Emission Properties Of Cathodes Research Articles

Experimental investigation of thermionic cathode properties of ultrafine tungsten filament

The thermionic cathode emission properties of an ultrafine tungsten filament are investigated with the accurate filament temperature (T) measured by an infrared pyrometer. The results show that the tungsten filament begins to emit electrons at T of about 1800 K, and the maximum electron emission efficiency (∼20 mA/W) occurs at T of about 2900 K. Moreover, the effective filament area for electron emission reaches saturation after T exceeds 2700 K. For a tungsten hot-cathode, a using standard is recommended that its operating temperature should not exceed 2600 K, the electron emission current density should not exceed 0.5 A/cm2, and the electron emission efficiency should be less than 5 mA/W. Additionally, the relation between the thermal emissivity of tungsten filament and T is also studied, showing a nearly linear increase of the thermal emissivity from 0.23 to 0.31 with T increasing from 1700 K to 2500 K and a saturated thermal emissivity of 0.48 at T of about 2900 K.

Current–voltage characteristics and mechanisms of electron emission from cold cathodes in a helium discharge

The abnormal discharge (AD) in pure helium and in helium containing molecular impurities was investigated. The obtained results were compared with the parameters of wide-aperture AD and different variants of ‘open’ discharge. It was shown that in all of the investigated types of discharges the current–voltage characteristics (CVCs) and, correspondingly, the emission properties of cold cathodes are determined mainly not by their material, but by the doping of cathodes with atoms of working gases and the purity of experimental conditions. With the impurity content less than 10−4% of the helium atom concentration, the CVCs begin to acquire S-shaped form, which is associated with a change in the electron emission mechanism. It was shown that the diversity of the CVCs is caused by uncertainty in the values of the secondary electron emission coefficients γ and the electron multiplication coefficient α in the cathode layer at reduced electric field strength E/N 103 Td. The reproducibility of CVCs and, correspondingly, emission properties of cathodes can be ensured by high purity of the working gas and by maintenance of the cathode doping only by the working gas atoms.

Investigation of changes in field electron emission characteristics of industrial fine-grained graphite when operated in an argon atmosphere up to 10–2 Pa

Studying of field electron emission properties of carbon cathodes operating under technical vacuum conditions is a promising scientific field. Massive cathode made of commercial fine-grained graphite of MG (Russian abbreviation) grade is being investigated. Experiments on obtaining current-voltage characteristics and long-term testing are being carried out. The emitter made of fine-grained graphite demonstrates good emission properties under technical vacuum conditions. Carbon cathode is capable of operating at pressures up to 2×10–2 Pa. Increased pressure in the vacuum chamber leads to deterioration of cathode emission properties. Electric field enhancement factors were calculated for all stages of studies. Analysis of experimental data demonstrates decrease in enhancement factor due to ion bombardment of cathode surface during exploitation. This results in higher electric field for operation of investigated graphite cold cathodes.

Field emission microscopy of carbon nanotube fibers: Evaluating and interpreting spatial emission

In this work, the authors quantify field emission properties of cathodes made from carbon nanotube (CNT) fibers. The cathodes were arranged in different configurations to determine the effect of cathode geometry on the emission properties. Various geometries were investigated including (1) flat cut fiber tip, (2) folded fiber, (3) looped fiber, and (4) fibers wound around a cylinder. The authors employ a custom field emission microscope to quantify I-V characteristics in combination with laterally resolved field-dependent electron emission area. Additionally, they look at the very early emission stages, first when a CNT fiber is turned on for the first time, which is then followed by multiple ramp-up/down runs. Upon the first turn on, all fibers demonstrated limited and discrete emission area. During ramping runs, all CNT fibers underwent multiple (minor and/or major) breakdowns, which improved emission properties in that turn-on field decreased and field enhancement factor and emission area both increased. It is proposed that breakdowns are responsible for removing initially undesirable emission sites caused by stray fibers higher than average. This initial breakdown process gives way to a larger emission area that is created when the CNT fiber subcomponents unfold and align with the electric field. The authors' results form the basis for careful evaluation of CNT fiber cathodes for dc or low frequency pulsed power systems in which large uniform area emission is required or for narrow beam high frequency applications in which high brightness is a must.

