Our
ability to optically interrogate nanoscopic objects is controlled
by the difference between their extinction cross sections and the
diffraction-limited area to which light can be confined in the far
field. We show that a partially transmissive spatial mask placed near
the back focal plane of a high numerical aperture microscope objective
enhances the extinction contrast of a scatterer near an interface
by approximately T–1/2, where T is the transmissivity of the mask. Numerical-aperture-based
differentiation of background from scattered light represents a general
approach to increasing extinction contrast and enables routine label-free
imaging down to the single-molecule level.
Dark field microscopy directly detects scattering from a sample by rejecting excitation light. The technique has been extensively used for spectral characterization of nanoscopic particles, but its sensitivity has been limited by residual stray light. Here, we present a simple geometry based on wide field illumination under normal incidence capable of background suppression by more than seven orders of magnitude. The setup is optimized for spectrally resolved wide-field detection with white light illumination. We record images and spectra of single 10 nm gold particles binding to a functionalized surface, demonstrating a more than two orders of magnitude improvement in sensitivity over the current state of the art. Our level of stray light rejection allows us to record single molecule fluorescence images with broadband excitation without any filters in the detection path. The approach is ideally suited for investigations on truly nanoscopic objects with applications in single molecule and nanoparticle spectroscopy, plasmonic sensing, and ultrafast spectroscopy.
The structural organization of cellular membranes has an essential influence on their functionality. The membrane surfaces currently are considered to consist of various distinct patches, which play an important role in many processes, however, not all parameters such as size and distribution are fully determined. In this study, purple membrane (PM) patches isolated from Halobacterium salinarum were investigated in a first step using TERS (tip-enhanced Raman spectroscopy). The characteristic Raman modes of the resonantly enhanced component of the purple membrane lattice, the retinal moiety of bacteriorhodopsin, were found to be suitable as PM markers. In a subsequent experiment a single Halobacterium salinarum was investigated with TERS. By means of the PM marker bands it was feasible to identify and localize PM patches on the bacterial surface. The size of these areas was determined to be a few hundred nanometers.
Coherent control uses tailored femtosecond
pulse shapes to influence
quantum pathways and drive a light-induced process toward a specific
outcome. There has been a long-standing debate whether the absorption
properties or the probability for population to remain in an excited
state of a molecule can be influenced by the pulse shape, even if
only a single photon is absorbed. Most such experiments are performed
on many molecules simultaneously, so that ensemble averaging reduces
the access to quantum effects. Here, we demonstrate systematic coherent
control experiments on the fluorescence intensity of a single molecule
in the weak-field limit. We demonstrate that a delay scan of interfering
pulses reproduces the excitation spectrum of the molecule upon Fourier
transformation, but that the spectral phase of a pulse sequence does
not affect the transition probability. We generalize this result to
arbitrary pulse shapes by performing the first closed-loop coherent
control experiments on a single molecule.
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