In the laser excitation of ultracold atoms to Rydberg states, we observe a dramatic suppression caused by van der Waals interactions. This behavior is interpreted as a local excitation blockade: Rydberg atoms strongly inhibit excitation of their neighbors. We measure suppression, relative to isolated atom excitation, by up to a factor of 6.4. The dependence of this suppression on both laser irradiance and atomic density are in good agreement with a mean-field model. These results are an important step towards using ultracold Rydberg atoms in quantum information processing.PACS numbers: 32.80. Rm, 03.67.Lx, 34.20.Cf The possibility of a computer that operates according to the principles of quantum mechanics has attracted growing interest from a variety of research fields [1,2]. A number of possible implementations are being investigated, including solid-state systems, nuclear magnetic resonance, cavity quantum electrodynamics, trapped dipolar molecules, trapped ions, and trapped neutral atoms. A key element to any successful system is the ability to control the coherent interactions between the fundamental building blocks (qubits). Highly-excited Rydberg atoms with principal quantum numbers n 30 have the advantage that they interact quite strongly with each other, allowing information to be exchanged quickly [3]. Here we report an important advance towards using ultracold Rydberg atoms in quantum computing. We observe that the laser excitation of a macroscopic sample of ultracold atoms to high-lying Rydberg states can be dramatically suppressed by their strong long-range interactions. This leads to a local blockade effect, where the excitation of one atom prevents excitation of its neighbors. Our observations agree well with a model based on mean-field interactions.In a high-n Rydberg state, the electron spends most of its time quite far from the nucleus [4]. As a result, the energy of this highly-excited state is very sensitive to external perturbations, including those caused by neighboring Rydberg atoms. A system of two ultracold Rydberg atoms, subject to these long-range interactions, has been proposed as a possible realization of a quantum logic gate [3,5]. Rydberg states combine the advantages of long radiative lifetimes and strong long-range interactions, allowing information to be exchanged before decoherence sets in, even when the atoms are sufficiently separated to allow individual addressing. If the atoms are ultracold, they can be highly localized, e.g., in the sites of an optical lattice, allowing control of their interactions and efficient detection of their quantum state. An outstanding challenge is the assurance that at most a single Rydberg atom is produced at a given site. Towards this end, the concept of an excitation blockade has been proposed [6,7]. With multiple atoms occupying a sufficiently localized site, the strong Rydberg-Rydberg interactions allow at most one Rydberg excitation. Further excitations are blocked by the large energy level shifts that push the resonant frequencies outsi...
Neurofibrillary degeneration is an important pathological finding in senile and presenile dementia of the Alzheimer type. Experimentally, aluminum induces neurofibrillary degeneration in neurons of higher mammals. Aluminum concentrations approaching those used experimentally have been found in some regions of the brains of patients with Alzheimer's disease.
Helium nanodroplets are widely used as a cold, weakly interacting matrix for spectroscopy of embedded species. In this work, we excite or ionize doped He droplets using synchrotron radiation and study the effect onto the dopant atoms depending on their location inside the droplets (rare gases) or outside at the droplet surface (alkali metals). Using photoelectron-photoion coincidence imaging spectroscopy at variable photon energies (20-25 eV), we compare the rates of charge-transfer to Penning ionization of the dopants in the two cases. The surprising finding is that alkali metals, in contrast to the rare gases, are efficiently Penning ionized upon excitation of the (n = 2)-bands of the host droplets. This indicates rapid migration of the excitation to the droplet surface, followed by relaxation, and eventually energy transfer to the alkali dopants.
Aluminium is neurotoxic and results in the proliferation of 100 A diameter filaments in the cytoplasm of certain neurons. The aluminium concentration for 7 normal human brains was 1-9 +/- 0-7 SD mug/g dry weight (n = 208 samples). The aluminium content of 585 areas sampled in 10 post-mortem cases of Alzheimer's disease ranging in age from 50 to 88 years, in which the diagnosis was based on the specific histological appearances, revealed an elevated aluminium content in some regions. A range of 0-4 - 107-0 mug/g was encountered and 28 per cent of all regions sampled had concentrations in excess of 4 mug/g. Five of 6 cerebral biopsies from patients with Alzheimer's disease also had elevated aluminium content. In 2 additional Alzheimer's brains with neurofibrillary degeneration restricted to certain anatomical areas, elevated aluminium content was found to be associated with neurofibrillary degeneration and not with senile plaques. Furthermore, elevated aluminium content in multiple cortical regions was not found in 2 vascular dementias of the elderly. While the cytotoxic concentration for human neurons is unknown, the cytotoxic concentration for cat's cerebral neurons appears to lie between 4 and 6 mug/g dry weight.
We present evidence for molecular resonances in a cold dense gas of rubidium Rydberg atoms. Single UV photon excitation from the 5s ground state to np Rydberg states (n=50-90) reveals resonances at energies corresponding to excited atom pairs (n-1)d+ns. We attribute these normally forbidden transitions to avoided crossings between the long-range molecular potentials of two Rydberg atoms. These strong van der Waals interactions result in avoided crossings at extremely long range, e.g., approximately 58 000 times the Bohr radius (a(0)) for n=70.
Nanostructured carbons are posited to offer an alternative to silicon and lead to further miniaturization of photonic and electronic devices. Here, we report the experimental realization of the first all-carbon solid-state optical diode that is based on axially asymmetric nonlinear absorption in a thin saturable absorber (graphene) and a thin reverse saturable absorber (C60) arranged in tandem. This all-optical diode action is polarization independent and has no phase-matching constraints. The nonreciprocity factor of the device can be tuned by varying the number of graphene layers and the concentration or thickness of the C60 coating. This ultracompact graphene/C60 based optical diode is versatile with an inherently large bandwidth, chemical and thermal stability, and is poised for cost-effective large-scale integration with existing fabrication technologies.
Helium nanodroplets irradiated by intense near-infrared laser pulses ignite and form highly ionized nanoplasmas even at laser intensities where helium is not directly ionized by the optical field, provided the droplets contain a few dopant atoms. We present a combined theoretical and experimental study of the He nanoplasma ignition dynamics for various dopant species. We find that the efficiency of dopants to ignite a nanoplasma in helium droplets strongly varies and mostly depends on (i) the number of free electrons each dopant donates upon ionization, (ii) the pick-up process, and (iii) the hitherto unexplored effect of the dopant location in or on the droplet.
We report the observation of electron-transfer-mediated decay (ETMD) involving magnesium (Mg) clusters embedded in helium (He) nanodroplets. ETMD is initiated by the ionization of He followed by removal of two electrons from the Mg clusters of which one is transferred to the He ion while the other electron is emitted into the continuum. The process is shown to be the dominant ionization mechanism for embedded clusters for photon energies above the ionization potential of He. For Mg clusters larger than five atoms we observe stable doubly ionized clusters. Thus, ETMD provides an efficient pathway to the formation of doubly ionized cold species in doped nanodroplets.
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