Chaos in high-power high-frequency gyrotrons

Airila, Markus

Chaos in high-power high-frequency gyrotrons

dc.contributor	Aalto-yliopisto	fi
dc.contributor	Aalto University	en
dc.contributor.author	Airila, Markus
dc.contributor.department	Department of Engineering Physics and Mathematics	en
dc.contributor.department	Teknillisen fysiikan ja matematiikan osasto	fi
dc.contributor.lab	Advanced Energy Systems	en
dc.contributor.lab	Energiateknologiat	fi
dc.date.accessioned	2012-02-13T12:36:30Z
dc.date.available	2012-02-13T12:36:30Z
dc.date.issued	2004-02-06
dc.description.abstract	Gyrotron interaction is a complex nonlinear dynamical process, which may turn chaotic in certain circumstances. The emergence of chaos renders dynamical systems unpredictable and causes bandwidth broadening of signals. Such effects would jeopardize the prospect of advanced gyrotrons in fusion. Therefore, it is important to be aware of the possibility of chaos in gyrotrons. There are three different chaos scenarios closely related to the development of high-power gyrotrons: First, the onset of chaos in electron trajectories would lead to difficulties in the design and efficient operation of depressed potential collectors, which are used for efficiency enhancement. Second, the radio-frequency signal could turn chaotic, decreasing the output power and the spectral purity of the output signal. As a result, mode conversion, transmission, and absorption efficiencies would be reduced. Third, spatio-temporal chaos in the resonator field structure can set a limit for the use of large-diameter interaction cavities and high-order TE modes (large azimuthal index) allowing higher generated power. In this thesis, the issues above are addressed with numerical modeling. It is found that chaos in electron residual energies is practically absent in the parameter region corresponding to high efficiency. Accordingly, depressed collectors are a feasible solution also in advanced high-power gyrotrons. A new method is presented for straightforward numerical solution of the one-dimensional self-consistent time-dependent gyrotron equations, and the method is generalized to two dimensions. In 1D, a chart of gyrotron oscillations is calculated. It is shown that the regions of stationary oscillations, automodulation, and chaos have a complicated topology in the plane of generalized gyrotron variables. The threshold current for chaotic oscillations exceeds typical operating currents by a factor of ten. However, reflection of the output signal may significantly lower the threshold. 2D computations indicate that stationary single-mode operation of gyrotrons would be impossible if the azimuthal index is about 46 or larger, which is rather close to the presently used values. Moreover, electron beam misalignment can lower this critical value. Above the critical value, less favorable modes suppress the operating mode.	en
dc.description.version	reviewed	en
dc.format.extent	45, [56]
dc.format.mimetype	application/pdf
dc.identifier.isbn	951-22-6917-1
dc.identifier.issn	1459-7268
dc.identifier.uri	https://aaltodoc.aalto.fi/handle/123456789/2385
dc.identifier.urn	urn:nbn:fi:tkk-003305
dc.language.iso	en	en
dc.publisher	Helsinki University of Technology	en
dc.publisher	Teknillinen korkeakoulu	fi
dc.relation.haspart	Airila M. I., Dumbrajs O., Reinfelds A. and Teychenné D., 2000. Traces of stochasticity in electron trajectories in gyrotron resonators. International Journal of Infrared and Millimeter Waves 21, number 11, pages 1759-1776. [article1.pdf] © 2000 Kluwer Academic Publishers. By permission.
dc.relation.haspart	Airila M. I. and Dumbrajs O., 2001. Generalized gyrotron theory with inclusion of adiabatic electron trapping in the presence of a depressed collector. Physics of Plasmas 8, number 4, pages 1358-1362. [article2.pdf] © 2001 American Institute of Physics. By permission.
dc.relation.haspart	Airila M. I., Dumbrajs O., Reinfelds A. and Strautiņš U., 2001. Nonstationary oscillations in gyrotrons. Physics of Plasmas 8, number 10, pages 4608-4612. [article3.pdf] © 2001 American Institute of Physics. By permission.
dc.relation.haspart	Airila M. I. and Kåll P., 2004. Effect of reflections on nonstationary gyrotron oscillations. IEEE Transactions on Microwave Theory and Techniques 52, number 2, to appear. [article4.pdf] © 2004 IEEE. By permission.
dc.relation.haspart	Airila M. I., Dumbrajs O., Kåll P. and Piosczyk B., 2003. Influence of reflections on the operation of the 2 MW, CW 170 GHz coaxial cavity gyrotron for ITER. Nuclear Fusion 43, number 11, pages 1454-1457. [article5.pdf] © 2003 International Atomic Energy Agency (IAEA). By permission.
dc.relation.haspart	Airila M. I. and Dumbrajs O., 2002. Spatio-temporal chaos in the transverse section of gyrotron resonators. IEEE Transactions on Plasma Science 30, number 3, pages 846-850. [article6.pdf] © 2002 IEEE. By permission.
dc.relation.haspart	Airila M. I., 2003. Degradation of operation mode purity in a gyrotron with an off-axis electron beam. Physics of Plasmas 10, number 1, pages 296-299. [article7.pdf] © 2003 American Institute of Physics. By permission.
dc.relation.ispartofseries	Helsinki University of Technology publications in engineering physics. A	en
dc.relation.ispartofseries	825	en
dc.subject.keyword	depressed collector	en
dc.subject.keyword	spatio-temporal chaos	en
dc.subject.keyword	microwave reflections	en
dc.subject.keyword	electron beam misalignment	en
dc.subject.keyword	modeling	en
dc.subject.other	Energy	en
dc.title	Chaos in high-power high-frequency gyrotrons	en
dc.type	G5 Artikkeliväitöskirja	fi
dc.type.dcmitype	text	en
dc.type.ontasot	Väitöskirja (artikkeli)	fi
dc.type.ontasot	Doctoral dissertation (article-based)	en
local.aalto.digiauth	ask
local.aalto.digifolder	Aalto_63421