218 research outputs found
Sub-cycle time resolution of multi-photon momentum transfer in strong-field ionization
During multi-photon ionization of an atom it is well understood how the
involved photons transfer their energy to the ion and the photoelectron.
However, the transfer of the photon linear momentum is still not fully
understood. Here, we present a time-resolved measurement of linear momentum
transfer along the laser pulse propagation direction. Beyond the limit of the
electric dipole approximation we observe a time-dependent momentum transfer. We
can show that the time-averaged photon radiation pressure picture is not
generally applicable and the linear momentum transfer to the photoelectron
depends on the ionization time within the electromagnetic wave cycle using the
attoclock technique. We can mostly explain the measured linear momentum
transfer within a classical model for a free electron in a laser field.
However, corrections are required due to the interaction of the outgoing
photoelectron with the parent ion and due to the initial momentum when the
electron appears in the continuum. The parent ion interaction induces a
measurable negative attosecond time delay between the appearance in the
continuum of the electron with minimal linear momentum transfer and the point
in time with maximum ionization rate
Distributed Optimization of District Heating Networks Using Optimality Condition Decomposition
The optimal operation of District Heating Networks (DHNs) is a challenging task. Current or future optimal dispatch energy management systems attempt to optimize objectives, such as monetary cost minimization, emission reduction, or social welfare maximization. Typically, this requires highly nonlinear models and has a substantial computational cost, especially for large DHNs. Consequently, it is difficult to solve the resulting nonlinear programming problem in real time. In particular, as typical applications allow for no more than several minutes of computation time. However, a distributed optimization approach may provide real time performance. Thereby, the solution of the central optimization problem is obtained by solving a set of small-scale, coupled optimization problems in parallel. At runtime, information is exchanged between the small-scale problems during the iterative solution procedure. A well-known approach of this class of distributed optimization algorithms is Optimality Condition Decomposition (OCD). Important advantages of this approach are the low amount of information exchange needed between the small-scale problems and that it does not require the tuning of parameters, which can be challenging. However, the DHNs model equation structure brings along many difficulties that hamper the application of the OCD approach. Simulation results demonstrate the applicability range of the presented method
Tunneling Time in Ultrafast Science is Real and Probabilistic
We compare the main competing theories of tunneling time against experimental
measurements using the attoclock in strong laser field ionization of helium
atoms. Refined attoclock measurements reveal a real and not instantaneous
tunneling delay time over a large intensity regime, using two different
experimental apparatus. Only two of the theoretical predictions are compatible
within our experimental error: the Larmor time, and the probability
distribution of tunneling times constructed using a Feynman Path Integral (FPI)
formulation. The latter better matches the observed qualitative change in
tunneling time over a wide intensity range, and predicts a broad tunneling time
distribution with a long tail. The implication of such a probability
distribution of tunneling times, as opposed to a distinct tunneling time,
challenges how valence electron dynamics are currently reconstructed in
attosecond science. It means that one must account for a significant
uncertainty as to when the hole dynamics begin to evolve.Comment: 11 pages, 4 figure
Early Acquisition of Neural Crest Competence During hESCs Neuralization
Background:
Neural crest stem cells (NCSCs) are a transient multipotent embryonic cell population that represents a defining characteristic of vertebrates. The neural crest (NC) gives rise to many derivatives including the neurons and glia of the sensory and autonomic ganglia of the peripheral nervous system, enteric neurons and glia, melanocytes, and the cartilaginous, bony and connective tissue of the craniofacial skeleton, cephalic neuroendocrine organs, and some heart vessels.
Methodology/Principal Findings:
We present evidence that neural crest (NC) competence can be acquired very early when human embryonic stem cells (hESCs) are selectively neuralized towards dorsal neuroepithelium in the absence of feeder cells in fully defined conditions. When hESC-derived neurospheres are plated on fibronectin, some cells emigrate onto the substrate. These early migratory Neural Crest Stem Cells (emNCSCs) uniformly upregulate Sox10 and vimentin, downregulate N-cadherin, and remodel F-actin, consistent with a transition from neuroepithelium to a mesenchymal NC cell. Over 13% of emNCSCs upregulate CD73, a marker of mesenchymal lineage characteristic of cephalic NC and connexin 43, found on early migratory NC cells. We demonstrated that emNCSCs give rise in vitro to all NC lineages, are multipotent on clonal level, and appropriately respond to developmental factors. We suggest that human emNCSC resemble cephalic NC described in model organisms. Ex vivo emNCSCs can differentiate into neurons in Ret.k- mouse embryonic gut tissue cultures and transplanted emNCSCs incorporate into NC-derived structures but not CNS tissues in chick embryos.
Conclusions/Significance:
These findings will provide a framework for further studying early human NC development including the epithelial to mesenchymal transition during NC delamination
Unexpected enhancement of enantioselectivity in copper(II) catalyzed conjugate addition of diethylzinc to cyclic enones with novel TADDOL phosphorus amidite ligands
The copper(II) catalyzed enantioselective 1,4-addition reactions of diethylzinc to cyclic enones in the presence of novel phosphorus amidite ligands, easily prepared from α,α,α',α'-tetraphenyl-2,2'-dimethyl-1,3-dioxolane-4,5-dimethanol (TADDOL) derivatives, resulted in e.e.s up to 71% for cyclohexenone and up to 62% for cyclopentenone. A remarkable enhancement of enantioselectivity was observed upon the addition of powdered molecular sieves to the reaction mixture
The Advocate
Headlines Include: Laurels For Feerick: An Alumnus To Remember; Crime at Fordham; Who\u27s Next?, Film at 11https://ir.lawnet.fordham.edu/student_the_advocate/1007/thumbnail.jp
Commission des Communautes Europeennes: Groupe du Porte-Parole. Reunion de la Commission du mercredi 29 octobre 1980 = Commission of European Communities: Spokesman Group. Meeting of the Commission on Wednesday, 29 October 1980. Spokesman Service Note to National Offices Bio No. (80) 432, 30 October 1980
We study strong-field ionization and rescattering beyond the long-wavelength limit of the dipole approximation with elliptically polarized mid-IR laser pulses. Full three-dimensional photoelectron momentum distributions (PMDs) measured with velocity map imaging and tomographic reconstruction revealed an unexpected sharp ridge structure in the polarization plane (2018 Phys. Rev. A 97 013404). This thin line-shaped ridge structure for low-energy photoelectrons is correlated with the ellipticity-dependent asymmetry of the PMD along the beam propagation direction. The peak of the projection of the PMD onto the beam propagation axis is shifted from negative to positive values when the sharp ridge fades away with increasing ellipticity. With classical trajectory Monte Carlo simulations and analytical analysis, we study the underlying physics of this feature. The underlying physics is based on the interplay between the lateral drift of the ionized electron, the laser magnetic field induced drift in the laser propagation direction, and Coulomb focusing. To apply our observations to emerging techniques relying on strong-field ionization processes, including time-resolved holography and molecular imaging, we present a detailed classical trajectory-based analysis of our observations. The analysis leads to the explanation of the fine structure of the ridge and its non-dipole behavior upon rescattering while introducing restrictions on the ellipticity. These restrictions as well as the ionization and recollision phases provide additional observables to gain information on the timing of the ionization and recollision process and non-dipole properties of the ionization process.ISSN:1361-6455ISSN:0368-3508ISSN:0953-4075ISSN:0022-370
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