localized surface plasmon 160017001800 Wavenumber (cm -1 )

7 Electronic and vibrational SERS 532 nm 633 nm

8 Ultrafast illumination: damage fs laser on Peak power limit: 10 12 W/cm 2 CN stretch

9 CARS versus Raman (single molecules) 2 X = Spontaneous X = SRS as-Raman 11 22 33 44

10 CARS versus Raman (single molecules) 2 X = SRS as-Raman 11 22 33 44 SRS step Raman step saturated!

11 Surface-enhanced CARS: colors Instantaneous thermal loading needs to be avoided Single dipolar mode excitation, avoid excitation of multi-modes 11 22 33 44

12 SE-CARS and SERS (frequency domain)

13 SE-CARS (time domain)  vib 11 22 33 44 τ 160017001800 Wavenumber (cm -1 ) Yampolsky et al, Nat. Photon. 8, 650- 656 (2014)

14 Time-resolved SE-CARS ensemble ‘single’ 15501600 1650 Wavenumber (cm -1 )

15 Non-optical detection: near-field force

16 f 01 f m = f 02  Topography PiFM f 01 f 02

17 PiFM: visualizing near-field Au J. Jahng et al, Opt. Lett., 40, 5059 (2015)

18 PiFM: visualizing near-field PiFM amplitude (a.u) 5um

19 PiFM of molecules: optical binding force

20 Spectroscopic imaging at the nanoscale

21 Nanoscopic imaging with PiFM Topography PiFM z = 18 nm z = 5 nm Jahng et al., Acc. Chem. Res. 48, 2671-2679 (2015).

22 Pump-probe with force detection

23 Time-resolved pump-probe at nanoscale

24 Take home messages Optimized excitation of antenna-equipped molecules enables SE-CARS. SE-CARS in the single molecule limit reveals information not directly accessible in ensemble measurements. PiFM offers a non-optical detection scheme for absorption and pump-probe measurements in the few molecule limit. Gracias.

25 CARS versus Raman (single molecules) 2 X = Spontaneous X = SRS as-Raman 11 22 33 44

26 CARS versus Raman (single molecules) X = SRS as-Raman CARS Raman = s-Raman SE-CARS ~ SERS when stimulated (SRS) step is saturated

27 Raman saturation? Depletion of Raman gain by SRS saturation in bulk liquid Silva, Graefe & Frontiera, ACS Photonics 3(1), 79-86 (2016) Saturation achieved for peak powers << 10 12 W/cm 2

28

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