Study of nanometric thin pyrolytic carbon films for explosive electron emission cathode in high-voltage planar diode

We report on an experimental study of explosive electron emission properties of cathode made by nanometric thin pyrolytic carbon (PyC) films (2–150nm) deposited on Cu substrate via methane-based chemical vapor deposition. High current density at level of 300A/cm2 in 5·10−5Pa vacuum has been observed together with very stable explosive emission from the planar cathode. The Raman spectroscopy investigation proves that the PyC films remain the same after seven shots. According to the optical image analysis of the cathode before and after one and seven shots, we conclude that the most unusual and interesting feature of using the PyC films/Cu cathode for explosive emission is that the PyC layer on the top of the copper target prevents its evaporation and oxidation, which leads to higher emission stability compared to conventional graphitic/Cu cathodes, and therefore results in longer working life.

Synthesis of Nanocrystalline Electron Emissive Materials with Homogenous Composition in Nanoscale

In this research, specific stoichiometric mixture of nanocrystalline barium carbonate, calcium carbonate, and aluminum oxide was fabricated by using the sol-gel combustion method. This mixture is used as emissive materials on impregnated cathodes which make up high power vacuum microwave tubes such as klystrons. Composition uniformity and particle size of emissive materials affect the electron emission properties of impregnated cathodes. In this study, dry gel and heat treated powder at 500 °C are investigated by thermal analysis (TG/DTA), X-ray diffraction (XRD), scanning electron microscopy (SEM), and energy dispersive X-ray spectroscopy (EDX). The results show that dry gel combusts at 260 °C , and that during combustion transforms from an amorphous phase to a nanocrystalline phase. The average crystallite size of the powders which is calculated by Debye-Scherrer's method based on the XRD patterns is under 45 nm. The results of SEM and EDX of powder after heat treatment at 500 °C show that the particle size of powder is under 100 nm, and the chemical composition of emissive material is uniform at nanoscale. technique and ball-milling method. They reported that the emission properties of cathode synthesized by sol-gel technique were better than that of cathode produced through ball-milling method. They claimed that small particles and more uniform mixing bring about good emission capability of scandate cathode synthesized by sol-gel technique. Generally, the sol-gel combustion method is a novel technique for the production of crystalline and high purity powders. Sol-gel combustion technique is based on a chemical sol-gel and the subsequent combustion process. During the sol-gel process, an aqueous solution containing salts of the desired metal and an organic fuel form a gel. After the gel obtained, ignition occurs in the gel due to combustion process. The product of this step is voluminous and fluffy with a large surface area. This technique is characterized by inexpensive raw materials, low temperature synthesis, and obtaining nanocrystalline powder with homogenous composition (9). Studies have shown that using emissive materials with uniform composition and crystallite size at nanoscale improve emission performance of cathode. Wang et al. (10) fabricated oxide cathode using nano emissive materials which is produced by liquid-gas method. They reported that the emission current density of oxide cathode used nano emissive materials is significantly higher than that of the conventional oxide cathode under the same condition. The main goals of this work were to synthesize appropriate mixture of emissive materials by sol-gel combustion technique and investigation of crystalline structure and the composition uniformity of synthesized powder.

The Preparation and Properties Research on Lanthanum-Rich Film Cathode

The surface lanthanum element plays a key role in emission mechanism of Lanthanum-contained cathodes. In order to gain insight into the relation between cathode emission properties and the cathode surface La/O ratio, lanthanum-rich film cathodes were prepared in situ by using a set of equipment, specially designed to cathode research, which connected with an Auger electron spectrometer (AES) and pulse laser deposition system. Electron emission properties and surface compositions (lanthanum and oxygen) of the cathodes are investigated experimentally. Experiment results indicate that film cathodes are lanthanum-rich film cathode, there has remained unchanged on film composition in different depth; the cathode emission properties are determined intensively by the surface atomic La/O ratios, the higher the La/O ratio gets, the better the emission property reaches. The excess active Lanthanum is crucial element to the improvement of emission properties.

