Hideo Takematsu scite author profile

Point cathode electron gun with high brightness and long cathode life has been developed. In this gun, a straightened tungsten wire is used as the point cathode, and the tip is locally heated to higher temperatures by electron beam bombardment. The high brightness operation and some findings on the local heating are presented.Gun construction is shown in Fig.l. Small heater assembly (annular electron gun: 5 keV, 1 mA) is set inside the Wehnelt electrode. The heater provides a disk-shaped bombarding electron beam focusing onto the cathode tip. The cathode is the tungsten wire of 0.1 mm in diameter. The tip temperature is raised to the melting point (3,650 K) at the beam power of 5 W, without any serious problem of secondary electrons for the gun operation. Figure 2 shows the cathode after a long time operation at high temperatures, or high brightnesses. Evaporation occurs at the tip, and the tip part retains a conical shape. The cathode can be used for a long period of time. The tip apex keeps the radius of curvature of 0.4 μm at 3,000 K and 0.3 μm at 3,200 K. The gun provides the stable beam up to the brightness of 6.4×106 A/cm2sr (3,150 K) at the accelerating voltage of 50 kV. At 3.4×l06 A/cm2sr (3,040 K), the tip recedes at a slow rate (26 μm/h), so that the effect can be offset by adjusting the Wehnelt bias voltage. The tip temperature is decreased as the tip moves out from the original position, but it can be kept at constant by increasing the bombarding beam power. This way of operation is possible for 10 h. A stepwise movement of the cathode is enough for the subsequent operation. Higher brightness operations with the rapid receding rates of the tip may be improved by a continuous movement of the wire cathode during the operations. Figure 3 shows the relation between the beam brightness, the tip receding rate by evaporation (αis the half-angle of the tip cone), and the cathode life per unit length, as a function of the cathode temperature. The working life of the point cathode is greatly improved by the local heating.

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<title>Surface-charge method and electron ray tracing on vector pipeline supercomputers</title>

Iiyoshi

Niwa

Takematsu

1993

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The surface charge method (SCM) is an accurate electric field solver based on the numerical integration of the charge distribution on the electrode surface. The method is suitable for the field analysis of an electron gun and lens with complicated geometry, but it becomes the most time-consuming part when electron rays are traced for the analysis of the electron optical characteristics of these devices. We have studied the SCM and the electron ray-tracing on vector pipeline supercomputers, the CRAY X-MP and the Fujitsu VP2600. On these computers, a big reduction of the computing time is obtained by the optimization of the SCM-code. This enables us to trace many electron rays for the electron beam analysis. Some applications of the optimized SCM-code for the beam analysis are also presented.

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Local Heating of Point Cathode: Numerical Calculations of Temperature Distribution and Cathode Shape Variation by Evaporation

Iiyoshi

Maruse

Takematsu

1990

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Fluorescence Decay Curves of Pyrene Crystals Containing High Concentration Perylene

et al. 1974

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Hideo Takematsu

Electron gun with electron-beam-heated point cathode: numerical analysis of electron beam for cathode tip heating

Point-Cathode Electron Gun Using Electron-Beam Bombardment for Cathode Tip Heating

<title>Surface-charge method and electron ray tracing on vector pipeline supercomputers</title>

Local Heating of Point Cathode: Numerical Calculations of Temperature Distribution and Cathode Shape Variation by Evaporation

Fluorescence Decay Curves of Pyrene Crystals Containing High Concentration Perylene

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