29 research outputs found
Cation- and vacancy-ordering in Li_xCoO_2
Using a combination of first-principles total energies, a cluster expansion
technique, and Monte Carlo simulations, we have studied the Li/Co ordering in
LiCoO_2 and Li-vacancy/Co ordering in CoO_2. We find: (i) A ground state search
of the space of substitutional cation configurations yields the (layered) CuPt
structure as the lowest-energy state in the octahedral system LiCoO_2 (and
CoO_2), in agreement with the experimentally observed phase. (ii) Finite
temperature calculations predict that the solid-state order- disorder
transitions for LiCoO_2 and CoO_2 occur at temperatures (~5100 K and ~4400 K,
respectively) much higher than melting, thus making these transitions
experimentally inaccessible. (iii) The energy of the reaction E(LiCoO_2) -
E(CoO_2) - E(Li) gives the average battery voltage V of a Li_xCoO_2/Li cell.
Searching the space of configurations for large average voltages, we find that
CuPt (a monolayer superlattice) has a high voltage (V=3.78 V), but that
this could be increased by cation randomization (V=3.99 V), partial disordering
(V=3.86 V), or by forming a 2-layer Li_2Co_2O_4 superlattice along
(V=4.90 V).Comment: 12 Pages, RevTeX galley format, 5 figures embedded using epsf Phys.
Rev. B (in press, 1998
Influence of sputtering gas pressure on the LiCoO2 thin film cathode post-annealed at 400 °C
Superconducting magnet and conductor research activities in the US fusion program
Fusion research in the United States is sponsored by the Department of Energy's Office of Fusion Energy Sciences (OFES). The OFES sponsors a wide range of programs to advance fusion science, fusion technology, and basic plasma science. Most experimental devices in the US fusion program are constructed using conventional technologies; however, a small portion of the fusion research program is directed towards large scale commercial power generation, which typically relies on superconductor technology to facilitate steady-state operation with high fusion power gain, Q. The superconductor portion of the US fusion research program is limited to a small number of laboratories including the Plasma Science and Fusion Center at MIT, Lawrence Livermore National Laboratory (LLNL), and the Applied Superconductivity Center at University of Wisconsin, Madison. Although Brookhaven National Laboratory (BNL) and Lawrence Berkeley National Laboratory (LBNL) are primarily sponsored by the US's High Energy Physics program, both have made significant contributions to advance the superconductor technology needed for the US fusion program. This paper summarizes recent superconductor activities in the US fusion program.close1
Intense highly charged ion beam production and operation with a superconducting electron cyclotron resonance ion source
The superconducting electron cyclotron resonance ion source with advanced design in Lanzhou (SECRAL) is a superconducting-magnet-based electron cyclotron resonance ion source (ECRIS) for the production of intense highly charged heavy ion beams. It is one of the best performing ECRISs worldwide and the first superconducting ECRIS built with an innovative magnet to generate a high strength minimum-B field for operation with heating microwaves up to 24–28 GHz. Since its commissioning in 2005, SECRAL has so far produced a good number of continuous wave intensity records of highly charged ion beams, in which recently the beam intensities of ^{40}Ar^{12+} and ^{129}Xe^{26+} have, for the first time, exceeded 1 emA produced by an ion source. Routine operations commenced in 2007 with the Heavy Ion accelerator Research Facility in Lanzhou (HIRFL), China. Up to June 2017, SECRAL has been providing more than 28,000 hours of highly charged heavy ion beams to the accelerator demonstrating its great capability and reliability. The great achievement of SECRAL is accumulation of numerous technical advancements, such as an innovative magnetic system and an efficient double-frequency (24+18 GHz) heating with improved plasma stability. This article reviews the development of SECRAL and production of intense highly charged ion beams by SECRAL focusing on its unique magnet design, source commissioning, performance studies and enhancements, beam quality and long-term operation. SECRAL development and its performance studies representatively reflect the achievements and status of the present ECR ion source, as well as the ECRIS impacts on HIRFL