Emission properties of cathodes based on B–N–C as a result of laser processing

Emission properties of cathodes produced under the action of laser radiation are presented. Cathodes were fabricated in nitrogen flow as a result of surface modification induced by laser treatment of the compacted samples of fine-grained graphite-like h-BN powders and 25 wt.% lamp black composite. Optical and scanning electron microscopes revealed new structures and morphologies on the surface of samples formed due to the interaction of plume of ionized B, C and N with nitrogen ambient. X-ray diffraction (XRD) study demonstrated complicated phase composition of the precipitates formed by B–N–C composite after heating by laser beam.

Field Emission Properties of Large Area Carbon Nanotube Cathodes in DC and Pulse Modes

AbstractA large area carbon nanotube cathode was fabricated by use of a screen printing method. The emission properties of the cathode were investigated in both direct current and pulse mode experiments. In the direct current mode, the cathode has high field enhancement factor and high emission current density. In the double-pulse mode, the emission current density can approach 267 A/cm2 at an applied electric field of 15.4 V/um. Steady intense electron beams were obtained from the cathode. The results proved that the emission mechanism of CNTs at pulse electric field is plasma-induced field emission. The carbon nanotube cathode is suitable for not only field emission display applications but also high-power microwave device applications.

Field emission properties of a carbon nanotube cathode in different electric field modes

A large area carbon nanotube cathode was fabricated by spray deposition. The emission properties of the cathode were investigated in both direct current and pulse mode experiments. In the direct current mode, the cathode has high field enhancement factor and high emission current density. In the pulse mode, steady intense-current electron beams were obtained from the cathode. The average current density is 108 A/cm 2 at an electric field of 16.7 V/μm. The uniformity and quality of electron beams were investigated, and they were very good. The carbon nanotube cathode is suitable for not only field emission display applications but also high-power microwave device applications.

Means for efficient electron beam generation in wide-aperture open-discharge light sources

The interaction of a plasma in the accelerating gap of an open discharge with a strong external electric field and with the cathode surface has been investigated theoretically and experimentally. In a pulsed nanosecond discharge, the ion inertia and plasma screening of the electric field cause a fast growth of the electric field E in the cathode region and a decrease in the length of the latter. Along with a reduction of the electron multiplication factor at high electric fields, this leads to a substantial decrease in the ion flux toward the cathode, which allows one to develop highly efficient open-discharge light sources with a long lifetime and low cathode sputtering. In this respect, continuous and quasi-continuous discharges are less advantageous because of the smaller increase in the electric field in the cathode region. The Townsend coefficients of charge multiplication and electron emission at high electric fields typical of open discharges have been measured for the first time. Fast ions and atoms extracted from the plasma of the accelerating gap significantly affect the cathode emission properties. In particular, photoemission is enhanced by more than one order of magnitude and becomes the main mechanism for electron generation. This also increases the efficiency and lifetime of open-discharge light sources.

Abnormal glow discharges in Ar: experiments and models

We review measured and calculated voltages and cathode-fallthicknesses against current and electrode separation for parallel-plane Arglow discharges in the above-normal, or abnormal, current range. We considerdc and pulsed discharges, but not radio-frequency discharges. Reasons for thevery high degree of variability among experiments and models are reviewed andsuggestions are made for improving the reliability of both. Variations of afactor of two in experimental cathode-fall voltages at a fixed normalizedcurrent density are attributed to differences in the cathode emissionproperties, varying electrode separation, and effects of discharge tube walls.We explore a wide range of normalized current densities, models of theionization coefficient against E/n, and the effective electron yields perpositive ion reaching the cathode using simple scaling laws. Ionization sourceterms for local-field and non-local-field models are compared and used as thebasis for a simplified non-local model. We discuss the present author'srecommendation that, because of current large uncertainties in the electronyield per ion for practical cathodes, the yield used in cathode-fall modelsshould be treated as an unknown. Recent models successfully predict thebehaviour of transient abnormal discharges on the microsecond time scale.

