PRF nugget - Gordon

results in Raman scattering [an inelastic process] where some of the light leaving the surface has less energy; if one detects ...
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Near-Field Vibrational Spectroscopy and Imaging of Chemical Species on Nanoparticles during Catalytic (de)Hydrogenation Michael J. Gordon, Dept. of Chemical Engineering University of California, Santa Barbara Interaction of laser light with free electrons in metallic nanostructures (also known as plasmonics) can be used to focus optical fields to dimensions far below the diffraction limit. These spatially-confined optical fields can be used to excite and detect molecular vibrations of chemical species on a surface when the field-enhancing optical antenna or “tip” is brought in close proximity (few nm). Excitation of molecular bonds by the probe light results in Raman scattering [an inelastic process] where some of the light leaving the surface has less energy; if one detects this energy deficit, chemical species on the surface can be unambiguously identified at nanoscale spatial resolutions. In this work, we combine near-field vibrational spectroscopy with plasma-based synthesis of nanoparticles (Pd, Pt, and Pt alloys) to investigate reaction mechanisms on nanoscale catalytic materials. Plasmonic coupling causes “enhanced” Raman scattering

laser light

Rayleigh scattering (elastic)

80

(a)simulation

70

Au tip

Raman scattering

60 50

inelastic = chemical info

40

E

30

k

optical field laser light

Microplasma synthesis of catalytic nanoparticles

z

enhancement

Enhanced vibrational signature of graphitic species on substrate surface

20

2 nm 10

x

glass substrate

16.3 nm

Pd nanoparticles

3200

Intensity (counts)

optical antenna

experiment

graphitic carbon

3000

G-band D-band

2800

tip engaged

2600 tip 1 µm away

2400 2200 500

1000

1500

2000 -1

Raman shift (cm )

1 mm

0.0 nm σ = 1.86 x 10 particles/cm