Sentence examples for screen anode from inspiring English sources

Partial oxidation of propylene on a screen anode in an aqueous solution of a pH value of 12.0 13.9 has been studied in the temperature range of 40°C 75°C, and in the partial pressure of propylene from 0.04 to 1.0 atm.

When the light screening floating anode is present an effective optical decoupling from both photodiodes is achieved while maintaining a good electrical conductivity and an increased light-to-dark sensitivity.

Constant and stable power output even with variable load condition (up to VSWR 2) is achieved by employing two real time feedback control loops-one for making constant output power and the other one for optimizing anode & screen grid dissipation.

The actuation of such device has been simulated using several numerical approaches including full determination of electrostatic potentials with accurate description of fields at the wedge region, electron beam propagation inside the device, and evaluation of the current density distributions at the anode detector screen.

According to our quantum screening effect model, as anode to the top of cathode separation d (like the top of our P-SiNT) approaches to nano-distance, the local field will decrease because of the quantum screening effect, but the applied field did not decrease because the separation of anode to the bottom of cathode is still large.

A salient feature of our work is that the data were collected on 50 μm thick anodes screen-printed on 110 μm thick YSZ electrolytes and the experiments were carried out in a fuel cell configuration.

The use of a metal grid (290 × 290 μm2 Cr pixels with 40 μm spacing) between the two diodes, working as light screening layer or as floating anode via an a-SiN insulator layer, is analyzed.

The anode plate has also a phosphor screen, by which we can directly observe FEM (Field Emission Microscope) image from emitted electrons, out of chamber through an optical fiber plate attaching on the phosphor screen.

In this experiment, the metal anode is replaced with a fluorescent screen in which the phosphor powder is uniformly smeared on the graphene electrode to collect emission electrons, as indicated in Figure 2.

The screen-printed support design was Ni-8YSZ functional anode (thickness ∼5 μm) on the thick NiO-NiAl2O4 composite (1 1 weight ratio) based support.

A glass plate with transparent indium tin oxide (ITO) electrode and phosphor was used as both an anode to collect electrons and a display screen.