High Electron Diffusion Research Articles

TiO2 Surface State Control for Dye Sensitized Solar Cells with High Efficiency and the Solidification -Fabrication of Charge Carrier Path

AbstractImprovement of photovoltaic performance for dye sensitized solar cells (DSC) is discussed in terms of electron-path and ion-path. In order to make electron path, we focused on passivation of TiO2 surface states which are observed by thermally stimulated current (TSC). The TiO2 surface was well-passivated with dye molecules under pressurized CO2 atmosphere. It was found that DSC cells prepared by a CO2 process (Cell-CO2) had higher efficiency than those prepared by a conventional dipping process (Cell-DIP) and the higher efficiency was associated with low TiO2-surface state, high electron diffusion coefficient and long electron life time in TiO2 for the Cell-CO2. In addition, dye-staining under pressurized CO2 atmosphere had advantages over a conventional dipping process on rapid dye-uptake and less dye aggregation. In order to fabricate ion-path in solidified electrolyte, we focused on surface modification of nano-materials. Surface of nano-materials such as TiO2-nanoparticles and porous alumina films were modified with imidazolium iodide moieties consisting of long alkyl chains which render surface-molecules self-organized. Redox-species are concentrated on the self-organized molecules and make ion-path. We propose quasi-solid electrolyte system consisting of two layers having different charge carrier concentration to keep high photoconversion efficiencies even after solidification.

Simulation of a direct current microplasma discharge in helium at atmospheric pressure

A numerical simulation of a dc microplasma discharge in helium at atmospheric pressure was performed based on a one-dimensional fluid model. The microdischarge was found to resemble a macroscopic low pressure dc glow discharge in many respects. The simulation predicted the existence of electric field reversals in the negative glow under operating conditions that favor a high electron diffusion flux emanating from the cathode sheath. The electric field adjusts to satisfy continuity of the total current. Also, the electric field in the anode layer is self adjusted to be positive or negative to satisfy the “global” particle balance in the plasma. Gas heating was found to play an important role in shaping the electric field profiles both in the negative glow and the anode layer. Basic plasma properties such as electron temperature, electron density, gas temperature, and electric field were studied. Simulation results were in good agreement with experimental observations.

A potentially insect-implantable trehalose electrooxidizing anode

The dominant sugar in the body fluids of many insects is not glucose, the sugar of the vertebrates, but trehalose. In a step toward a cell that would operate in insects, we describe here a trehalose electrooxidizing anode. The novel component of the anode is its engineered, trehalose oxidation catalyzing, FAD-glucose-3-dehydrogenase (G3DH). Screening for gene-sources of G3DH pointed to the G3DH of Agrobacterium tumefaciens. Sequencing of the A. tumefaciens genome revealed a 1.7 kb fragment which contained the G3DH coding gene. The fragment was isolated, cloned and expressed in E. coli strain BL-21, to yield the approximately 65 kDa his-tagged flavoenzyme, with a specific activity of approximately 2.5U/mg protein. Electrical wiring of its reaction center to a carbon electrode through a high apparent electron diffusion coefficient (5.8 x 10(-6)cm(2)/s) redox hydrogel with a -0.2V versus Ag/AgCl redox potential resulted in the trehalose electrooxidizing anode. Trehalose was electrooxidized at pH 7.2 already at -0.36 V versus Ag/AgCl. At 0 V versus Ag/AgCl the trehalose electrooxidation current density was 0.1 mA/cm(2).

Three-dimensional cylindrical X-band ESR imaging by a combined pulsed gradient Fourier and static gradient projection reconstruction method

Static gradient electron spin echo projection reconstruction imaging is favourable for X-band material science applications requiring temperature variation with a metal cryostat. To prevent imaging artefacts due to the high conduction electron diffusion coefficient in the preferred conduction direction of quasi-one-dimensional conductors, only pulsed gradient phase encoding for that direction can be tolerated. We present results of an appropriate cylindrical imaging scheme combining both methods. Conduction electron spin density images with 13 × 13 × 17 μm 3 volume element size or spin–lattice relaxation time images with inversion recovery sequence and 13 × 13 × 68 μm 3 volume element size are presented for fluoranthene radical cation salt single crystals of typical sizes of 0.4 × 0.4 × 1 mm 3.

Tokamak-like confinement at a high beta and low toroidal field in the MST reversed field pinch**Presented at the 19th IAEA Fusion Energy Conference with the title Overview of Improved Confinement and Plasma Control in the MST Reversed Field Pinch.

Energy confinement comparable with tokamak quality is achieved in the Madison Symmetric Torus (MST) reversed field pinch (RFP) at a high beta and low toroidal magnetic field. Magnetic fluctuations normally present in the RFP are reduced via parallel current drive in the outer region of the plasma. In response, the electron temperature nearly triples and beta doubles. The confinement time increases ten-fold (to ∼10 ms), which is comparable with L- and H-mode scaling values for a tokamak with the same plasma current, density, heating power, size and shape. Runaway electron confinement is evidenced by a 100-fold increase in hard x-ray bremsstrahlung. Fokker–Planck modelling of the x-ray energy spectrum reveals that the high energy electron diffusion is independent of the parallel velocity, uncharacteristic of magnetic transport and more like that for electrostatic turbulence. The high core electron temperature correlates strongly with a broadband reduction of resonant modes at mid-radius where the stochasticity is normally most intense. To extend profile control and add auxiliary heating, rf current drive and neutral beam heating are in development. Low power lower-hybrid and electron Bernstein wave injection experiments are underway. Dc current sustainment via ac helicity injection (sinusoidal inductive loop voltages) is also being tested. Low power neutral beam injection shows that fast ions are well-confined, even in the presence of relatively large magnetic fluctuations.

High electron diffusion length silicon ribbons by plasma torch projection

Silicon powder has been injected into a plasma torch, melted in the hydrogen-argon plasma and deposited onto an alumina substrate. Ribbons of up to 5 cm × 5 cm, which may be detached from the substrate, have been obtained. Doping was controlled by adding B 2O 3 to the silicon powder. This material is microcrystalline and contains some porosity and microcracks, in addition to a high content of transition element impurities. It can be electron gun annealed, leading to a large grain size, partly purified ribbon. The electron diffusion length was measured from the photoelectric current of metal-insulator-semiconductor diodes. It is measured as 17–32 μm for the initial ribbons, and up to 69 μm for annealed ribbons of hole density 10 17 cm −3. This good photoelectric quality is attributed to the oxidation of impurities in the plasma and to hydrogen passivation of the grain boundaries.