Zbigniew Łodziana

Fe 3 O 4 ( 001 ) films on Fe ( 001 ) : Termination and reconstruction of iron-rich surfaces

High-quality and impurity-free magnetite surfaces with

Hydrogen tracer diffusion in LiBH4 measured by spatially resolved Raman spectroscopy

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Understanding and Tuning the Intrinsic Hydrophobicity of Rare-Earth Oxides: A DFT+U Study.

reconstruction have been obtained for the

A Composite of Complex and Chemical Hydrides Yields the First Al‐Based Amidoborane with Improved Hydrogen Storage Properties

{\mathrm{Fe}}_{3}{\mathrm{O}}_{4}(001)

Modified Anion Packing of Na2B12H12 in Close to Room Temperature Superionic Conductors

epitaxial films deposited on

Expanding and Reducing Complexity in Materials Science Models with Relevance in Catalysis and Energy

\mathrm{Fe}(001)

Reevaluation of the Structure and Fundamental Physical Properties of Dawsonites by DFT Studies

. Based on atomically resolved scanning tunneling microscopy images for both negative and positive sample polarity and density-functional-theory calculations, a model of the magnetite (001) surface terminated with Fe ions forming dimers on the reconstructed

Phonon Mode Conversion at Planar Interfaces in Crystalline Solids. Harmonic and Anharmonic Interface Potentials

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Dynamics of the Coordination Complexes in a Solid-State Mg Electrolyte

octahedral iron layer is proposed.

Quantum mechanical calculations of elastic properties of doped tetragonal yttria-stabilized zirconium dioxide

The hydrogen tracer diffusion in LiBH(4) has been determined by spatially resolved Raman spectroscopy. The measurements give direct evidence of a macroscopic diffusion of BH ions as well as atomic exchange of hydrogen between the anions. An effective tracer diffusion coefficient of deuterium in LiBH(4) of D approximately 7 x 10(-14) m(2) s(-1) at 473 K is derived. The direct exchange rate of hydrogen between BH(4) units is 10 orders of magnitude slower, i.e. the relatively fast effective hydrogen diffusion has its origin in the fast diffusion of BH(4) units.