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6 results on '"T. Basche"'

1. Single Molecule Spectroscopy : Nobel Conference Lectures

Author

R. Rigler, M. Orrit, T. Basche, R. Rigler, M. Orrit, and T. Basche

Subjects
Atoms, Molecules, Physical chemistry, Condensed matter, Spectrum analysis, Lasers, Measurement, Measuring instruments
Abstract

One often hears that nanoscience or, in other words, the knowledge and control of matter at length scales of a few nanometers, will be the scientific frontier of the 21st century. Although it has become almost commonplace, this prediction deserves some justification. The technological and scientific stakes of nanoscience indeed encompass many fields of science: they include the ultimate miniaturization of electronic devices to acquire, store, and process information, and also such basic endeavors as understanding the microscopic processes and patterns responsible for the physical properties of materials, or the many unsolved questions raised by the astoundingly intricate workings of living matter. Although the dream of observing and controlling matter at molecular scales is nearly as old as the very concept of molecules, earlier attempts at practical realizations were hampered by a scarcity of suitable access to the nanoworld. During the last two decades of the 20th century, owing to the several new tools which have been developed to address objects at nanometer scales, the nanoworld appears closer than ever, within our reach! A major class of methods in nanoscience are local probe microscopies such as scanning tunnelling or atomic force microscopies. They require scanning a sharp tip with molecular dimensions across the surface of the sample under study and, by direct action of the tip on the sample, they make nano-manipulations possible. The present book is devoted to another class of methods, the selection and study of single, optically active nano-objects by purely optical means.

Published
2012

3. Observation of Spectral Diffusion in Solids Using a Single Molecule

Author

W. P. Ambrose, T. Basche', and W. E. Moerner

Abstract

Recent advances in high-efficiency fluorescence excitation spectroscopy of pentacene in p-terphenyl crystals1-3 have improved the signal to noise ratio for the detection of single pentacene defects, thus confirming single pentacene detection using absorption techniques.4 Using 1-10 μm thick crystals, tightly focused laser beams, and high collection efficiency, background emission noise is significantly reduced below the fluorescence emission rate of single pentacene defects. To observe single molecules, the laser is tuned out into the wings of the pentacene O1 site inhomogeneous line until the number of defects per homogeneous linewidth is less than 1. With the improved detection sensitivity, we have observed two classes of pentacene defects present in both the red and blue wings of the inhomogeneous line: class I consist of stable, time-independent defects with lifetime limited homogeneous linewidths below 4 K, and class II have time varying resonance frequencies.

Published
1991

4. Novel physical phenomena in the optical spectroscopy of single molecules in a solid

Author

T. Basche, W. P. Ambrose, and W. E. Moerner

Abstract

As was recently demonstrated1 using highly efficient fluorescence excitation spectroscopy with N.A. = 0.98 collection optics, single molecules of pentacene in a p-terphenyl crystal can be detected with signal-to-noise ratios (SNR) as high as 30 in a 1 -Hz bandwidth at low temperatures. As a result, it has become possible to study the electronic absorption spectra of individual impurity molecules in solids in great detail. Our measurements include precise determination of the lifetime-limited linewidth and the temperature dependence of the optical dephasing, both of which agree with earlier measurements on large assemblies of molecules. Surprisingly, it was also found that some molecules absorbing in the wing of the inhomogeneous line change their absorption frequency with time in a random fashion. This spectral jumping behavior (which was quite unexpected in the crystalline p-terphenyl matrix but reminiscent of amorphous systems) is termed spectral diffusion and is thought to be caused by an instability in the local environment of the single pentacene absorbers that is driven by phonons present at 1.5 K. The experiments revealed that the jumps in frequency space in general are not restricted to occur between a small number of accessible states. In fact, the spectral diffusion processes observed are very rich and complex and range from discontinuous jumps between several states to quasicontinuous wandering in frequency space.

Published
1991

6. Three-dimensional orientational colocalization of individual donor--acceptor pairs.

Author

Hubner CG, Ksenofontov V, Nolde F, Mullen K, and Basche T

Abstract

We report on the determination of the three-dimensional orientation of the donor and acceptor transition dipoles in individual fluorescence resonance energy transfer (FRET) pairs by means of scanning optical microscopy with annular illumination. Knowledge of the mutual orientation of the donor and acceptor dipole is mandatory for reliable distance determination based on FRET efficiency measurements. In our model system perylenediimide as the donor and terryelenediimide as the acceptor are coupled via a stiff p-terphenyl linker. The absorption dipoles of the donor and acceptor are selectively addressed by the 488 nm and 647 line of an Ar/Kr mixed gas laser, respectively. A clear deviation from collinearity is observed with a distribution of misalignment angles peaked around 22 degrees.

Published
2004
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