353 research outputs found
SiH Aggregates: From Simple Building Blocks to Highly Magnetic Functionalized Materials
Density-functional theory based global geometry optimization is used to
scrutinize the possibility of using endohedrally-doped hydrogenated Si clusters
as building blocks for constructing highly magnetic materials. In contrast to
the known clathrate-type facet-sharing, the clusters exhibit a predisposition
to aggregation through double Si-Si bridge bonds. For the prototypical
CrSiH cluster we show that reducing the degree of hydrogenation
may be used to control the number of reactive sites to which other cages can be
attached, while still preserving the structural integrity of the building block
itself. This leads to a toolbox of CrSiH monomers with
different number of double "docking sites", that allows building network
architectures of any morphology. For (CrSiH) dimer and
[CrSiH](CrSiH) trimer structures we
illustrate that such aggregates conserve the high spin moments of the dopant
atoms and are therefore most attractive candidates for cluster-assembled
materials with unique magnetic properties. The study suggests that the
structural completion of the individual endohedral cages within the
doubly-bridge bonded structures and the high thermodynamic stability of the
obtained aggregates are crucial for potential synthetic polymerization routes
controlled dehydrogenation
On the stability of "non-magic" endohedrally doped Si clusters: A first-principles sampling study of MSi16^+ (M =Ti,V,Cr)
Density-functional theory is used to study the geometric and electronic
structure of cationic Si16^+ clusters with a Ti, V or Cr dopant atom. Through
unbiased global geometry optimization based on the basin-hopping approach we
confirm that a Frank- Kasper polyhedron with the metal atom at the center
represents the ground-state isomer for all three systems. The endohedral cage
geometry is thus stabilized even though only VSi16^+ achieves electronic shell
closure within the prevalent spherical potential model. Our analysis of the
electronic structure traces this diminished role of shell closure for the
stabilization back to the adaptive capability of the metal- Si bonding, which
is more the result of a complex hybridization than the orginally proposed mere
formal charge transfer. The resulting flexibility of the metal-Si bond can help
to stabilize also "non-magic" cage-dopant combinations, which suggests that a
wider range of materials may eventually be cast into this useful geometry for
cluster-assembled materials.Comment: 13 pages including 5 figures; related publications can be found at
http://www.fhi-berlin.mpg.de/th/th.htm
Multi-Doping of Si Cages: High Spin States beyond the Single-Dopant Septet Limit
Density-functional theory based global geometry optimization is employed to
systematically scrutinize the possibility of multi-doping of hydrogenated Si
clusters in order to achieve high spin states beyond the septet limit of a
single-atom dopant. While our unbiased configurational search reveals that the
previously suggested Si18H12 double hexagonal prism structure is generally too
small to accommodate two dopants in magnetized state, the larger Si24H24 cage
turns out to be suitable for such applications. For dimer dopants M2+ = Cr2+,
Mn2+ and CrMn+, the structural integrity of the host cage is conserved in the
ground-state structure of corresponding M2+@Si24H24 aggregates, as is the
unusually high spin state of the guest dopant, which in case of Cr2+ already
exceeds the single-atom dopant septet limit by almost a factor of two.
