Transmission of intense electron beams through apertures

Harris, John R.; Lewellen, John W.

doi:10.1063/1.3353094

Physics of Plasmas

2010

DOI: 10.1063/1.3353094

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Transmission of intense electron beams through apertures

John R. Harris

John W. Lewellen

Abstract: Apertures are an effective and widely used means for altering the properties of charged particle beams. Despite their conceptual simplicity, they can lead to interesting and seemingly paradoxical behavior. For example, when an intense beam is incident on an aperture, space charge will cause the beam spot size to be a function of beam current. Increasing the beam current can cause the beam area to increase so rapidly that the current density incident on the aperture will decrease, thereby decreasing the current… Show more

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Cited by 9 publications

References 28 publications

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Guiding of Reactive Plasma Species by Micro‐Channels

Zimmermann

Klämpfl

et al. 2012

Plasma Processes & Polymers

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We investigate the effect of the micro‐channel plate (MCP) on the diffusive transport of reactive plasma species generated by a cold atmospheric discharge. The diffusion of the reactive plasma species is guided by the micro‐channels and the side diffusion is consequently reduced. Therefore the reactive plasma species are more effectively transported to the target surface. A higher bactericidal efficiency is found in comparison with the open, unhindered configuration when the open area ratio of the MCP equals 50%. Furthermore, the experimental results show a significant UV reduction because of the shielding by the MCP. magnified image

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Guiding of Reactive Plasma Species by Micro‐Channels

Zimmermann

Klämpfl

et al. 2012

Plasma Processes & Polymers

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Transport of intense beams with current-dependent initial conditions in linearly tapered solenoid channels

Harris

2019

Laser Part. Beams

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In electron beams where space charge plays an important role in the beam transport, the beams’ transverse and longitudinal properties will become coupled. One example of this is the transverse–longitudinal correlation produced in a current-modulated beam generated in a DC electron gun, formed through the competition between the time-dependent radial space charge force and the time-independent radial focusing force. This correlation will cause both the slice radius and divergence of the beam extracted from the gun to depend on the slice current. Here we consider the transport of such a beam in a linearly tapered solenoid focusing channel. Transport performance was generally improved with longer taper lengths, minimal initial correlation between slice divergence and slice current, and moderate degrees of initial correlation between initial slice radius and slice current. Performance was also generally improved with lower slice emittances, although surprisingly transport was improved by slightly increasing the assumed slice emittance in certain limited circumstances.

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Suppression of current fluctuations in an intense electron beam

Harris

Lewellen

2010

Journal of Applied Physics

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When an intense beam encounters an aperture, the transmitted current depends on the properties of the beam and the transport channel, as well as those of the aperture itself. In some cases, an increase in the incident beam current will be exactly compensated by an increase in the incident beam area, so that the current density at the aperture remains unchanged. When this occurs, the transmitted beam current becomes independent of changes in the incident beam current, providing a passive means for suppressing current fluctuations in the beam. In this article, a key requirement for the existence of this condition is derived. This requirement is shown to be fulfilled in the case of an idealized uniform focusing channel in the small-signal limit, but to be violated when the current fluctuations are not small. Even in this case, the apertured transport system retains the ability to suppress—but not totally eliminate—fluctuations in the transmitted beam current for a wide range of incident beam currents.

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Transmission of intense electron beams through apertures

Cited by 9 publications

References 28 publications

Guiding of Reactive Plasma Species by Micro‐Channels

Guiding of Reactive Plasma Species by Micro‐Channels

Transport of intense beams with current-dependent initial conditions in linearly tapered solenoid channels

Suppression of current fluctuations in an intense electron beam

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