Phase-Control of a Rising Sun Magnetron Using a Modulated, Addressable, Current Source

Sulmer Fernandez-Gutierrez; Jim Browning; Ming-Chieh Lin; David N. Smithe; Jack Watrous

doi:10.1116/1.4916631

Phase-Control of a Rising Sun Magnetron Using a Modulated, Addressable, Current Source

Sulmer Fernandez-Gutierrez
, Jim Browning
, Ming-Chieh Lin
, David N. Smithe
, Jack Watrous

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

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Abstract

It has been proposed that the use of gated field emitters with a faceted cathode in place of the conventional thermionic cathode could be used to control the current injection in a magnetron, both temporally and spatially. In this work, this concept is studied using the particle-in-cell code VORPAL. The magnetron studied is a ten-cavity, rising sun magnetron, which can be modeled easily using a 2D simulation. The magnetron has a ten-sided faceted cathode. The electrons are injected from three emitter elements on each of the ten facets. Each emitter is turned ON and OFF in sequence at the oscillating frequency with five emitter elements ON at once to obtain the five electron spokes of the π-mode. The simulation results show that the modulated, addressable cathode reduces startup time from 100 to 35 ns, increases the power density, controls the RF phase, and allows active phase control during oscillation.

Original language	American English
Article number	031203
Journal	Journal of Vacuum Science and Technology B
Volume	33
Issue number	3
DOIs	https://doi.org/10.1116/1.4916631
State	Published - 1 May 2015

Keywords

anodes
cathodes
charge injection
current density
field emmitters

EGS Disciplines

Electrical and Computer Engineering

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Phase-Control of a Rising Sun Magnetron Using a Modulated AddresFinal published version, 1.48 MBLicense: Unspecified

Cite this

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title = "Phase-Control of a Rising Sun Magnetron Using a Modulated, Addressable, Current Source",

abstract = " It has been proposed that the use of gated field emitters with a faceted cathode in place of the conventional thermionic cathode could be used to control the current injection in a magnetron, both temporally and spatially. In this work, this concept is studied using the particle-in-cell code VORPAL. The magnetron studied is a ten-cavity, rising sun magnetron, which can be modeled easily using a 2D simulation. The magnetron has a ten-sided faceted cathode. The electrons are injected from three emitter elements on each of the ten facets. Each emitter is turned ON and OFF in sequence at the oscillating frequency with five emitter elements ON at once to obtain the five electron spokes of the π-mode. The simulation results show that the modulated, addressable cathode reduces startup time from 100 to 35 ns, increases the power density, controls the RF phase, and allows active phase control during oscillation.",

keywords = "anodes, cathodes, charge injection, current density, field emmitters",

author = "Sulmer Fernandez-Gutierrez and Jim Browning and Ming-Chieh Lin and Smithe, \{David N.\} and Jack Watrous",

note = "Publisher Copyright: {\textcopyright} 2015 American Vacuum Society.",

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language = "American English",

volume = "33",

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T1 - Phase-Control of a Rising Sun Magnetron Using a Modulated, Addressable, Current Source

AU - Fernandez-Gutierrez, Sulmer

AU - Browning, Jim

AU - Lin, Ming-Chieh

AU - Smithe, David N.

AU - Watrous, Jack

PY - 2015/5/1

Y1 - 2015/5/1

N2 - It has been proposed that the use of gated field emitters with a faceted cathode in place of the conventional thermionic cathode could be used to control the current injection in a magnetron, both temporally and spatially. In this work, this concept is studied using the particle-in-cell code VORPAL. The magnetron studied is a ten-cavity, rising sun magnetron, which can be modeled easily using a 2D simulation. The magnetron has a ten-sided faceted cathode. The electrons are injected from three emitter elements on each of the ten facets. Each emitter is turned ON and OFF in sequence at the oscillating frequency with five emitter elements ON at once to obtain the five electron spokes of the π-mode. The simulation results show that the modulated, addressable cathode reduces startup time from 100 to 35 ns, increases the power density, controls the RF phase, and allows active phase control during oscillation.

AB - It has been proposed that the use of gated field emitters with a faceted cathode in place of the conventional thermionic cathode could be used to control the current injection in a magnetron, both temporally and spatially. In this work, this concept is studied using the particle-in-cell code VORPAL. The magnetron studied is a ten-cavity, rising sun magnetron, which can be modeled easily using a 2D simulation. The magnetron has a ten-sided faceted cathode. The electrons are injected from three emitter elements on each of the ten facets. Each emitter is turned ON and OFF in sequence at the oscillating frequency with five emitter elements ON at once to obtain the five electron spokes of the π-mode. The simulation results show that the modulated, addressable cathode reduces startup time from 100 to 35 ns, increases the power density, controls the RF phase, and allows active phase control during oscillation.

KW - anodes

KW - cathodes

KW - charge injection

KW - current density

KW - field emmitters

UR - https://scholarworks.boisestate.edu/electrical_facpubs/282

UR - https://www.scopus.com/pages/publications/84926431430

U2 - 10.1116/1.4916631

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Phase-Control of a Rising Sun Magnetron Using a Modulated, Addressable, Current Source

Abstract

Keywords

EGS Disciplines

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