Moreover, the possibility of further increasing the cluster spin moment by
encapsulating an even larger number of dopants into a suitably sized
hydrogenated Si cage is illustrated for the example of a (CrMn+)2@Si28H28
aggregate with a total number of 18 unpaired electrons. These results strongly
suggest multi-doping of Si clusters as a viable route to novel cluster-based
materials for magneto-optic applications
The contribution of methanol to the 3.4 micron feature in comets
With the advent of improved detectors and improved moderate resolution spectrometers several interesting features have been seen in the infrared spectra of comets. In particular, an emission excess at 3.52 microns was observed in several comets, and has recently been tentatively assigned to the nu 3 band of methanol (CH3OH). Using a developed model it is possible to calculate the relative strengths of the CH3OH features. The 3.52 microns emission strengths were used in a number of comets to retrieve methanol amounts, and the model was used to predict the fraction of the 3.4 micron flux which is contributed by the species. Implications for cometary formation are discussed
Infrared remote sensing of cometary parent volatiles from the ground, air, and space
A balanced view of the present generation of infrared instruments for cometary compositional studies is presented. Ground-based instruments are compared with airborne and spaceborne capabilities. An attempt to give examples of the unique science achievable with each is made, and particular emphasis is on the unique aspects of a dedicated Cometary Composition Telescope in earth orbit for investigating the chemical and structural heterogeneity of the cometary nucleus
Angiographic Findings in Diaphragmatic Rupture
The angiographic findings are presented in four patients with ruptured diaphragms. With rupture of the left hemidiaphragm the findings vary with the structures herniating. Gastric, mesenteric or splenic artery branches extending into the lower chest indicate herniation of the stomach, bowel or spleen. A herniating spleen is frequently ruptured. On the right, the liver is generally the only organ to herniate. An indentation in the lateral liver margin in the venous phase, if present, indicates the level of the diaphragm.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/73631/1/j.1440-1673.1976.tb02012.x.pd
Pseudoslit Spectrometer
The pseudoslit spectrometer is a conceptual optoelectronic instrument that would offer some of the advantages, without the disadvantages, of prior linear-variable etalon (LVE) spectrometers and prior slit spectrometers. The pseudoslit spectrometer is so named because it would not include a slit, but the combined effects of its optical components would include a spatial filtering effect approximately equivalent to that of a slit. Like a prior LVE spectrometer, the pseudoslit spectrometer would include an LVE (essentially, a wedge-like narrowband- pass filter, the pass wavelength of which varies linearly with position in one dimension) in a focal plane covering an imaging planar array of photodetectors. However, the pseudoslit spectrometer would be more efficient because unlike a prior LVE spectrometer, the pseudoslit spectrometer would not have to be scanned across an entire field of view to obtain the spectrum of an object of interest that may occupy only a small portion of the field of view. Like a prior slit spectrometer, the pseudoslit spectrometer could acquire the entire spectrum of such a small object without need for scanning. However, the pseudoslit spectrometer would be optically and mechanically simpler: it would have fewer components and, hence, would pose less of a problem of alignment of components and would be less vulnerable to misalignment
If at First You Don't Succeed: That's Pretty Much Standard Practice - Oddities on the Way to Discovery
No abstract availabl
Science Goals to Requirements
The presentation will be given at the 26th Annual Thermal Fluids Analysis Workshop (TFAWS 2015) hosted by the Goddard SpaceFlight Center (GSFC) Thermal Engineering Branch (Code 545): This short course will present the science goals for a variety of types of imaging and spectral measurements, the thermal requirements that these goals impose on the instruments designed to obtain the measurements, and some of the types of trades that can be made among instrument subsystems to ensure the required performance is maintained. Examples of thermal system evolution from initial concept to final implementation will be given for several actual systems
Stray Light Artifacts in Imagery from the Landsat 8 Thermal Infrared Sensor
The Thermal Infrared Sensor (TIRS) has been collecting imagery of the Earth since its launch aboard Landsat 8 in early 2013. In many respects, TIRS has been exceeding its performance requirements on orbit, particularly in terms of noise and stability. However, several artifacts have been observed in the TIRS data which include banding and absolute calibration discrepancies that violate requirements in some scenes. Banding is undesired structure that appears within and between the focal plane array assemblies. In addition, in situ measurements have shown an error in the TIRS absolute radiometric calibration that appears to vary with season and location within the image. The source of these artifacts has been determined to be out-of-field radiance that scatters onto the detectors thereby adding a non-uniform signal across the field-of-view. The magnitude of this extra signal can be approximately 8% or higher (band 11) and is generally twice as large in band 11 as it is in band 10. A series of lunar scans were obtained to gather information on the source of this out-of-field radiance. Analyses of these scans have produced a preliminary map of stray light, or ghost, source locations in the TIRS out-of-field area. This dataset has been used to produce a synthetic TIRS scene that closely reproduces the banding effects seen in actual TIRS imagery. Now that the cause of the banding has been determined, a stray light optics model is in development that will pin-point the cause of the stray light source. Several methods are also being explored to correct for the banding and the absolute calibration error in TIRS imager
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