Design of plasmonic probe tips to control light on the nanoscale for imaging and spectroscopy with ultrahigh spatial and temporal resolution
EMSL Project ID
40088
Abstract
The optical probing of matter with simultaneous nanometer spatial and femtosecond temporal resolution has remained a great challenge. Here, using focused ion beam milling we will tune the optical antenna properties of scanning probe tips to achieve a spatially confined optical excitation with desired frequency and temporal characteristics. This provides access to the dynamics of mesoscopic phenomena at the dimensions of the electron or phonon scattering length scales for the first time in, for example, molecular nanocomposites and transition metal oxides. In addition, the new ability to probe the near-field vector distribution of nanophotonic and plasmonic devices with nanometer resolution in 3D provides a much needed design tool, offering a high technological potential for optical antenna-coupled molecular sensors, biomedical diagnostics, optical waveguides, and switches.
Project Details
Project type
Large-Scale EMSL Research
Start Date
2010-10-01
End Date
2011-09-30
Status
Closed
Released Data Link
Team
Principal Investigator
Team Members
Related Publications
Berweger S, JM Atkin, RL Olmon, and BM Raschke. 2010. "Adiabatic Tip-Plasmon Focusing for Nano-Raman Spectroscopy." The Journal of Physical Chemistry Letters 1(24):3427–3432. doi:10.1021/jz101289z
Berweger S, JM Atkin, XG Xu, RL Olmon, and BM Raschke. 2011. "Femtosecond Nanofocusing with Full Optical Waveform Control." Nano Letters 11(10):4309–4313. doi:10.1021/nl2023299
Olmon RL, M Rang, PM Krenz, BA Lail, LV Saraf, GD Boreman, and BM Raschke. 2010. "Determination of Electric-Field, Magnetic-Field, and Electric-Current Distributions of Infrared Optical Antennas: A Near-Field Optical Vector Network Analyzer." Physical Review Letters 105(16):Article No.: 167403. doi:10.1103/PhysRevLett.105.167403
Olmon R L, Optical vector near-field imaging for the design of impedance matched optical antennas and devices, Dissertation, Department of Electrical Engineering, University of Washington (2012)