Narain Karedla scite author profile

Inorganic carbon nanomaterials, also called carbon nanodots, exhibit a strong photoluminescence with unusual properties and, thus, have been the focus of intense research. Nonetheless, the origin of their photoluminescence is still unclear and the subject of scientific debates. Here, we present a single particle comprehensive study of carbon nanodot photoluminescence, which combines emission and lifetime spectroscopy, defocused emission dipole imaging, azimuthally polarized excitation dipole scanning, nanocavity-based quantum yield measurements, high resolution transmission electron microscopy, and atomic force microscopy. We find that photoluminescent carbon nanodots behave as electric dipoles, both in absorption and emission, and that their emission originates from the recombination of photogenerated charges on defect centers involving a strong coupling between the electronic transition and collective vibrations of the lattice structure.

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Enhanced dimerization drives ligand-independent activity of mutant epidermal growth factor receptor in lung cancer

Valley

Arndt‐Jovin

Karedla

et al. 2015

MBoC

100

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Graphene-based metal-induced energy transfer for sub-nanometre optical localization

et al. 2019

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Axial Colocalization of Single Molecules with Nanometer Accuracy Using Metal-Induced Energy Transfer

et al. 2018

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Single-molecule localization based super-resolution microscopy has revolutionized optical microscopy and routinely allows for resolving structural details down to a few nanometers. However, there exists a rather large discrepancy between lateral and axial localization accuracy, the latter typically three to five times worse than the former. Here, we use single-molecule metal-induced energy transfer (smMIET) to localize single molecules along the optical axis, and to measure their axial distance with an accuracy of 5 nm. smMIET relies only on fluorescence lifetime measurements and does not require additional complex optical setups.

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Single‐Molecule Metal‐Induced Energy Transfer (smMIET): Resolving Nanometer Distances at the Single‐Molecule Level

et al. 2014

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We present a new concept for measuring distance values of single molecules from a surface with nanometer accuracy using the energy transfer from the excited molecule to surface plasmons of a metal film. We measure the fluorescence lifetime of individual dye molecules deposited on a dielectric spacer as a function of a spacer thickness. By using our theoretical model, we convert the lifetime values into the axial distance of individual molecules. Similar to Förster resonance energy transfer (FRET), this allows emitters to be localized with nanometer accuracy, but in contrast to FRET the distance range at which efficient energy transfer takes place is an order of magnitude larger. Our technique can be potentially used as a tool for measuring intramolecular distances of biomolecules and complexes.

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Dead-time correction of fluorescence lifetime measurements and fluorescence lifetime imaging

et al. 2016

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We present a comprehensive theory of dead-time effects on Time-Correlated Single Photon Counting (TCSPC) as used for fluorescence lifetime measurements, and develop a correction algorithm to remove these artifacts. We apply this algorithm to fluorescence lifetime measurements as well as to Fluorescence Lifetime Imaging Microscopy (FLIM), where rapid data acquisition is necessarily connected with high count rates. There, dead-time effects cannot be neglected, and lead to distortions in the observed lifetime image. The algorithm is quite general and completely independent of the particular nature of the measured signal. It can also be applied to any other single-event counting measurement with detector and/or electronics dead-time.

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Cell–Substrate Dynamics of the Epithelial-to-Mesenchymal Transition

et al. 2017

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The biological process of the epithelial-to-mesenchymal transition (EMT) allows epithelial cells to enhance their migratory and invasive behavior and plays a key role in embryogenesis, fibrosis, wound healing, and metastasis. Among the multiple biochemical changes from an epithelial to a mesenchymal phenotype, the alteration of cellular dynamics in cell-cell as well as cell-substrate contacts is crucial. To determine these variations over the whole time scale of the EMT, we measure the cell-substrate distance of epithelial NMuMG cells during EMT using our newly established metal-induced energy transfer (MIET) microscopy, which allows one to achieve nanometer axial resolution. We show that, in the very first hours of the transition, the cell-substrate distance increases substantially, but later in the process after reaching the mesenchymal state, this distance is reduced again to the level of untreated cells. These findings relate to a change in the number of adhesion points and will help to better understand remodeling processes associated with wound healing, embryonic development, cancer progression, or tissue regeneration.

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Charge-Driven Fluorescence Blinking in Carbon Nanodots

Khan

Karedla

et al. 2017

J. Phys. Chem. Lett.

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This study focuses on the mechanism of fluorescence blinking of single carbon nanodots, which is one of their key but less understood properties. The results of our single-particle fluorescence study show that the mechanism of carbon nanodots blinking has remarkable similarities with that of semiconductor quantum dots. In particular, the temporal behavior of carbon nanodot blinking follows a power law both at room and at cryogenic temperatures. Our experimental data suggest that static quenching via Dexter-type electron transfer between surface groups of a nanoparticle plays a major role in the transition of carbon nanodots to off or gray states, whereas the transition back to on states is governed by an electron tunneling from the particle's core. These findings advance our understanding of the complex mechanism of carbon nanodots emission, which is one of the key steps for their application in fluorescence imaging.

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Narain Karedla

Photoluminescence of Carbon Nanodots: Dipole Emission Centers and Electron–Phonon Coupling

Enhanced dimerization drives ligand-independent activity of mutant epidermal growth factor receptor in lung cancer

Graphene-based metal-induced energy transfer for sub-nanometre optical localization

Axial Colocalization of Single Molecules with Nanometer Accuracy Using Metal-Induced Energy Transfer

Single‐Molecule Metal‐Induced Energy Transfer (smMIET): Resolving Nanometer Distances at the Single‐Molecule Level

Dead-time correction of fluorescence lifetime measurements and fluorescence lifetime imaging

Cell–Substrate Dynamics of the Epithelial-to-Mesenchymal Transition

Charge-Driven Fluorescence Blinking in Carbon Nanodots

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