15 research outputs found
Coherent Electron-Phonon Coupling in Tailored Quantum Systems
The coupling between a two-level system and its environment leads to
decoherence. Within the context of coherent manipulation of electronic or
quasiparticle states in nanostructures, it is crucial to understand the sources
of decoherence. Here, we study the effect of electron-phonon coupling in a
graphene and an InAs nanowire double quantum dot. Our measurements reveal
oscillations of the double quantum dot current periodic in energy detuning
between the two levels. These periodic peaks are more pronounced in the
nanowire than in graphene, and disappear when the temperature is increased. We
attribute the oscillations to an interference effect between two alternative
inelastic decay paths involving acoustic phonons present in these materials.
This interpretation predicts the oscillations to wash out when temperature is
increased, as observed experimentally.Comment: 11 pages, 4 figure
Electrical generation and absorption of phonons in carbon nanotubes
The interplay between discrete vibrational and electronic degrees of freedom
directly influences the chemical and physical properties of molecular systems.
This coupling is typically studied through optical methods such as
fluorescence, absorption, and Raman spectroscopy. Molecular electronic devices
provide new opportunities for exploring vibration-electronic interactions at
the single molecule level. For example, electrons injected from a scanning
tunneling microscope tip into a metal can excite vibrational excitations of a
molecule in the gap between tip and metal. Here we show how current directly
injected into a freely suspended individual single-wall carbon nanotube can be
used to excite, detect, and control a specific vibrational mode of the
molecule. Electrons inelastically tunneling into the nanotube cause a
non-equilibrium occupation of the radial breathing mode, leading to both
stimulated emission and absorption of phonons by successive electron tunneling
events. We exploit this effect to measure a phonon lifetime on the order of 10
nanoseconds, corresponding to a quality factor well over 10000 for this
nanomechanical oscillator.Comment: 17 pages, 4 figure
Franck-Condon blockade in suspended carbon nanotube quantum dots
Understanding the influence of vibrational motion of the atoms on electronic
transitions in molecules constitutes a cornerstone of quantum physics, as
epitomized by the Franck-Condon principle of spectroscopy. Recent advances in
building molecular-electronics devices and nanoelectromechanical systems open a
new arena for studying the interaction between mechanical and electronic
degrees of freedom in transport at the single-molecule level. The tunneling of
electrons through molecules or suspended quantum dots has been shown to excite
vibrational modes, or vibrons. Beyond this effect, theory predicts that strong
electron-vibron coupling dramatically suppresses the current flow at low
biases, a collective behaviour known as Franck-Condon blockade. Here we show
measurements on quantum dots formed in suspended single-wall carbon nanotubes
revealing a remarkably large electron-vibron coupling and, due to the high
quality and unprecedented tunability of our samples, admit a quantitative
analysis of vibron-mediated electronic transport in the regime of strong
electron-vibron coupling. This allows us to unambiguously demonstrate the
Franck-Condon blockade in a suspended nanostructure. The large observed
electron-vibron coupling could ultimately be a key ingredient for the detection
of quantized mechanical motion. It also emphasizes the unique potential for
nanoelectromechanical device applications based on suspended graphene sheets
and carbon nanotubes.Comment: 7 pages, 3 figure
Characterization of Leishmania donovani Aquaporins Shows Presence of Subcellular Aquaporins Similar to Tonoplast Intrinsic Proteins of Plants
Leishmania donovani, a protozoan parasite, resides in the macrophages of the mammalian host. The aquaporin family of proteins form important components of the parasite-host interface. The parasite-host interface could be a potential target for chemotherapy. Analysis of L. major and L. infantum genomes showed the presence of five aquaporins (AQPs) annotated as AQP9 (230aa), AQP putative (294aa), AQP-like protein (279aa), AQP1 (314aa) and AQP-like protein (596aa). We report here the structural modeling, localization and functional characterization of the AQPs from L. donovani. LdAQP1, LdAQP9, LdAQP2860 and LdAQP2870 have the canonical NPA-NPA motifs, whereas LdAQP putative has a non-canonical NPM-NPA motif. In the carboxyl terminal to the second NPA box of all AQPs except AQP1, a valine/alanine residue was found instead of the arginine. In that respect these four AQPs are similar to tonoplast intrinsic proteins in plants, which are localized to intracellular organelles. Confocal microscopy of L. donovani expressing GFP-tagged AQPs showed an intracellular localization of LdAQP9 and LdAQP2870. Real-time PCR assays showed expression of all aquaporins except LdAQP2860, whose level was undetectable. Three-dimensional homology modeling of the AQPs showed that LdAQP1 structure bears greater topological similarity to the aquaglyceroporin than to aquaporin of E. coli. The pore of LdAQP1 was very different from the rest in shape and size. The cavity of LdAQP2860 was highly irregular and undefined in geometry. For functional characterization, four AQP proteins were heterologously expressed in yeast. In the fps1Δ yeast cells, which lacked the key aquaglyceroporin, LdAQP1 alone displayed an osmosensitive phenotype indicating glycerol transport activity. However, expression of LdAQP1 and LdAQP putative in a yeast gpd1Δ strain, deleted for glycerol production, conferred osmosensitive phenotype indicating water transport activity or aquaporin function. Our analysis for the first time shows the presence of subcellular aquaporins and provides structural and functional characterization of aquaporins in Leishmania donovani
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Nanophononics: State of the art and perspectives
Understanding and controlling vibrations in condensed matter is emerging as an essential necessity both at fundamental level and for the development of a broad variety of technological applications. Intelligent design of the band structure and transport properties of phonons at the nanoscale and of their interactions with electrons and photons impact the efficiency of nanoelectronic systems and thermoelectric materials, permit the exploration of quantum phenomena with micro- and nanoscale resonators, and provide new tools for spectroscopy and imaging. In this colloquium we assess the state of the art of nanophononics, describing the recent achievements and the open challenges in nanoscale heat transport, coherent phonon generation and exploitation, and in nano- and optomechanics. We also underline the links among the diverse communities involved in the study of nanoscale phonons, pointing out the common goals and opportunities