Afterpulses in a proportional counter with various cathode materials

The results of an investigation of afterpulses arising in a proportional counter due to the photoeffect on the cathode are presented. It was found that, as the gas amplification changes, the amplitude of afterpulses becomes proportional to the square amplitude of the primary pulse, and that the coefficient of proportionality can serve as a criterion for comparing the emission properties of cathodes made of various materials. Such a comparison was performed for cathodes of stainless steel, copper, beryllium and aluminum alloys. It was found that phosphatizing of aluminum produces a coating, which essentially reduces the photoeffect on the cathode. Unlike anodic oxidation, a phosphate layer possesses sufficient conductivity that prevents spontaneous discharges in a counter caused by accumulation of electrical charges followed by an electrical breakdown of the coating layer.

Quantitative LEIS analysis of thermionic dispenser cathodes

An UHV LEIS setup has been converted into a dedicated apparatus to study the surface composition, structure and dynamics of real dispenser cathodes and cathode model systems based on W single crystals. LEIS, AES and LEED are available to investigate the surface characteristics, and the cathode emission properties are derived in situ from a close-spaced diode configuration. In this paper, the focus is on the quantitative surface composition of B-type and M-type dispenser cathodes by LEIS. A straightforward quantification is hampered by the influence of the cathode workfunction on the neutralisation of the ions. It is shown that the ion fraction decreases as the workfunction of the cathode decreases. The Ba surface density is observed to increase with decreasing workfunction. However, before an accurate quantitative surface analysis can be performed a validation of the model used to correct for the influence of the ion fraction has to be performed.

The Deuterium attack of titanium electrodes under electric discharge conditions

AbstractElectrochemical and electrophysical investigations methods of TiD2, LiD(v)‐LiD(m)‐Me systems with subsequent structure and metallographic testing of the titanium electrodes were carried out. Electrophysical properties of a system depend upon metallic (liquid) cathode emission properties. TiD2 content was shown to be higher in Ti anodes with significant surface changes (nondeep cracks creation) after testing and Ti‐cathodes show deep cracks. The maximal hardened material was observed at the crack creation zone.

Technology and emission properties of dispenser cathode with controlled porosity

We report on a controlled porosity dispenser cathode using a new design and new manufacturing technology. Emission properties of this cathode in the temperature range of 800–1050°C are significantly greater than L, M and MM cathodes. Novel application of such kind of cathodes may be electron sources for multi-beam klystrons, TWTs, linear accelerators etc.

Thermionic emission properties of rare-earth-added LaB6 crystal cathodes

Subgrain boundaries were removed from LaB 6 crystals prepared by the floating zone method, by adding the rare earth hexaborides CeB 6 , PrB 6 and NdB 6 . In this work the thermionic emission properties of cathodes made from the boundary-free crystals were examined and compared with those of an LaB 6 crystal cathode. Addition of the rare earth borides did not influence the emission properties (emission current density, brightness and life) under practical working conditions.

Plasma-enhanced photoemission as a discharge lamp diagnostic

We describe our application of plasma-enhanced photoemission as an in situ electrode diagnostic for operating discharge lamps. The method uses focused low-power laser beams of various wavelengths to investigate emission properties of cathodes in fluorescent lamps. When a pulsed laser beam is directed onto the cathode, the photoemission effect will cause electrons to be ejected if hν is greater than the effective work function of the surface over the area illuminated. This burst of photoelectrons can be monitored, as well as the optogalvanic signal which results as they enter the surrounding discharge and produce additional ionization. The photon energy at which photoemission is observed places an upper limit on the local effective work function, which is influenced by the electric field at the cathode surface.

