Scanning probe microscopes scan and manipulate a sharp tip in the immediate vicinity of a sample surface. The limited bandwidth of the feedback mechanism used for stabilizing the separation between the tip and the sample makes the fragile nanoscopic tip very susceptible to mechanical instabilities. We propose, demonstrate, and characterize an alternative device based on bulging a thin substrate against a second substrate and rolling them with respect to each other. We showcase the power of this method by placing gold nanoparticles and semiconductor quantum dots on the two opposite substrates and positioning them with nanometer precision to enhance the fluorescence intensity and emission rate. Furthermore, we exhibit the passive mechanical stability of the system over more than 1 h. Our design concept finds applications in a variety of other scientific and technological contexts, where nanoscopic features have to be positioned and kept near contact with each other. a thin substrate against a second substrate and rolling them with respect each other. We showcase the power of this method by placing gold nanoparticles and semiconductor quantum dots on the two opposite substrates and positioning them with nanometer precision to enhance the fluorescence intensity and emission rate. We exhibit the passive mechanical stability of the system over more than one hour. The design concept presented in this work holds promise in a variety of other contexts, where nanoscopic features have to be positioned and kept near contact with each other.
Deciphering a hexameric protein complex with Angstrom optical resolution
Cryogenic optical localization in three dimensions (COLD) was recently shown to resolve up to four binding sites on a single protein. However, because COLD relies on intensity fluctuations that result from the blinking behavior of fluorophores, it is limited to cases where individual emitters show different brightness. This significantly lowers the measurement yield. To extend the number of resolved sites as well as the measurement yield, we employ partial labeling and combine it with polarization encoding in order to identify single fluorophores during their stochastic blinking. We then use a particle classification scheme to identify and resolve heterogenous subsets and combine them to reconstruct the three-dimensional arrangement of large molecular complexes. We showcase this method (polarCOLD) by resolving the trimer arrangement of proliferating cell nuclear antigen (PCNA) and six different sites of the hexamer protein Caseinolytic Peptidase B (ClpB) of Thermus thermophilus in its quaternary structure, both with Angstrom resolution. The combination of polarCOLD and single-particle cryogenic electron microscopy (cryoEM) promises to provide crucial insight into intrinsic heterogeneities of biomolecular structures. Furthermore, our approach is fully compatible with fluorescent protein labeling and can, thus, be used in a wide range of studies in cell and membrane biology.
Precision size and refractive index analysis of weakly scattering nanoparticles in polydispersions
Anna D. Kashkanova,
Martin Blessing,
André Gemeinhardt,
Didier Soulat,
Vahid Sandoghdar
Characterization of the size and material properties of particles in liquid suspensions is in very high demand, for example, in the analysis of colloidal samples or of bodily fluids such as urine or blood plasma. However, existing methods are limited in their ability to decipher the constituents of realistic samples. Here we introduce iNTA as a new method that combines interferometric detection of scattering with nanoparticle tracking analysis to reach unprecedented sensitivity and precision in determining the size and refractive index distributions of nanoparticles in suspensions. After benchmarking iNTA with samples of colloidal gold, we present its remarkable ability to resolve the constituents of various multicomponent and polydisperse samples of known origin. Furthermore, we showcase the method by elucidating the refractive index and size distributions of extracellular vesicles from Leishmania parasites and human urine. The current performance of iNTA already enables advances in several important applications, but we also discuss possible improvements.
PiSCAT: A Python Package for Interferometric Scattering Microscopy
Houman Mirzaalian Dastjerdi,
Reza Gholami Mahmoodabadi,
Matthias Bär,
Vahid Sandoghdar,
Harald Köstler
The Journal of Open Source Software
7
(71)
4024
(2022)
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Interferometric scattering (iSCAT) microscopy allows one to image and track nano-objects with a nanometer spatial and microsecond temporal resolution over arbitrarily long measurement times (Lindfors et al., 2004; Taylor & Sandoghdar, 2019b, 2019a). A key advantage of this technique over the well-established fluorescence methods is the indefinite photostability of the scattering phenomenon in contrast to the photobleaching of fluorophores. This means that one can perform very long measurements. Moreover, scattering processes are linear and thus do not saturate. This leads to larger signals than is possible from a single fluorophore. As a result, one can image at a much faster rate than in fluorescence microscopy. Furthermore, the higher signal makes it possible to localize a nano-object with much better spatial precision. The remarkable sensitivity of iSCAT, however, also brings about the drawback that one obtains a rich speckle-like background from other nano-objects in the field of view.
