AB INITIO LCAO/MO CLUSTER-TYPE CALCULATION OF THE SELF CONSISTENT ELECTRONIC SCREENING CHARGE DENSITY AROUND A SINGLE HYDROGEN IMPURITY IN A NICKEL CRYSTAL

SIMPSON, RUSSELL WOODWARD

January 1978

No description available.

Physics

Condensed Matter

THE PHOTOREFRACTIVE AND THE BULK PHOTOVOLTAIC EFFECTS IN LITHIUM-NIOBATE AND LITHIUM-TANTALATE

JOINER, CHARLES STEVEN

January 1979

No description available.

Physics

Condensed Matter

THE MAGNETOELASTIC INTERACTIONS IN DYSPROSIUM SINGLE CRYSTAL

KOO, JEN-WEI CARL

January 1979

No description available.

Physics

Condensed Matter

THERMOELECTRIC POWER OF MOLYBDENUM-RICH RHENIUM, MOLYBDENUM-NIOBIUM, NIOBIUM-RICH ZIRCONIUM AND TUNGSTEN-TANTALUM ALLOYS

LIN, AN-CHUNG

January 1978

No description available.

Physics

Condensed Matter

THE EFFECTS OF STRONG VIBRONIC COUPLING ON THE ELECTRON PARAMAGNETIC RESONANCE SPECTRA OF D(3) AND D(4) IONS IN ALKALINE-EARTH FLUORIDES

PRATER, RUDY LESTER

January 1979

No description available.

Physics

Condensed Matter

ULTRASONIC GENERATION IN THIN FILMS OF TERBIUM-IRON(2)

WIMBUSH, WALTER LESLIE, JR.

January 1978

No description available.

Physics

Condensed Matter

THE USE OF RESONANT EPITHERMAL NEUTRON SCATTERING FOR THE STUDY OF CONDENSED MATTER

WORD, ROBERT EARL

January 1979

No description available.

Physics

Condensed Matter

CONDUCTIVITY STUDIES IN IRON-DOPED LITHIUM-NIOBATE BY PHASE HOLOGRAPHY

BIENVENU, MICHAEL PATRICK

January 1981

By the use of holographic storage techniques, the conductivity of iron doped lithium niobate has been investigated. The results indicate that the conductivity of the material immediately after hologram formation is much greater than previously suspected. This increased conductivity is shown to be a direct result of the multivalent properties of the iron dopant molecules, and the underlying theory necessary to account for the effect is presented, this theory being an elaboration of the bulk photovoltaic theory of von der Linde and Glass.

Physics, Condensed Matter

DOUBLE ELECTRON MUON RESONANCE

VANDERWATER, DAVID ALLEN

January 1981

Muon-containing defects in insulators and in semiconductors have been studied for several years using the muon spin rotation ((mu)SR) technique. Double electron muon resonance (DEMUR) is an extension to the more common technique. This new double resonance technique can be used to observe EPR transitions of these muonic defects that are not directly observable in normal (mu)SR. This experimental technique has been applied successfully to muonium in quartz. A general theory of the response of two strongly coupled spin 1/2 particles to an intense rf magnetic field, when particularized to muonium in quartz, is found to describe the experimental results in detail.

Physics, Condensed Matter

AN ELECTRON SPIN POLARIZED HELIUM-EXCITED(TRIPLET-2S) METASTABLE BEAM FOR USE IN SURFACE STUDIES

RIDDLE, THOMAS WAYNE

January 1982

A source of electron spin polarized He*(2('3)S) metastable atoms is described that provides a thermal energy beam with a flux up to 8 x 10('12) metastables/sec/sterad at a polarization P(,z) (TURN) 50%. The polarization is created by optical pumping and can be simply reversed or modulated without changing the beam trajectory or flux. The source is housed in a system of three differentially pumped vacuum chambers which allows the beam to be used for surface experiments in an ultra high vacuum environment. The polarization is measured with a Stern-Gerlach type analyzer which also serves as a useful diagnostic of beam composition and verifies the purity of the 2('3)S beam. The beam is demonstrated not to contain any significant admixture of 2('1)S metastables, ions, fast neutrals, or photons. Unless care is exercised, however, it is possible to produce a beam of energetic ground state helium which is of much greater intensity than the metastable beam. The conditions under which this occurs are described. A brief overview of metastable deexcitation spectroscopy (MDS) is given and a proposed first experiment involving the investigation of surface magnetism of Ni(110) and the necessary apparatus for this experiment are described.

Physics, Condensed Matter