Experimental tube for investigating the emission properties of thermionic cathodes working at high temperatures, heated by parallel electron-beam bombardment

The experimental tube for investigating the emission properties of cathodes working at high temperatures was constructed. Cermet cathodes, in the shape of tablets, were heated by parallel electron beam bombardment. The thermoemission constants of ThO <inf xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">2</inf> -Mo cermet cathodes were measured by Richardson's straight line method.

Spark Breakdown Potentials as a Function of the Product of the Pressure by the Plate Separation in A,N2andH2for Pt and Na Cathodes

Measurements were made on the sparking potentials between fixed plane parallel electrodes in purified, mercury-free A, ${\mathrm{N}}_{2}$ and ${\mathrm{H}}_{2}$ for Pt and Na cathodes for extended pressure ranges. The effect on the sparking potentials in ${\mathrm{H}}_{2}$ produced by heated Pt and Na cathodes was investigated. In all of the gases studied, the values of the sparking potential are lower for a Na-coated Pt cathode than for a clean Pt cathode throughout the pressure ranges investigated. The percentage lowering, which is especially pronounced near the minimum sparking potential, decreases with increasing $p\ensuremath{\delta}$. In A, the sparking potentials for a Pt cathode agree very closely with the Fe cathode values of Penning except in the vicinity of the minimum sparking potential; the discrepancy at low values of $p\ensuremath{\delta}$ is caused by the difference in cathode surface. For a Na-coated surface, the sparking potentials are 50 percent lower in the vicinity of the minimum and 7.5 percent lower at $p\ensuremath{\delta}$ equal to 240 mm\ifmmode\times\else\texttimes\fi{}cm. The predischarge currents within a few volts of breakdown were less than ${10}^{\ensuremath{-}9}$ amp. for both Na and Pt surfaces. The effect of a Na cathode on the breakdown potentials in A is in satisfactory agreement with the quantitative predictions of classical Townsend theory given by Loeb. In ${\mathrm{N}}_{2}$, the lowering produced by Na is 28 percent near the minimum and 20 percent at $p\ensuremath{\delta}$ equal to 340 mm\ifmmode\times\else\texttimes\fi{}cm. The ${\mathrm{N}}_{2}$ results are not applicable to the theory discussed by Loeb because of the heavy predischarge currents, 360 microamperes at $p\ensuremath{\delta}$ equal to 356, which occur in the presence of Na. The lowered sparking potentials and the heavy predischarge currents, as well as the increase in the values of the Townsend coefficient $\ensuremath{\alpha}$ in the presence of a Na-covered cathode which was observed by Bowls, indicate that there occurs in the presence of Na a volatile substance, Na or something else, of vapor pressure greater than ${10}^{\ensuremath{-}4}$ mm and ionization potential less than that of ${\mathrm{N}}_{2}$ which acts independently of cathode phenomena. ${\mathrm{H}}_{2}$ is intermediate between ${\mathrm{N}}_{2}$ and A both with respect to the approach of the Na and Pt curves at high $p\ensuremath{\delta}$ and the magnitudes of the predischarge currents. In the ${\mathrm{H}}_{2}$---Na case, the marked predischarge currents and the lowered sparking potentials are probably caused by a volatile impurity, Na or something else. The sparking potentials in ${\mathrm{H}}_{2}$ with heated Pt and Na cathodes are identical within the limits of experimental error. The coincidence at both low and high values of $p\ensuremath{\delta}$ may be explained by the formation of NaH and the distilling off from the heated surface of the Na and/or NaH. At low values of $p\ensuremath{\delta}$, the sparking potentials are governed considerably more by cathode phenomena than by the primary process of ionization by collision. The heated Na cathode has no Na nor NaH deposited on it; the cathode emission properties are the same therefore as those of the heated Pt surface. Hence, the sparking potentials are the same. At high values of $p\ensuremath{\delta}$, $\ensuremath{\alpha}$ is predominant in determining the sparking potentials, and $\ensuremath{\alpha}$ is very sensitive to the presence of Na. The formation of NaH, which occurs because of the presence of the heated cathode, probably removes most of the Na vapor and destroys all of the volatile substance which causes the lowering in the case of the cold Na cathodes.