High-resolution vibronic spectroscopy of a single molecule embedded in a
crystal
Johannes Zirkelbach,
Masoud Mirzaei,
Irena Deperasińska,
Boleslaw Kozankiewicz,
Burak Gürlek,
Alexey Shkarin,
Tobias Utikal,
Stephan Götzinger,
Vahid Sandoghdar
The Journal of Chemical Physics
156
104301
(2022)
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Vibrational levels of the electronic ground states in dye molecules have not been previously explored at a high resolution in solid matrices. We present new spectroscopic measurements on single polycyclic aromatic molecules of dibenzoterrylene embedded in an organic crystal made of para-dichlorobenzene. To do this, we use narrow-band continuous-wave lasers and combine spectroscopy methods based on fluorescence excitation and stimulated emission depletion to assess individual vibrational linewidths in the electronic ground state at a resolution of ∼30 MHz dictated by the linewidth of the electronic excited state. In this fashion, we identify several exceptionally narrow vibronic levels with linewidths down to values around 2 GHz. Additionally, we sample the distribution of vibronic wavenumbers, relaxation rates, and Franck–Condon factors, in both the electronic ground and excited states for a handful of individual molecules. We discuss various noteworthy experimental findings and compare them with the outcome of density functional theory calculations. The highly detailed vibronic spectra obtained in our work pave the way for studying the nanoscopic local environment of single molecules. The approach also provides an improved understanding of the vibrational relaxation mechanisms in the electronic ground state, which may help create long-lived vibrational states for applications in quantum technology.
Single photon sources for quantum radiometry: a brief review about the current state‑of‑the‑art
Stefan Kück,
Marco López,
Helmuth Hofer,
Hristina Georgieva,
Justus Christinck,
Beatrice Rodiek,
Geiland Porrovecchio,
Marek Smid,
Stephan Götzinger,
Christoph Becher,
Philipp Fuchs,
Pietro Lombardi,
Costanza Toninelli,
Marco Trapuzzano, et al.
Applied Physics B: Lasers and Optics
128
28
(2022)
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Single-photon sources have a variety of applications. One of these is quantum radiometry, which is reported on in this paper in the form of an overview, specifically of the current state of the art in the application of deterministic single photon sources to the calibration of single photon detectors. To optimize single-photon sources for this purpose, extensive research is currently carried out at the European National Metrology Institutes (NMIs), in collaboration with partners from universities. Single-photon sources of different types are currently under investigation, including sources based on defect centres in (nano-)diamonds, on molecules and on semiconductor quantum dots. We will present, summarise, and compare the current results obtained at European NMIs for single-photon sources in terms of photon flux, single-photon purity, and spectral power distribution as well as the results of single-photon detector calibrations carried out with this type of light sources.
Comparison of back focal plane imaging of nitrogen vacancy centers in nanodiamond and core-shell CdSe/CdS quantum dots
Justus Christinck,
Beatrice Rodiek,
Marco Lopez ,
Hristina Georgieva,
Stephan Götzinger,
Stefan Kück
Journal of Physics: Conference Series
2149
012014
(2022)
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We report on the characterization of the angular-dependent emission of two different single-photon emitters based on nitrogen-vacancy centers in nanodiamond and on core-shell CdSe/CdS quantum dot nanoparticles. The emitters were characterized in a confocal microscope setup by spectroscopy and Hanbury-Brown and Twiss interferometry. The angular-dependent emission is measured using a back focal plane imaging technique. A theoretical model of the angular emission patterns of the 2D dipoles of the emitters is developed to determine their orientation. Experiment and model agree well with each other.
Contact
Nano-Optics Division Prof. Vahid Sandoghdar
Max Planck Institute for the Science of Light Staudtstr. 2 91058 Erlangen, Germany
