TeV Superconducting Linear Accelerator (TESLA) cryostats consist of eight, 1-meter-long radio frequency (RF) cavity modules cryogenically connected in series with one focusing quadrupole. Each module contains one, 9-cell superconducting RF cavity operating at 1.3 GHz in a 1.8K helium bath. Individual modules are self-contained in the that they have their own input couplers, high order mode couplers, and tuning mechanisms. Services common to the entire cryostat consist of 70K and 4.5K thermal radiation shields, shield supply and return lines, a 1.8K helium supply line, and a gas helium return pipe. All cavity modules, the quadrupole, and cryogenic seances are contained in a single 12-meter-long vacuum vessel. The goal of the present work on TESLA is the successful fabrication and test of four complete cryostat assemblies. These cryostats will be installed in a string cooled to operating temperature, and powered. This test will address problems which may arise when modules are installed in a tunnel environment It will also permit testing of the basic cooling concepts, measurement of static heat losses, and measurement of the RF performance of all cavities.

Slow strain rate testing has been undertaken to determine the effects of individual chemical species on the fracture process of high-strength 4340 steel. Test environments included potassium chloride, ammonium nitrate, and ammonium chloride at concentrations from 0.001 to 1.0 mole por liter at ambient temperature. Tests were performed at cathodic and anodic controlled potentials, as well as at the open-circuit potential, to delineate the stress corrosion cracking range.

In next-to-leading order quantum chromodynamics, gluon-gluon interactions dominate the production of bottom quarks at hadron collider energies, and gluon-quark interactions control inclusive prompt photon production at large transverse momentum in pp collisions at fixed-target energies. Using such data, in conjunction with data from deep inelastic lepton scattering, we determine a new gluon density whose shape differs substantially from that derived from previous fits of data. The new set of parton densities provides a good fit to bottom quark, prompt photon, and deep inelastic data, including the most recent NMC and CCFR results.

The DWPF Salt Cell Vent Condenser (SCVC) includes a High Efficiency Mist Eliminator (HEME) designed to remove mercury aerosols that may form in the Precipitate Reactor (PR) condenser. The Savannah River Technology Center was requested by DWPF to make a performance assesssment of a prototypic HEME element in the vent system of the Precipitate Hydrolysis Experimental Facility at TNX.[sup a]

Work on the `Energy and the Environment` project has been focused on completion of two interrelated efforts: (1) development, production, and installation of energy related exhibits in the Ecology and Environment gallery, and (2) creation and implementation of the `Energy Backpack` program. The Energy exhibits have been available to over 1.5 million visitors since the opening of the new St. Louis Science Center. The `Energy Backpack` program will be implemented with students, teachers, and family groups this fall.

In next-to-leading order quantum chromodynamics, gluon-gluon interactions dominate the production of bottom quarks at hadron collider energies, and gluon-quark interactions control inclusive prompt photon production at large transverse momentum in pp collisions at fixed-target energies. Using such data, in conjunction with data from deep inelastic lepton scattering, we determine a new gluon density whose shape differs substantially from that derived from previous fits of data. The new set of parton densities provides a good fit to bottom quark, prompt photon, and deep inelastic data, including the most recent NMC and CCFR results.

The DWPF Salt Cell Vent Condenser (SCVC) includes a High Efficiency Mist Eliminator (HEME) designed to remove mercury aerosols that may form in the Precipitate Reactor (PR) condenser. The Savannah River Technology Center was requested by DWPF to make a performance assesssment of a prototypic HEME element in the vent system of the Precipitate Hydrolysis Experimental Facility at TNX.

The January 2, 1992 explosion in an electrochemistry laboratory at SRI International (SRI) resulted in the death of scientist Andrew Riley, and gained some notoriety due to its association with experimental work in the controversial field of cold fusion research. Selected components of explosion debris were subjected to forensic analyses at LLNL to elucidate potential causes of, or contributing factors to, the explosion. Interrogation of the debris by LLNL encompassed nuclear, chemical, physical, and materials investigations. Nuclear studies for the determination of tritium and neutron-activation products in stainless steel and brass were negative. No evidence of signature species indicative of orthodox nuclear events was detected. The inorganic and particulate analyses were likewise negative with respect to residues of unexpected chemical species. Such target compounds included conventional explosives, accelerants, propellants, or any exceptional industrial chemicals. The GC-MS analyses of trace organic components in the explosion debris provided perhaps the most interesting results obtained at LLNL. Although no evidence of organic explosives, oxidizers, or other unusual compounds was detected, the presence of a hydrocarbon oil in the interior of the electrochemical cell was established. It is likely that its source was lubricating fluid from the machining of the metal cell components. If …