Attosecond streaking of correlated two-electron transitions in helium

We present fully ab initio simulations of attosecond streaking for ionization of helium accompanied by shakeup of the second electron. This process represents a prototypical case for strongly correlated electron dynamics on the attosecond time scale. We show that streaking spectroscopy can provide detailed information on the Eisenbud-Wigner-Smith time delay as well as on the infrared-field dressing of both bound and continuum states. We find a novel contribution to the streaking delay that stems from the interplay of electron-electron and infrared-field interactions in the exit channel. We quantify all the contributions with attosecond precision and provide a benchmark for future experiments.     

Surface Initiated Polymerization on Pulsed Plasma Deposited Polyallylamine: A Polymer Substrate‐Independent Strategy to Soft Surfaces with Polymer Brushes

The deposition of polyallylamine (PAA) adlayers by pulsed plasma polymerization on various types of polymeric substrates has been explored as a general route to amino functionalized polymeric surfaces. These amino groups are highly suitable for anchoring an atom transfer radical polymerization (ATRP) initiator via a robust amide linkage. Subsequent surface initiated ATRP (SI‐ATRP) of monomethoxy oligo(ethylene glycol) methacrylate (MeOEGMA) resulted in polyMeOEGMA brush grafted polymer surfaces. This combined strategy of pulsed plasma polymerization with SI‐ATRP was demonstrated for five different polymeric substrates namely polyether ether ketone (PEEK), polyethylene terephthalate (PET), polyimide (PI), polypropylene (PP), and polytetrafluoroethylene (PTFE). Analysis of brush layers by attenuated total reflection infrared (ATR‐IR) spectroscopy as well as X‐ray photoelectron spectroscopy (XPS) fully corroborated the success of the proposed strategy for all substrate types.

     

A note on the perron root of a weighted t-th Order mean of nonnegative matrices

In this paper we compare the spectral radius of a weighted additive mean L of order t involving Hadamard powers of nonnegative matrices with the corresponding mean R of the respective spectral radii especially, when all matrices are row stochastic, we obtain L≥R for t≥1 and L≤R for 0 ≤ t ≤ 1.     

An improved LCAO interpolation scheme for energy band structures. Application to four compounds (ScN,ScP, TiN,ZrN) crystallizing in the sodium chloride structure

An improved version of the LCAO interpolation scheme using metal s-, p-, d-, and non metal s-, and p-basis functions is presented for transition metal compounds with sodium chloride structure. This method enables us to interpolate with reasonable accuracy occupied bands as well as unoccupied energy bands up to 0.9 Rydberg above the Fermi level for the compounds ScN, ScP, TiN and ZrN. Due to the limited basis, problems arise however with bands of predominantly transition metal f or non metal d character lying in this energy range - as is the case for ScP.Optimized parameter sets are presented for the compounds ScN, ScP, TiN and ZrN. They were used for the calculation of the imaginary part of the complex dielectric function, ₂(), as will be shown in two forthcoming papers.     

On reasons of Si NMR chemical shift/structure relations for silicon oxides, nitrides, and carbides: An individual-gauge-for-localized-orbitals study

For -quartz, monoclinic ZSM-5, -and β-Si₃N₄ and SiC---6H polytype, the silicon chemical shifts have been calculated using the IGLO (individual gauge for localized orbitals) method and models of different size in real crystal geometry. The result is a theoretical chemical shift scale, which is very similar to the corresponding experimental scale from ²⁹Si MAS NMR experiments. It is shown that the assignment of isotropic silicon chemical shifts of crystallized solids based on theory is a method of practical applicability, also in cases where experimental methods or empirical relations fail. The two NMR spectral lines of -Si₃N₄ are for the first time assigned to the crystallographic positions. The partition of the silicon chemical shifts into localized contributions from different parts of the model allows insight into the interactions around the resonance nucleus due to substituent and geometry variations leading to silicon chemical shifts.     

A computer program for the automatic estimation of H NMR chemical shifts

A computer program has been developed for predicting ¹H NMR chemical shifts. It automatically finds the various substructures of a given molecule for which additivity rules are available. Several strategies have been used to widen the range of applicability. with 200 test compounds, over 90% of the assigned chemical shifts of protons bonded to a carbon atom could be predicted. The mean deviation between observed and predicted values was 0.08 ppm with a standard deviation of 0.19ppm.     

Synthesis and Structure of Vitamin B12-Derivatives with a Modified Ribose-Unit

The acylation at the 5′-OH group of the ribose-unit of vitamin B₁₂ (cyanocobalamin) or of aquocobalamin with two conventional reagents gave mono-acylated B₁₂-derivatives with good to very high selectivity. The site of the modification was deduced from spectral data of the products and was further supported by the crystal structure data of three such modified B₁₂-derivatives. These three B₁₂-derivatives were found to crystallize in the space group P2₁2₁2₁, irrespective of the nature of the appendage. Acylation at 5′-OH has been used to protect (or block) this group in the context of functionalization of 2′-OH or elsewhere in the B₁₂-molecule. Attachment of the bifunctional succinyl-unit has allowed the preparation of further modified derivatives of vitamin B₁₂ and binding of B₁₂-derivatives to biological carriers and other macromolecules. In aqueous solution, 5′-acylcobalamins turned out to be rather susceptible to hydrolytic loss of the acyl-functionality.