EM scattering from semiconducting nanowires and nanocones

1. EM scattering from semiconducting nanowires and nanocones Vadim Karagodsky • Enhanced Raman scattering from individual semiconductor nanocones • and nanowires, L. Cao et al. and J. E. Spanier, Physical Review Letters, 96, • 157402 (2006) • On the Raman scattering from semiconducting nanowires, L. Cao, et al. and • J. E. Spanier, Journal of Raman Spectroscopy, 38, 697-703 (2007) • Electromagnetic scattering from long nanowires, M. E. Pellen et al. and P. C. • Eklund, Antennas and Propagation International Symposium, 2007 IEEE.

2. Motivation • Similarly to surface plasmon resonance in metallic particles and films, semiconducting nanowires are also demonstrated to provide intense resonant enhancement of visible EM light, and to be excellent scatterers. • The key factor is: subwavelength dimensions. Applications • Sensors and detectors • Couplers • Nano-antenna arrays

3. Backscattering experiment Si nanocones / Si nanowires / c-Si(100) wafer (bulk) Laser polarization: TM and TE “Nano”-wires (too large): 130nm < diameter < ~1m “Nano”-cones: <5nm  = 0.12rad ~25m

4. Backscattered intensity 632.8 nm (diameter~250nm) 5 times larger than bulk (near the base) twice as large as bulk

5. Backscattering enhancement – 632.8 nm Raman Enhancement (RE) = [Inw/Vnw]/[Ibulk/Vbulk] I = scattered intensity; V = probed volume • RE=250~300 at the • nanocone tip. • RE~800 for the 130nm • nanowire. • Good agreement between • nanowires and nanocones. • Small but reproducible • differences between TM • and TE

6. Backscattering experiment - wavelength dependence • The RE increases • with wavelength. • Qualitative reason: • The enhancement • is controlled by the • ratio: • diameter/wavelength

7. Theoretical Model Plane wave / infinite cylinder E-field inside the cylinder Definition of average intensity Avg. intensity inside the cylinder

8. RE as a Quality factor - comparison with experiment Qint=Iint,nw/Ibulk Qscat~Qint RE=QRaman~QintQscat~Qint2 • Reasonable agreement between • theory and experiment • The calculated values are • consistently lower. • The undulations are not • observed. Suggested reason: • Period of undulations: ~70nm • Diameter variation across the • laser spot: ~170nm.

9. Theoretical Model - calculation results • Normalized units reveal • wavelength insensitivity • for small diameters • The nanowire can be designed • for TM/TE mode selectivity

10. FDTD simulation - GaP nanowire (polarization dependence) E-field – TM: E-Field – TE:

11. Conclusions • The Raman enhancement depends on the • diameter, wavelength and polarization. • For small diameters the enhancement over bulk is • up to 3 orders of magnitude, due to resonant • scattering. • Reasonable agreement between theory and • experiment. • The efficient radiation coupling to Si is good for • photonic and sensing properties of Si and Si-based • nanostructures.

12. Suggestions for improvement: • Measure the entire scattered spectrum – the • enhancement is not necessarily Raman related. • Normalize by scattering cross-section instead of • probed volume. • Revise the Q-factor model for the intensity • enhancement. Thank you