Original publication

Matthias Mader, Jakob Reichel, Theodor W. Hänsch, and David Hunger
A Scanning Cavity Microscope
Nature Communications, DOI: 10.1038/ncomms8249, 24 June 2015.


Dr. David Hunger
Max Planck Institute of Quantum Optics,
Ludwig-Maximilians-Universität Munich
Schellingstr. 4 /III, 80799 Munich, Germany
Phone: +49 (0)89 / 21 80 -3937
E-mail:  david.hunger@physik.lmu.de

Prof. Dr. Theodor W. Hänsch
Professor of Experimental Physics
Ludwig-Maximilians-Universität Munich,
Direktor at the Max Planck Institute of Quantum Optics
Hans-Kopfermann-Str. 1
85748 Garching, Germany
Phone: +49 (0)89 / 32 905 -712
E-mail:  t.w.haensch@...

Dr. Olivia Meyer-Streng
Press & Public Relations
Max Planck Institute of Quantum Optics, Garching, Germany
Phone: +49 (0)89 / 32 905 -213
E-mail:  olivia.meyer-streng@...


A novel microscope for nanosystems

LMU/MPQ-scientists can image the optical properties of individual nanoparticles with a novel microscope.

June 24, 2015

Nanomaterials play an essential role in many areas of daily life. There is thus a large interest to gain detailed knowledge about their optical and electronic properties. Conventional microscopes get beyond their limits when particle size falls to the range of a few ten nanometers where a single particle provides only a vanishingly small signal. As a consequence, many investigations are limited to large ensembles of particles. Now, a team of scientists of the Laser Spectroscopy Division of Prof. Theodor W. Hänsch (Director at the Max Planck Institute of Quantum Optics and Chair for Experimental Physics at the Ludwig-Maximilians-Universität Munich) has developed a technique, where an optical microcavity is used to enhance the signals by more than 1000-fold and at the same time achieves an optical resolution close to the fundamental diffraction limit. The possibility to study the optical properties of individual nanoparticles or macromolecules promises intriguing potential for many areas of biology, chemistry, and nanoscience (Nature Communications, DOI: 10.1038/ncomms8249, 24 June 2015).

Spectroscopic measurements on large ensembles of nanoparticles suffer from the fact that individual differences in size, shape, and molecular composition are washed out and only average quantities can be extracted. There is thus a large interest to develop single-particle-sensitive techniques. “Our approach is to trap the probe light used for imaging inside of an optical resonator, where it circulates tens of thousands of times. This enhances the interaction between the light and the sample, and the signal becomes easily measurable”, explains Dr. David Hunger, one of the scientists working on the experiment. “For an ordinary microscope, the signal would be only a millionth of the input power, which is hardly measurable. Because of the resonator, the signal gets enhanced by a factor of 50000.”

In the microscope, built by Dr. David Hunger and his team, one side of the resonator is made of a plane mirror that serves at the same time as a carrier for the nanoparticles under investigation. The counterpart is a strongly curved mirror on the end facet of an optical fibre. Laser light is coupled into the resonator through this fibre. The plane mirror is moved point by point with respect to the fibre in order to bring the particle step by step into its focus. At the same time, the distance between both mirrors is adjusted such that the condition for the appearance of resonance modes is fulfilled. This requires an accuracy in the range of picometers.

Intuitive illustration of the new method for imaging nanoparticles. Zoom Image
Intuitive illustration of the new method for imaging nanoparticles.

For their first measurements, the scientists used gold spheres with a diameter of 40 nanometers. “The gold particles serve as our reference system, as we can calculate their properties precisely and therefore check the validity of our measurements” says David Hunger. “Since we know the optical properties of our measurement apparatus very accurately, we can determine the optical properties of the particles from the transmission signal quantitatively and compare it to the calculation”. In contrast to other methods relying on direct signal enhancement, the light field is limited to a very small area, such that by using only the fundamental mode, a spatial resolution of 2 micron is achieved. By combining higher order modes, the scientists could even increase the resolution to around 800 nanometers.

The method becomes even more powerful when both absorptive and dispersive properties of a single particle were determined at the same time. This is interesting especially if the particles are not spherical but e.g. elongated. Then, the corresponding quantities depend on the orientation of the polarization of light with respect to the symmetry axes of the particle. “In our experiment we use gold nanorods (34x25x25 nm³) and we observe how the resonance frequency shifts depending on the orientation of the polarization. If the polarization is oriented parallel to the axes of the rod, the shift of the resonance is larger than if the polarization is oriented orthogonally, resulting in two different resonance frequencies for both orthogonal polarizations” explains Matthias Mader, PhD student at the experiment. “This birefringence can be measured very precisely and is a very sensitive indicator for the shape and orientation of the particle.”

“As an application of our method, we could think of e.g. investigating the temporal dynamics of macro molecules, such as the folding dynamics of proteins” says David Hunger. “Overall we see a large potential for our method: from the characterization of nanomaterials and biological nanosystems to spectroscopy of quantum emitters.” Olivia Meyer-Streng

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